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class |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.logand | val logand : _: Lib.IntTypes.int_t t l -> _: Lib.IntTypes.int_t t l -> Lib.IntTypes.int_t t l | let logand #t #l = Lib.IntTypes.logand #t #l | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 51,
"end_line": 16,
"start_col": 7,
"start_line": 16
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8 | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | _: Lib.IntTypes.int_t t l -> _: Lib.IntTypes.int_t t l -> Lib.IntTypes.int_t t l | Prims.Tot | [
"total"
] | [] | [
"Lib.IntTypes.inttype",
"Lib.IntTypes.secrecy_level",
"Lib.IntTypes.logand",
"Lib.IntTypes.int_t"
] | [] | false | false | false | false | false | let logand #t #l =
| Lib.IntTypes.logand #t #l | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.repeat_blocks | val repeat_blocks : blocksize: n: Prims.pos{n <= Prims.pow2 32 - 1} ->
inp: Lib.Sequence.seq _ ->
f: (_: Lib.Sequence.lseq _ blocksize -> _: _ -> _) ->
l: (len: Prims.nat{len < blocksize} -> s: Lib.Sequence.lseq _ len -> _: _ -> _) ->
init: _
-> _ | let repeat_blocks = Lib.Sequence.repeat_blocks | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 53,
"end_line": 18,
"start_col": 7,
"start_line": 18
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
blocksize: n: Prims.pos{n <= Prims.pow2 32 - 1} ->
inp: Lib.Sequence.seq _ ->
f: (_: Lib.Sequence.lseq _ blocksize -> _: _ -> _) ->
l: (len: Prims.nat{len < blocksize} -> s: Lib.Sequence.lseq _ len -> _: _ -> _) ->
init: _
-> _ | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.repeat_blocks",
"Prims.pos",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"Prims.op_Subtraction",
"Prims.pow2",
"Lib.Sequence.seq",
"Lib.Sequence.lseq",
"Prims.nat",
"Prims.op_LessThan"
] | [] | false | false | false | false | false | let repeat_blocks =
| Lib.Sequence.repeat_blocks | false |
|
Lattice.fst | Lattice.bind | val bind (a b: Type) (labs1 labs2: list eff_label) (c: repr a labs1) (f: (x: a -> repr b labs2))
: Tot (repr b (labs1 @ labs2)) | val bind (a b: Type) (labs1 labs2: list eff_label) (c: repr a labs1) (f: (x: a -> repr b labs2))
: Tot (repr b (labs1 @ labs2)) | let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 5,
"end_line": 92,
"start_col": 0,
"start_line": 82
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
a: Type ->
b: Type ->
labs1: Prims.list Lattice.eff_label ->
labs2: Prims.list Lattice.eff_label ->
c: Lattice.repr a labs1 ->
f: (x: a -> Lattice.repr b labs2)
-> Lattice.repr b (labs1 @ labs2) | Prims.Tot | [
"total"
] | [] | [
"Prims.list",
"Lattice.eff_label",
"Lattice.repr",
"Lattice.state",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.option",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Pervasives.Native.None",
"FStar.List.Tot.Base.op_At"
] | [] | false | false | false | false | false | let bind (a b: Type) (labs1 labs2: list eff_label) (c: repr a labs1) (f: (x: a -> repr b labs2))
: Tot (repr b (labs1 @ labs2)) =
| let r =
fun s0 ->
match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r | false |
Lattice.fst | Lattice.test_catch2 | val test_catch2 (f: (unit -> EFF int [EXN; EXN; WR])) : EFF int [EXN; WR] | val test_catch2 (f: (unit -> EFF int [EXN; EXN; WR])) : EFF int [EXN; WR] | let test_catch2 (f : unit -> EFF int [EXN;EXN;WR]) : EFF int [EXN;WR] =
catch f g | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 11,
"end_line": 190,
"start_col": 0,
"start_line": 189
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0)
let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r
let subcomp (a:Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
: Pure (repr a labs2)
(requires (sublist labs1 labs2))
(ensures (fun _ -> True))
= f
let ite (p q r : Type0) = (p ==> q) /\ (~p ==> r)
let if_then_else
(a : Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
(g : repr a labs2)
(p : bool)
: Type
= repr a (labs1@labs2)
total // need this for catch!!
reifiable
reflectable
effect {
EFF (a:Type) (_:list eff_label)
with {repr; return; bind; subcomp; if_then_else}
}
let lift_pure_eff
(a:Type)
(wp : pure_wp a)
(f : unit -> PURE a wp)
: Pure (repr a [])
(requires (wp (fun _ -> True)))
(ensures (fun _ -> True))
= FStar.Monotonic.Pure.elim_pure_wp_monotonicity wp;
fun s0 -> (Some (f ()), s0)
sub_effect PURE ~> EFF = lift_pure_eff
let get () : EFF int [RD] =
EFF?.reflect (fun s0 -> (Some s0, s0))
let put (s:state) : EFF unit [WR] =
EFF?.reflect (fun _ -> (Some (), s))
let raise #a () : EFF a [EXN] =
EFF?.reflect (fun s0 -> (None, s0))
let test0 (x y : int) : EFF int [RD; EXN] =
let z = get () in
if x + z > 0
then raise ()
else y - z
let test1 (x y : int) : EFF int [EXN; RD; WR] =
let z = get () in
if x + z > 0
then raise ()
else (put 42; y - z)
let sublist_at_self (l1 : list eff_label)
: Lemma (sublist (l1@l1) l1)
[SMTPat (l1@l1)]
= Classical.forall_intro (List.Tot.Properties.append_mem l1 l1)
let labpoly #labs (f g : unit -> EFF int labs) : EFF int labs =
f () + g ()
let catch0 #a #labs (f:repr a (EXN::labs)) (g:repr a labs)
: repr a labs
= fun s0 ->
let r0 : option a & state = f s0 in
let r1 : option a & state =
match r0 with
| (Some v, s1) -> (Some v, s1)
| (None, s1) -> g s1
| _ -> unreachable ()
in
r1
let catch #a #labs
(f : unit -> EFF a (EXN::labs))
(g : unit -> EFF a labs)
: EFF a labs
= EFF?.reflect (catch0 (reify (f ())) (reify (g ())))
// TODO: haskell-like runST.
// strong update with index on state type(s)?
//AR: 07/03: this g was inlined earlier, but then the proofs were relying on smt_reifiable
let g #labs () : EFF int labs = 42
let test_catch #labs (f : unit -> EFF int [EXN;WR]) : EFF int [WR] =
catch f g | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | f: (_: Prims.unit -> Lattice.EFF Prims.int) -> Lattice.EFF Prims.int | Lattice.EFF | [] | [] | [
"Prims.unit",
"Prims.int",
"Prims.Cons",
"Lattice.eff_label",
"Lattice.EXN",
"Lattice.WR",
"Prims.Nil",
"Lattice.catch",
"Lattice.g"
] | [] | false | true | false | false | false | let test_catch2 (f: (unit -> EFF int [EXN; EXN; WR])) : EFF int [EXN; WR] =
| catch f g | false |
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.read_bounded_int32_le' | val read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32))) | val read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32))) | let read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer_le sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer_le sz)
(in_bounds min max))
() | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 6,
"end_line": 552,
"start_col": 0,
"start_line": 535
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 ()
#push-options "--z3rlimit 20"
let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul
#pop-options
let write_bounded_integer_le_2 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_2 ()
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_le_3
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out pos (pos `U32.add` 1ul) (B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let write_bounded_integer_le_3 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_3 ()
let serialize32_bounded_integer_le_4
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h;
LE.store32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h h';
4ul
let write_bounded_integer_le_4 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_4 ()
let write_u16_le =
[@inline_let] let _ = synth_u16_le_injective; synth_u16_le_inverse in
write_synth write_bounded_integer_le_2 synth_u16_le synth_u16_le_recip (fun x -> synth_u16_le_recip x) ()
let write_u32_le =
write_synth write_bounded_integer_le_4 synth_u32_le synth_u32_le_recip (fun x -> synth_u32_le_recip x) ()
inline_for_extraction
let validate_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer_le sz)
(read_bounded_integer_le sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_le_1
min32 max32
= validate_bounded_int32_le' min32 max32 1
let validate_bounded_int32_le_2
min32 max32
= validate_bounded_int32_le' min32 max32 2
let validate_bounded_int32_le_3
min32 max32
= validate_bounded_int32_le' min32 max32 3
let validate_bounded_int32_le_4
min32 max32
= validate_bounded_int32_le' min32 max32 4
inline_for_extraction
let jump_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_le_1
min32 max32
= jump_bounded_int32_le' min32 max32 1
let jump_bounded_int32_le_2
min32 max32
= jump_bounded_int32_le' min32 max32 2
let jump_bounded_int32_le_3
min32 max32
= jump_bounded_int32_le' min32 max32 3
let jump_bounded_int32_le_4
min32 max32
= jump_bounded_int32_le' min32 max32 4
inline_for_extraction
let write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_le_1
min32 max32
= write_bounded_int32_le' min32 max32 1
let write_bounded_int32_le_2
min32 max32
= write_bounded_int32_le' min32 max32 2
let write_bounded_int32_le_3
min32 max32
= write_bounded_int32_le' min32 max32 3
let write_bounded_int32_le_4
min32 max32
= write_bounded_int32_le' min32 max32 4 | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
min32: FStar.UInt32.t ->
max32:
FStar.UInt32.t
{ 0 < FStar.UInt32.v max32 /\ FStar.UInt32.v min32 <= FStar.UInt32.v max32 /\
FStar.UInt32.v max32 < 4294967296 } ->
sz: Prims.nat{sz == LowParse.Spec.BoundedInt.log256' (FStar.UInt32.v max32)}
-> LowParse.Low.Base.leaf_reader (LowParse.Spec.BoundedInt.parse_bounded_int32_le (FStar.UInt32.v min32
)
(FStar.UInt32.v max32)) | Prims.Tot | [
"total"
] | [] | [
"FStar.UInt32.t",
"Prims.l_and",
"Prims.b2t",
"Prims.op_LessThan",
"FStar.UInt32.v",
"Prims.op_LessThanOrEqual",
"Prims.nat",
"Prims.eq2",
"LowParse.Spec.BoundedInt.log256'",
"LowParse.Low.Combinators.read_inline_synth",
"LowParse.Spec.Combinators.parse_filter_kind",
"LowParse.Spec.BoundedInt.parse_bounded_integer_kind",
"LowParse.Spec.Combinators.parse_filter_refine",
"LowParse.Spec.BoundedInt.bounded_integer",
"LowParse.Spec.BoundedInt.in_bounds",
"LowParse.Spec.BoundedInt.bounded_int32",
"LowParse.Spec.Combinators.parse_filter",
"LowParse.Spec.BoundedInt.parse_bounded_integer_le",
"LowParse.Low.Combinators.read_filter",
"LowParse.Low.BoundedInt.read_bounded_integer_le",
"FStar.UInt.uint_t",
"LowParse.Low.Base.leaf_reader",
"LowParse.Spec.BoundedInt.parse_bounded_int32_kind",
"LowParse.Spec.BoundedInt.parse_bounded_int32_le"
] | [] | false | false | false | false | false | let read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32))) =
| [@@ inline_let ]let min = U32.v min32 in
[@@ inline_let ]let max = U32.v max32 in
read_inline_synth (parse_filter (parse_bounded_integer_le sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter (read_bounded_integer_le sz) (in_bounds min max))
() | false |
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.serialize32_bounded_integer_le_2 | val serialize32_bounded_integer_le_2 : serializer32 (serialize_bounded_integer_le 2) | val serialize32_bounded_integer_le_2 : serializer32 (serialize_bounded_integer_le 2) | let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 5,
"end_line": 378,
"start_col": 0,
"start_line": 369
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 () | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 20,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | LowParse.Low.Base.serializer32 (LowParse.Spec.BoundedInt.serialize_bounded_integer_le 2) | Prims.Tot | [
"total"
] | [] | [
"LowParse.Spec.BoundedInt.bounded_integer",
"LowStar.Monotonic.Buffer.srel",
"LowParse.Bytes.byte",
"LowStar.Monotonic.Buffer.mbuffer",
"FStar.UInt32.t",
"FStar.UInt32.__uint_to_t",
"Prims.unit",
"LowParse.Low.Endianness.store_post_modifies",
"FStar.UInt32.v",
"FStar.Seq.Base.seq",
"Prims.eq2",
"Prims.int",
"Prims.l_or",
"Prims.b2t",
"Prims.op_GreaterThanOrEqual",
"FStar.UInt.size",
"FStar.UInt16.n",
"FStar.Endianness.le_to_n",
"FStar.UInt16.v",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"LowStar.Endianness.store16_le_i",
"LowParse.Low.Endianness.writable_store_pre",
"FStar.UInt16.t",
"Prims.op_Equality",
"Prims.op_Modulus",
"Prims.pow2",
"FStar.Int.Cast.uint32_to_uint16",
"LowParse.Spec.BoundedInt.bounded_integer_prop_equiv"
] | [] | false | false | false | false | false | let serialize32_bounded_integer_le_2 =
| fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.repeat_blocks_f | val repeat_blocks_f : bs: (n: Prims.nat{n <= Prims.pow2 32 - 1}){bs > 0} ->
inp: Lib.Sequence.seq _ ->
f: (_: Lib.Sequence.lseq _ bs -> _: _ -> _) ->
nb: Prims.nat{nb == Lib.Sequence.length inp / bs} ->
i: Prims.nat{i < nb} ->
acc: _
-> _ | let repeat_blocks_f = Lib.Sequence.repeat_blocks_f | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 57,
"end_line": 19,
"start_col": 7,
"start_line": 19
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
bs: (n: Prims.nat{n <= Prims.pow2 32 - 1}){bs > 0} ->
inp: Lib.Sequence.seq _ ->
f: (_: Lib.Sequence.lseq _ bs -> _: _ -> _) ->
nb: Prims.nat{nb == Lib.Sequence.length inp / bs} ->
i: Prims.nat{i < nb} ->
acc: _
-> _ | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.repeat_blocks_f",
"Prims.nat",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"Prims.op_Subtraction",
"Prims.pow2",
"Prims.op_GreaterThan",
"Lib.Sequence.seq",
"Lib.Sequence.lseq",
"Prims.eq2",
"Prims.int",
"Prims.op_Division",
"Lib.Sequence.length",
"Prims.op_LessThan"
] | [] | false | false | false | false | false | let repeat_blocks_f =
| Lib.Sequence.repeat_blocks_f | false |
|
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.write_bounded_int32_le_fixed_size | val write_bounded_int32_le_fixed_size
(min32: U32.t)
(max32: U32.t { U32.v min32 <= U32.v max32 })
: Tot (leaf_writer_strong (serialize_bounded_int32_le_fixed_size (U32.v min32) (U32.v max32))) | val write_bounded_int32_le_fixed_size
(min32: U32.t)
(max32: U32.t { U32.v min32 <= U32.v max32 })
: Tot (leaf_writer_strong (serialize_bounded_int32_le_fixed_size (U32.v min32) (U32.v max32))) | let write_bounded_int32_le_fixed_size
min32 max32
= write_filter write_u32_le (in_bounds (U32.v min32) (U32.v max32)) | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 67,
"end_line": 580,
"start_col": 0,
"start_line": 578
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 ()
#push-options "--z3rlimit 20"
let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul
#pop-options
let write_bounded_integer_le_2 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_2 ()
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_le_3
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out pos (pos `U32.add` 1ul) (B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let write_bounded_integer_le_3 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_3 ()
let serialize32_bounded_integer_le_4
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h;
LE.store32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h h';
4ul
let write_bounded_integer_le_4 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_4 ()
let write_u16_le =
[@inline_let] let _ = synth_u16_le_injective; synth_u16_le_inverse in
write_synth write_bounded_integer_le_2 synth_u16_le synth_u16_le_recip (fun x -> synth_u16_le_recip x) ()
let write_u32_le =
write_synth write_bounded_integer_le_4 synth_u32_le synth_u32_le_recip (fun x -> synth_u32_le_recip x) ()
inline_for_extraction
let validate_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer_le sz)
(read_bounded_integer_le sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_le_1
min32 max32
= validate_bounded_int32_le' min32 max32 1
let validate_bounded_int32_le_2
min32 max32
= validate_bounded_int32_le' min32 max32 2
let validate_bounded_int32_le_3
min32 max32
= validate_bounded_int32_le' min32 max32 3
let validate_bounded_int32_le_4
min32 max32
= validate_bounded_int32_le' min32 max32 4
inline_for_extraction
let jump_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_le_1
min32 max32
= jump_bounded_int32_le' min32 max32 1
let jump_bounded_int32_le_2
min32 max32
= jump_bounded_int32_le' min32 max32 2
let jump_bounded_int32_le_3
min32 max32
= jump_bounded_int32_le' min32 max32 3
let jump_bounded_int32_le_4
min32 max32
= jump_bounded_int32_le' min32 max32 4
inline_for_extraction
let write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_le_1
min32 max32
= write_bounded_int32_le' min32 max32 1
let write_bounded_int32_le_2
min32 max32
= write_bounded_int32_le' min32 max32 2
let write_bounded_int32_le_3
min32 max32
= write_bounded_int32_le' min32 max32 3
let write_bounded_int32_le_4
min32 max32
= write_bounded_int32_le' min32 max32 4
inline_for_extraction
let read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer_le sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer_le sz)
(in_bounds min max))
()
let read_bounded_int32_le_1
min32 max32
= read_bounded_int32_le' min32 max32 1
let read_bounded_int32_le_2
min32 max32
= read_bounded_int32_le' min32 max32 2
let read_bounded_int32_le_3
min32 max32
= read_bounded_int32_le' min32 max32 3
let read_bounded_int32_le_4
min32 max32
= read_bounded_int32_le' min32 max32 4
let validate_bounded_int32_le_fixed_size
min32 max32
= validate_filter (validate_u32_le ()) read_u32_le (in_bounds (U32.v min32) (U32.v max32)) (fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
let read_bounded_int32_le_fixed_size
min32 max32
= read_filter read_u32_le (in_bounds (U32.v min32) (U32.v max32)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | min32: FStar.UInt32.t -> max32: FStar.UInt32.t{FStar.UInt32.v min32 <= FStar.UInt32.v max32}
-> LowParse.Low.Base.leaf_writer_strong (LowParse.Spec.BoundedInt.serialize_bounded_int32_le_fixed_size
(FStar.UInt32.v min32)
(FStar.UInt32.v max32)) | Prims.Tot | [
"total"
] | [] | [
"FStar.UInt32.t",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"FStar.UInt32.v",
"LowParse.Low.Combinators.write_filter",
"LowParse.Spec.Int.parse_u32_kind",
"LowParse.Spec.BoundedInt.parse_u32_le",
"LowParse.Spec.BoundedInt.serialize_u32_le",
"LowParse.Low.BoundedInt.write_u32_le",
"LowParse.Spec.BoundedInt.in_bounds",
"LowParse.Low.Base.leaf_writer_strong",
"LowParse.Spec.BoundedInt.parse_bounded_int32_fixed_size_kind",
"LowParse.Spec.BoundedInt.bounded_int32",
"LowParse.Spec.BoundedInt.parse_bounded_int32_le_fixed_size",
"LowParse.Spec.BoundedInt.serialize_bounded_int32_le_fixed_size"
] | [] | false | false | false | false | false | let write_bounded_int32_le_fixed_size min32 max32 =
| write_filter write_u32_le (in_bounds (U32.v min32) (U32.v max32)) | false |
Lattice.fst | Lattice.sublist_at_self | val sublist_at_self (l1: list eff_label) : Lemma (sublist (l1 @ l1) l1) [SMTPat (l1 @ l1)] | val sublist_at_self (l1: list eff_label) : Lemma (sublist (l1 @ l1) l1) [SMTPat (l1 @ l1)] | let sublist_at_self (l1 : list eff_label)
: Lemma (sublist (l1@l1) l1)
[SMTPat (l1@l1)]
= Classical.forall_intro (List.Tot.Properties.append_mem l1 l1) | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 65,
"end_line": 157,
"start_col": 0,
"start_line": 154
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0)
let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r
let subcomp (a:Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
: Pure (repr a labs2)
(requires (sublist labs1 labs2))
(ensures (fun _ -> True))
= f
let ite (p q r : Type0) = (p ==> q) /\ (~p ==> r)
let if_then_else
(a : Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
(g : repr a labs2)
(p : bool)
: Type
= repr a (labs1@labs2)
total // need this for catch!!
reifiable
reflectable
effect {
EFF (a:Type) (_:list eff_label)
with {repr; return; bind; subcomp; if_then_else}
}
let lift_pure_eff
(a:Type)
(wp : pure_wp a)
(f : unit -> PURE a wp)
: Pure (repr a [])
(requires (wp (fun _ -> True)))
(ensures (fun _ -> True))
= FStar.Monotonic.Pure.elim_pure_wp_monotonicity wp;
fun s0 -> (Some (f ()), s0)
sub_effect PURE ~> EFF = lift_pure_eff
let get () : EFF int [RD] =
EFF?.reflect (fun s0 -> (Some s0, s0))
let put (s:state) : EFF unit [WR] =
EFF?.reflect (fun _ -> (Some (), s))
let raise #a () : EFF a [EXN] =
EFF?.reflect (fun s0 -> (None, s0))
let test0 (x y : int) : EFF int [RD; EXN] =
let z = get () in
if x + z > 0
then raise ()
else y - z
let test1 (x y : int) : EFF int [EXN; RD; WR] =
let z = get () in
if x + z > 0
then raise ()
else (put 42; y - z) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | l1: Prims.list Lattice.eff_label
-> FStar.Pervasives.Lemma (ensures Lattice.sublist (l1 @ l1) l1) [SMTPat (l1 @ l1)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Prims.list",
"Lattice.eff_label",
"FStar.Classical.forall_intro",
"Prims.b2t",
"Prims.op_Equality",
"Prims.bool",
"FStar.List.Tot.Base.mem",
"FStar.List.Tot.Base.op_At",
"Prims.op_BarBar",
"FStar.List.Tot.Properties.append_mem",
"Prims.unit",
"Prims.l_True",
"Prims.squash",
"Lattice.sublist",
"Prims.Cons",
"FStar.Pervasives.pattern",
"FStar.Pervasives.smt_pat",
"Prims.Nil"
] | [] | false | false | true | false | false | let sublist_at_self (l1: list eff_label) : Lemma (sublist (l1 @ l1) l1) [SMTPat (l1 @ l1)] =
| Classical.forall_intro (List.Tot.Properties.append_mem l1 l1) | false |
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.write_bounded_int32_le' | val write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32))) | val write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32))) | let write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
() | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 6,
"end_line": 516,
"start_col": 0,
"start_line": 500
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 ()
#push-options "--z3rlimit 20"
let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul
#pop-options
let write_bounded_integer_le_2 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_2 ()
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_le_3
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out pos (pos `U32.add` 1ul) (B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let write_bounded_integer_le_3 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_3 ()
let serialize32_bounded_integer_le_4
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h;
LE.store32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h h';
4ul
let write_bounded_integer_le_4 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_4 ()
let write_u16_le =
[@inline_let] let _ = synth_u16_le_injective; synth_u16_le_inverse in
write_synth write_bounded_integer_le_2 synth_u16_le synth_u16_le_recip (fun x -> synth_u16_le_recip x) ()
let write_u32_le =
write_synth write_bounded_integer_le_4 synth_u32_le synth_u32_le_recip (fun x -> synth_u32_le_recip x) ()
inline_for_extraction
let validate_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer_le sz)
(read_bounded_integer_le sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_le_1
min32 max32
= validate_bounded_int32_le' min32 max32 1
let validate_bounded_int32_le_2
min32 max32
= validate_bounded_int32_le' min32 max32 2
let validate_bounded_int32_le_3
min32 max32
= validate_bounded_int32_le' min32 max32 3
let validate_bounded_int32_le_4
min32 max32
= validate_bounded_int32_le' min32 max32 4
inline_for_extraction
let jump_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_le_1
min32 max32
= jump_bounded_int32_le' min32 max32 1
let jump_bounded_int32_le_2
min32 max32
= jump_bounded_int32_le' min32 max32 2
let jump_bounded_int32_le_3
min32 max32
= jump_bounded_int32_le' min32 max32 3
let jump_bounded_int32_le_4
min32 max32
= jump_bounded_int32_le' min32 max32 4 | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
min32: FStar.UInt32.t ->
max32:
FStar.UInt32.t
{ 0 < FStar.UInt32.v max32 /\ FStar.UInt32.v min32 <= FStar.UInt32.v max32 /\
FStar.UInt32.v max32 < 4294967296 } ->
sz: Prims.nat{sz == LowParse.Spec.BoundedInt.log256' (FStar.UInt32.v max32)}
-> LowParse.Low.Base.leaf_writer_strong (LowParse.Spec.BoundedInt.serialize_bounded_int32_le (FStar.UInt32.v
min32)
(FStar.UInt32.v max32)) | Prims.Tot | [
"total"
] | [] | [
"FStar.UInt32.t",
"Prims.l_and",
"Prims.b2t",
"Prims.op_LessThan",
"FStar.UInt32.v",
"Prims.op_LessThanOrEqual",
"Prims.nat",
"Prims.eq2",
"LowParse.Spec.BoundedInt.log256'",
"LowParse.Low.Combinators.write_synth",
"LowParse.Spec.Combinators.parse_filter_kind",
"LowParse.Spec.BoundedInt.parse_bounded_integer_kind",
"LowParse.Spec.Combinators.parse_filter_refine",
"LowParse.Spec.BoundedInt.bounded_integer",
"LowParse.Spec.BoundedInt.in_bounds",
"LowParse.Spec.Combinators.parse_filter",
"LowParse.Spec.BoundedInt.parse_bounded_integer_le",
"LowParse.Spec.Combinators.serialize_filter",
"LowParse.Spec.BoundedInt.serialize_bounded_integer_le",
"LowParse.Low.Combinators.write_filter",
"LowParse.Low.BoundedInt.write_bounded_integer_le",
"LowParse.Spec.BoundedInt.bounded_int32",
"FStar.UInt.uint_t",
"LowParse.Low.Base.leaf_writer_strong",
"LowParse.Spec.BoundedInt.parse_bounded_int32_kind",
"LowParse.Spec.BoundedInt.parse_bounded_int32_le",
"LowParse.Spec.BoundedInt.serialize_bounded_int32_le"
] | [] | false | false | false | false | false | let write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t{0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296})
(sz: nat{sz == log256' (U32.v max32)})
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32))) =
| [@@ inline_let ]let min = U32.v min32 in
[@@ inline_let ]let max = U32.v max32 in
write_synth (write_filter (write_bounded_integer_le sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
() | false |
Lattice.fst | Lattice.labpoly | val labpoly (#labs: _) (f g: (unit -> EFF int labs)) : EFF int labs | val labpoly (#labs: _) (f g: (unit -> EFF int labs)) : EFF int labs | let labpoly #labs (f g : unit -> EFF int labs) : EFF int labs =
f () + g () | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 13,
"end_line": 160,
"start_col": 0,
"start_line": 159
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0)
let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r
let subcomp (a:Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
: Pure (repr a labs2)
(requires (sublist labs1 labs2))
(ensures (fun _ -> True))
= f
let ite (p q r : Type0) = (p ==> q) /\ (~p ==> r)
let if_then_else
(a : Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
(g : repr a labs2)
(p : bool)
: Type
= repr a (labs1@labs2)
total // need this for catch!!
reifiable
reflectable
effect {
EFF (a:Type) (_:list eff_label)
with {repr; return; bind; subcomp; if_then_else}
}
let lift_pure_eff
(a:Type)
(wp : pure_wp a)
(f : unit -> PURE a wp)
: Pure (repr a [])
(requires (wp (fun _ -> True)))
(ensures (fun _ -> True))
= FStar.Monotonic.Pure.elim_pure_wp_monotonicity wp;
fun s0 -> (Some (f ()), s0)
sub_effect PURE ~> EFF = lift_pure_eff
let get () : EFF int [RD] =
EFF?.reflect (fun s0 -> (Some s0, s0))
let put (s:state) : EFF unit [WR] =
EFF?.reflect (fun _ -> (Some (), s))
let raise #a () : EFF a [EXN] =
EFF?.reflect (fun s0 -> (None, s0))
let test0 (x y : int) : EFF int [RD; EXN] =
let z = get () in
if x + z > 0
then raise ()
else y - z
let test1 (x y : int) : EFF int [EXN; RD; WR] =
let z = get () in
if x + z > 0
then raise ()
else (put 42; y - z)
let sublist_at_self (l1 : list eff_label)
: Lemma (sublist (l1@l1) l1)
[SMTPat (l1@l1)]
= Classical.forall_intro (List.Tot.Properties.append_mem l1 l1) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | f: (_: Prims.unit -> Lattice.EFF Prims.int) -> g: (_: Prims.unit -> Lattice.EFF Prims.int)
-> Lattice.EFF Prims.int | Lattice.EFF | [] | [] | [
"Prims.list",
"Lattice.eff_label",
"Prims.unit",
"Prims.int",
"Prims.op_Addition"
] | [] | false | true | false | false | false | let labpoly #labs (f: (unit -> EFF int labs)) (g: (unit -> EFF int labs)) : EFF int labs =
| f () + g () | false |
Lattice.fst | Lattice.g | val g: #labs: _ -> Prims.unit -> EFF int labs | val g: #labs: _ -> Prims.unit -> EFF int labs | let g #labs () : EFF int labs = 42 | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 34,
"end_line": 184,
"start_col": 0,
"start_line": 184
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0)
let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r
let subcomp (a:Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
: Pure (repr a labs2)
(requires (sublist labs1 labs2))
(ensures (fun _ -> True))
= f
let ite (p q r : Type0) = (p ==> q) /\ (~p ==> r)
let if_then_else
(a : Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
(g : repr a labs2)
(p : bool)
: Type
= repr a (labs1@labs2)
total // need this for catch!!
reifiable
reflectable
effect {
EFF (a:Type) (_:list eff_label)
with {repr; return; bind; subcomp; if_then_else}
}
let lift_pure_eff
(a:Type)
(wp : pure_wp a)
(f : unit -> PURE a wp)
: Pure (repr a [])
(requires (wp (fun _ -> True)))
(ensures (fun _ -> True))
= FStar.Monotonic.Pure.elim_pure_wp_monotonicity wp;
fun s0 -> (Some (f ()), s0)
sub_effect PURE ~> EFF = lift_pure_eff
let get () : EFF int [RD] =
EFF?.reflect (fun s0 -> (Some s0, s0))
let put (s:state) : EFF unit [WR] =
EFF?.reflect (fun _ -> (Some (), s))
let raise #a () : EFF a [EXN] =
EFF?.reflect (fun s0 -> (None, s0))
let test0 (x y : int) : EFF int [RD; EXN] =
let z = get () in
if x + z > 0
then raise ()
else y - z
let test1 (x y : int) : EFF int [EXN; RD; WR] =
let z = get () in
if x + z > 0
then raise ()
else (put 42; y - z)
let sublist_at_self (l1 : list eff_label)
: Lemma (sublist (l1@l1) l1)
[SMTPat (l1@l1)]
= Classical.forall_intro (List.Tot.Properties.append_mem l1 l1)
let labpoly #labs (f g : unit -> EFF int labs) : EFF int labs =
f () + g ()
let catch0 #a #labs (f:repr a (EXN::labs)) (g:repr a labs)
: repr a labs
= fun s0 ->
let r0 : option a & state = f s0 in
let r1 : option a & state =
match r0 with
| (Some v, s1) -> (Some v, s1)
| (None, s1) -> g s1
| _ -> unreachable ()
in
r1
let catch #a #labs
(f : unit -> EFF a (EXN::labs))
(g : unit -> EFF a labs)
: EFF a labs
= EFF?.reflect (catch0 (reify (f ())) (reify (g ())))
// TODO: haskell-like runST.
// strong update with index on state type(s)? | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | _: Prims.unit -> Lattice.EFF Prims.int | Lattice.EFF | [] | [] | [
"Prims.list",
"Lattice.eff_label",
"Prims.unit",
"Prims.int"
] | [] | false | true | false | false | false | let g #labs () : EFF int labs =
| 42 | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.fmul | val fmul : x: Spec.Poly1305.felem -> y: Spec.Poly1305.felem -> Spec.Poly1305.felem | let fmul = S.fmul | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 24,
"end_line": 26,
"start_col": 7,
"start_line": 26
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Spec.Poly1305.felem -> y: Spec.Poly1305.felem -> Spec.Poly1305.felem | Prims.Tot | [
"total"
] | [] | [
"Spec.Poly1305.fmul"
] | [] | false | false | false | true | false | let fmul =
| S.fmul | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.fadd | val fadd : x: Spec.Poly1305.felem -> y: Spec.Poly1305.felem -> Spec.Poly1305.felem | let fadd = S.fadd | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 24,
"end_line": 25,
"start_col": 7,
"start_line": 25
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Spec.Poly1305.felem -> y: Spec.Poly1305.felem -> Spec.Poly1305.felem | Prims.Tot | [
"total"
] | [] | [
"Spec.Poly1305.fadd"
] | [] | false | false | false | true | false | let fadd =
| S.fadd | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.uint_from_bytes_le | val uint_from_bytes_le : b: Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 l) (Lib.IntTypes.numbytes t)
-> Lib.IntTypes.int_t t l | let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 79,
"end_line": 22,
"start_col": 7,
"start_line": 22
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | b: Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 l) (Lib.IntTypes.numbytes t)
-> Lib.IntTypes.int_t t l | Prims.Tot | [
"total"
] | [] | [
"Lib.IntTypes.inttype",
"Prims.l_and",
"Prims.b2t",
"Lib.IntTypes.unsigned",
"Prims.l_not",
"Lib.IntTypes.uu___is_U1",
"Lib.IntTypes.secrecy_level",
"Lib.ByteSequence.uint_from_bytes_le",
"Lib.Sequence.lseq",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.numbytes"
] | [] | false | false | false | false | false | let uint_from_bytes_le #t #l =
| Lib.ByteSequence.uint_from_bytes_le #t #l | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.felem | val felem : Type0 | let felem = S.felem | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 26,
"end_line": 24,
"start_col": 7,
"start_line": 24
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Type0 | Prims.Tot | [
"total"
] | [] | [
"Spec.Poly1305.felem"
] | [] | false | false | false | true | true | let felem =
| S.felem | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.sub | val sub : s1: Lib.Sequence.lseq a len ->
start: n: Prims.nat{n <= Prims.pow2 32 - 1} ->
n: (n: Prims.nat{n <= Prims.pow2 32 - 1}){start + n <= len}
-> s2:
Lib.Sequence.lseq a n
{ Lib.Sequence.to_seq s2 == FStar.Seq.Base.slice (Lib.Sequence.to_seq s1) start (start + n) /\
(forall (k: Prims.nat{k < n}). {:pattern Lib.Sequence.index s2 k}
Lib.Sequence.index s2 k == Lib.Sequence.index s1 (start + k)) } | let sub #a #len = Lib.Sequence.sub #a #len | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 49,
"end_line": 20,
"start_col": 7,
"start_line": 20
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
s1: Lib.Sequence.lseq a len ->
start: n: Prims.nat{n <= Prims.pow2 32 - 1} ->
n: (n: Prims.nat{n <= Prims.pow2 32 - 1}){start + n <= len}
-> s2:
Lib.Sequence.lseq a n
{ Lib.Sequence.to_seq s2 == FStar.Seq.Base.slice (Lib.Sequence.to_seq s1) start (start + n) /\
(forall (k: Prims.nat{k < n}). {:pattern Lib.Sequence.index s2 k}
Lib.Sequence.index s2 k == Lib.Sequence.index s1 (start + k)) } | Prims.Tot | [
"total"
] | [] | [
"Lib.IntTypes.size_nat",
"Lib.Sequence.sub",
"Lib.Sequence.lseq",
"Prims.nat",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"Prims.op_Subtraction",
"Prims.pow2",
"Prims.op_Addition",
"Prims.l_and",
"Prims.eq2",
"FStar.Seq.Base.seq",
"Lib.Sequence.to_seq",
"FStar.Seq.Base.slice",
"Prims.l_Forall",
"Prims.op_LessThan",
"Prims.l_or",
"FStar.Seq.Base.index",
"Lib.Sequence.index"
] | [] | false | false | false | false | false | let sub #a #len =
| Lib.Sequence.sub #a #len | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.modp | val modp : x: Prims.int -> Prims.int | let modp = V.modp | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 24,
"end_line": 28,
"start_col": 7,
"start_line": 28
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd
unfold let fmul = S.fmul | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Prims.int -> Prims.int | Prims.Tot | [
"total"
] | [] | [
"Vale.Poly1305.Spec_s.modp"
] | [] | false | false | false | true | false | let modp =
| V.modp | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.mod2_128 | val mod2_128 : x: Prims.int -> Prims.int | let mod2_128 = V.mod2_128 | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 32,
"end_line": 29,
"start_col": 7,
"start_line": 29
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd
unfold let fmul = S.fmul
unfold let to_felem = S.to_felem | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Prims.int -> Prims.int | Prims.Tot | [
"total"
] | [] | [
"Vale.Poly1305.Spec_s.mod2_128"
] | [] | false | false | false | true | false | let mod2_128 =
| V.mod2_128 | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.prime | val prime : Prims.pos | let prime = S.prime | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 26,
"end_line": 23,
"start_col": 7,
"start_line": 23
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Prims.pos | Prims.Tot | [
"total"
] | [] | [
"Spec.Poly1305.prime"
] | [] | false | false | false | true | false | let prime =
| S.prime | false |
|
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.lbytes | val lbytes : len: Lib.IntTypes.size_nat -> Type0 | let lbytes = Lib.ByteSequence.lbytes | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 43,
"end_line": 21,
"start_col": 7,
"start_line": 21
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | len: Lib.IntTypes.size_nat -> Type0 | Prims.Tot | [
"total"
] | [] | [
"Lib.ByteSequence.lbytes"
] | [] | false | false | false | true | true | let lbytes =
| Lib.ByteSequence.lbytes | false |
|
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.validate_bounded_int32_le_fixed_size | val validate_bounded_int32_le_fixed_size
(min32: U32.t)
(max32: U32.t { U32.v min32 <= U32.v max32 })
: Tot (validator (parse_bounded_int32_le_fixed_size (U32.v min32) (U32.v max32))) | val validate_bounded_int32_le_fixed_size
(min32: U32.t)
(max32: U32.t { U32.v min32 <= U32.v max32 })
: Tot (validator (parse_bounded_int32_le_fixed_size (U32.v min32) (U32.v max32))) | let validate_bounded_int32_le_fixed_size
min32 max32
= validate_filter (validate_u32_le ()) read_u32_le (in_bounds (U32.v min32) (U32.v max32)) (fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x)) | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 144,
"end_line": 572,
"start_col": 0,
"start_line": 570
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 ()
#push-options "--z3rlimit 20"
let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul
#pop-options
let write_bounded_integer_le_2 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_2 ()
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_le_3
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out pos (pos `U32.add` 1ul) (B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let write_bounded_integer_le_3 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_3 ()
let serialize32_bounded_integer_le_4
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h;
LE.store32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.le_to_n s == U32.v v) h h';
4ul
let write_bounded_integer_le_4 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_4 ()
let write_u16_le =
[@inline_let] let _ = synth_u16_le_injective; synth_u16_le_inverse in
write_synth write_bounded_integer_le_2 synth_u16_le synth_u16_le_recip (fun x -> synth_u16_le_recip x) ()
let write_u32_le =
write_synth write_bounded_integer_le_4 synth_u32_le synth_u32_le_recip (fun x -> synth_u32_le_recip x) ()
inline_for_extraction
let validate_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer_le sz)
(read_bounded_integer_le sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_le_1
min32 max32
= validate_bounded_int32_le' min32 max32 1
let validate_bounded_int32_le_2
min32 max32
= validate_bounded_int32_le' min32 max32 2
let validate_bounded_int32_le_3
min32 max32
= validate_bounded_int32_le' min32 max32 3
let validate_bounded_int32_le_4
min32 max32
= validate_bounded_int32_le' min32 max32 4
inline_for_extraction
let jump_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_le_1
min32 max32
= jump_bounded_int32_le' min32 max32 1
let jump_bounded_int32_le_2
min32 max32
= jump_bounded_int32_le' min32 max32 2
let jump_bounded_int32_le_3
min32 max32
= jump_bounded_int32_le' min32 max32 3
let jump_bounded_int32_le_4
min32 max32
= jump_bounded_int32_le' min32 max32 4
inline_for_extraction
let write_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32_le (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer_le sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_le_1
min32 max32
= write_bounded_int32_le' min32 max32 1
let write_bounded_int32_le_2
min32 max32
= write_bounded_int32_le' min32 max32 2
let write_bounded_int32_le_3
min32 max32
= write_bounded_int32_le' min32 max32 3
let write_bounded_int32_le_4
min32 max32
= write_bounded_int32_le' min32 max32 4
inline_for_extraction
let read_bounded_int32_le'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32_le (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer_le sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer_le sz)
(in_bounds min max))
()
let read_bounded_int32_le_1
min32 max32
= read_bounded_int32_le' min32 max32 1
let read_bounded_int32_le_2
min32 max32
= read_bounded_int32_le' min32 max32 2
let read_bounded_int32_le_3
min32 max32
= read_bounded_int32_le' min32 max32 3
let read_bounded_int32_le_4
min32 max32
= read_bounded_int32_le' min32 max32 4 | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | min32: FStar.UInt32.t -> max32: FStar.UInt32.t{FStar.UInt32.v min32 <= FStar.UInt32.v max32}
-> LowParse.Low.Base.validator (LowParse.Spec.BoundedInt.parse_bounded_int32_le_fixed_size (FStar.UInt32.v
min32)
(FStar.UInt32.v max32)) | Prims.Tot | [
"total"
] | [] | [
"FStar.UInt32.t",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"FStar.UInt32.v",
"LowParse.Low.Combinators.validate_filter",
"LowParse.Spec.Int.parse_u32_kind",
"LowParse.Spec.BoundedInt.parse_u32_le",
"LowParse.Low.BoundedInt.validate_u32_le",
"LowParse.Low.BoundedInt.read_u32_le",
"LowParse.Spec.BoundedInt.in_bounds",
"Prims.op_Negation",
"Prims.op_BarBar",
"FStar.UInt32.lt",
"Prims.bool",
"Prims.eq2",
"LowParse.Low.Base.validator",
"LowParse.Spec.BoundedInt.parse_bounded_int32_fixed_size_kind",
"LowParse.Spec.BoundedInt.bounded_int32",
"LowParse.Spec.BoundedInt.parse_bounded_int32_le_fixed_size"
] | [] | false | false | false | false | false | let validate_bounded_int32_le_fixed_size min32 max32 =
| validate_filter (validate_u32_le ())
read_u32_le
(in_bounds (U32.v min32) (U32.v max32))
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x)) | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.to_felem | val to_felem : x: Prims.nat{x < Spec.Poly1305.prime} -> Spec.Poly1305.felem | let to_felem = S.to_felem | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 32,
"end_line": 27,
"start_col": 7,
"start_line": 27
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Prims.nat{x < Spec.Poly1305.prime} -> Spec.Poly1305.felem | Prims.Tot | [
"total"
] | [] | [
"Spec.Poly1305.to_felem"
] | [] | false | false | false | false | false | let to_felem =
| S.to_felem | false |
|
Lattice.fst | Lattice.test0 | val test0 (x y: int) : EFF int [RD; EXN] | val test0 (x y: int) : EFF int [RD; EXN] | let test0 (x y : int) : EFF int [RD; EXN] =
let z = get () in
if x + z > 0
then raise ()
else y - z | {
"file_name": "examples/layeredeffects/Lattice.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 12,
"end_line": 146,
"start_col": 0,
"start_line": 142
} | module Lattice
open FStar.Tactics.V2
open FStar.List.Tot
// GM: Force a type equality by SMT
let coerce #a #b (x:a{a == b}) : b = x
let unreachable #a () : Pure a (requires False) (ensures (fun _ -> False)) = coerce "whatever"
type eff_label =
| RD
| WR
//| DIV
| EXN
// DONE: split ST into READ/WRITE with relational prop on abides
// ^ this was incredibly easy
// DONE add specs (see LatticeSpec.fst)
type annot = eff_label -> bool
type state = int
type repr0 (a:Type u#aa) : Type u#aa =
state -> Tot (option a & state)
let abides #a (f : repr0 a) (ann:annot) : prop =
(ann RD = false ==> (forall s0 s1. fst (f s0) == fst (f s1)))
/\ (ann WR = false ==> (forall s0. snd (f s0) == s0))
/\ (ann EXN = false ==> (forall s0. Some? (fst (f s0))))
let interp (l : list eff_label) : annot =
fun lab -> mem lab l
let rec interp_at (l1 l2 : list eff_label) (l : eff_label)
: Lemma (interp (l1@l2) l == (interp l1 l || interp l2 l))
[SMTPat (interp (l1@l2) l)]
= match l1 with
| [] -> ()
| _::l1 -> interp_at l1 l2 l
let sublist (l1 l2 : list eff_label) =
forall x. mem x l1 ==> mem x l2
let sublist_refl
(l : list eff_label)
: Lemma (sublist l l)
[SMTPat (sublist l l)]
= ()
let rec interp_sublist (l1 l2 : list eff_label) (l : eff_label)
: Lemma (requires (sublist l1 l2))
(ensures (interp l1 l ==> interp l2 l))
[SMTPat (interp l1 l); SMTPat (sublist l1 l2)]
= match l1 with
| [] -> ()
| _::l1 -> interp_sublist l1 l2 l
let rec sublist_at
(l1 l2 : list eff_label)
: Lemma (sublist l1 (l1@l2) /\ sublist l2 (l1@l2))
[SMTPatOr [[SMTPat (sublist l1 (l1@l2))];
[SMTPat (sublist l2 (l1@l2))]]]
= match l1 with
| [] -> ()
| _::l1 -> sublist_at l1 l2
type repr (a:Type)
(labs : list eff_label)
: Type =
r:(repr0 a){abides r (interp labs)}
let ann_le (ann1 ann2 : annot) : prop =
forall x. ann1 x ==> ann2 x
let return (a:Type) (x:a)
: repr a [] =
fun s0 -> (Some x, s0)
let bind (a b : Type)
(labs1 labs2 : list eff_label)
(c : repr a labs1)
(f : (x:a -> repr b labs2))
: Tot (repr b (labs1@labs2))
= let r =
fun s0 -> match c s0 with
| Some x, s1 -> f x s1
| None, s1 -> None, s1
in
r
let subcomp (a:Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
: Pure (repr a labs2)
(requires (sublist labs1 labs2))
(ensures (fun _ -> True))
= f
let ite (p q r : Type0) = (p ==> q) /\ (~p ==> r)
let if_then_else
(a : Type)
(labs1 labs2 : list eff_label)
(f : repr a labs1)
(g : repr a labs2)
(p : bool)
: Type
= repr a (labs1@labs2)
total // need this for catch!!
reifiable
reflectable
effect {
EFF (a:Type) (_:list eff_label)
with {repr; return; bind; subcomp; if_then_else}
}
let lift_pure_eff
(a:Type)
(wp : pure_wp a)
(f : unit -> PURE a wp)
: Pure (repr a [])
(requires (wp (fun _ -> True)))
(ensures (fun _ -> True))
= FStar.Monotonic.Pure.elim_pure_wp_monotonicity wp;
fun s0 -> (Some (f ()), s0)
sub_effect PURE ~> EFF = lift_pure_eff
let get () : EFF int [RD] =
EFF?.reflect (fun s0 -> (Some s0, s0))
let put (s:state) : EFF unit [WR] =
EFF?.reflect (fun _ -> (Some (), s))
let raise #a () : EFF a [EXN] =
EFF?.reflect (fun s0 -> (None, s0)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.V2.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Monotonic.Pure.fst.checked",
"FStar.List.Tot.Properties.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "Lattice.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.List.Tot",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | x: Prims.int -> y: Prims.int -> Lattice.EFF Prims.int | Lattice.EFF | [] | [] | [
"Prims.int",
"Prims.op_GreaterThan",
"Prims.op_Addition",
"Lattice.raise",
"Prims.bool",
"Prims.op_Subtraction",
"Lattice.get",
"Prims.Cons",
"Lattice.eff_label",
"Lattice.RD",
"Lattice.EXN",
"Prims.Nil"
] | [] | false | true | false | false | false | let test0 (x y: int) : EFF int [RD; EXN] =
| let z = get () in
if x + z > 0 then raise () else y - z | false |
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.serialize32_bounded_integer_3 | val serialize32_bounded_integer_3 : unit -> Tot (serializer32 (serialize_bounded_integer 3)) | val serialize32_bounded_integer_3 : unit -> Tot (serializer32 (serialize_bounded_integer 3)) | let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 5,
"end_line": 141,
"start_col": 0,
"start_line": 123
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16" | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 16,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | _: Prims.unit
-> LowParse.Low.Base.serializer32 (LowParse.Spec.BoundedInt.serialize_bounded_integer 3) | Prims.Tot | [
"total"
] | [] | [
"Prims.unit",
"LowParse.Spec.BoundedInt.bounded_integer",
"LowStar.Monotonic.Buffer.srel",
"LowParse.Bytes.byte",
"LowStar.Monotonic.Buffer.mbuffer",
"FStar.UInt32.t",
"FStar.UInt32.__uint_to_t",
"Prims._assert",
"FStar.Seq.Base.equal",
"FStar.Seq.Base.slice",
"LowStar.Monotonic.Buffer.as_seq",
"Prims.op_Addition",
"FStar.UInt32.v",
"FStar.Seq.Base.create",
"LowStar.Monotonic.Buffer.modifies_buffer_from_to_elim",
"FStar.UInt32.add",
"LowStar.Monotonic.Buffer.loc_buffer_from_to",
"LowParse.Low.Endianness.store_post_modifies",
"FStar.Seq.Base.seq",
"Prims.eq2",
"Prims.int",
"Prims.l_or",
"Prims.b2t",
"Prims.op_GreaterThanOrEqual",
"FStar.UInt.size",
"FStar.UInt16.n",
"FStar.Endianness.be_to_n",
"FStar.UInt16.v",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"LowStar.Endianness.store16_be_i",
"LowParse.Low.Endianness.writable_store_pre",
"LowParse.Low.Base.writable_weaken",
"FStar.UInt16.t",
"Prims.op_Equality",
"Prims.op_Modulus",
"Prims.pow2",
"FStar.Int.Cast.uint32_to_uint16",
"FStar.Math.Lemmas.small_mod",
"Prims.op_Division",
"LowParse.Low.BoundedInt.div256",
"LowParse.Low.Base.mbuffer_upd",
"FStar.Ghost.hide",
"Prims.nat",
"FStar.UInt8.t",
"FStar.UInt8.v",
"FStar.Int.Cast.uint32_to_uint8",
"FStar.Pervasives.assert_norm",
"LowParse.Endianness.reveal_n_to_be",
"LowParse.Spec.BoundedInt.bounded_integer_prop_equiv"
] | [] | false | false | false | false | false | let serialize32_bounded_integer_3 () =
| fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out
(pos `U32.add` 2ul)
(pos `U32.add` 3ul)
(B.loc_buffer_from_to out pos (pos `U32.add` 2ul))
h1
h2;
assert ((Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3))
`Seq.equal`
(Seq.create 1 lo));
3ul | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_key | val test1_key:lbytes 20 | val test1_key:lbytes 20 | let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 24,
"start_col": 0,
"start_line": 17
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 20 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_key:lbytes 20 =
| let l =
List.Tot.map u8_from_UInt8
[
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy
]
in
assert_norm (List.Tot.length l == 20);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_data | val test1_data:lbytes 8 | val test1_data:lbytes 8 | let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 32,
"start_col": 0,
"start_line": 27
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 8 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_data:lbytes 8 =
| let l =
List.Tot.map u8_from_UInt8 [0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy]
in
assert_norm (List.Tot.length l == 8);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_expected224 | val test1_expected224:lbytes 28 | val test1_expected224:lbytes 28 | let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 43,
"start_col": 0,
"start_line": 35
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy; 0x68uy; 0x32uy; 0x10uy; 0x7cuy;
0xd4uy; 0x9duy; 0xf3uy; 0x3fuy; 0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_key | val test3_key:lbytes 20 | val test3_key:lbytes 20 | let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 163,
"start_col": 0,
"start_line": 156
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 20 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_key:lbytes 20 =
| let l =
List.Tot.map u8_from_UInt8
[
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy
]
in
assert_norm (List.Tot.length l == 20);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_expected224 | val test2_expected224:lbytes 28 | val test2_expected224:lbytes 28 | let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 112,
"start_col": 0,
"start_line": 104
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy; 0x45uy; 0x69uy; 0x0fuy; 0x3auy;
0x7euy; 0x9euy; 0x6duy; 0x0fuy; 0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_expected256 | val test1_expected256:lbytes 32 | val test1_expected256:lbytes 32 | let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 54,
"start_col": 0,
"start_line": 46
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy; 0x5cuy; 0xa8uy; 0xafuy; 0xceuy;
0xafuy; 0x0buy; 0xf1uy; 0x2buy; 0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_data | val test3_data:lbytes 50 | val test3_data:lbytes 50 | let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 177,
"start_col": 0,
"start_line": 166
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 50 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_data:lbytes 50 =
| let l =
List.Tot.map u8_from_UInt8
[
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
]
in
assert_norm (List.Tot.length l == 50);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_key | val test5_key:lbytes 20 | val test5_key:lbytes 20 | let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 316,
"start_col": 0,
"start_line": 309
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 20 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_key:lbytes 20 =
| let l =
List.Tot.map u8_from_UInt8
[
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
]
in
assert_norm (List.Tot.length l == 20);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_expected256 | val test3_expected256:lbytes 32 | val test3_expected256:lbytes 32 | let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 199,
"start_col": 0,
"start_line": 191
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy; 0x85uy; 0x4duy; 0xb8uy; 0xebuy;
0xd0uy; 0x91uy; 0x81uy; 0xa7uy; 0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_data | val test2_data:lbytes 28 | val test2_data:lbytes 28 | let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 101,
"start_col": 0,
"start_line": 93
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_data:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy; 0x79uy; 0x61uy; 0x20uy; 0x77uy;
0x61uy; 0x6euy; 0x74uy; 0x20uy; 0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_key | val test4_key:lbytes 25 | val test4_key:lbytes 25 | let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 240,
"start_col": 0,
"start_line": 232
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 25 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_key:lbytes 25 =
| let l =
List.Tot.map u8_from_UInt8
[
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy; 0x09uy; 0x0auy; 0x0buy; 0x0cuy;
0x0duy; 0x0euy; 0x0fuy; 0x10uy; 0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
]
in
assert_norm (List.Tot.length l == 25);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_expected384 | val test1_expected384:lbytes 48 | val test1_expected384:lbytes 48 | let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 67,
"start_col": 0,
"start_line": 57
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy; 0x6buy; 0x08uy; 0x25uy; 0xf4uy;
0xabuy; 0x46uy; 0x90uy; 0x7fuy; 0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy; 0xfauy; 0xeauy; 0x9euy; 0xa9uy;
0x07uy; 0x6euy; 0xdeuy; 0x7fuy; 0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_data | val test4_data:lbytes 50 | val test4_data:lbytes 50 | let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 254,
"start_col": 0,
"start_line": 243
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 50 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_data:lbytes 50 =
| let l =
List.Tot.map u8_from_UInt8
[
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
]
in
assert_norm (List.Tot.length l == 50);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_expected224 | val test3_expected224:lbytes 28 | val test3_expected224:lbytes 28 | let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 188,
"start_col": 0,
"start_line": 180
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy; 0xffuy; 0xa9uy; 0x69uy; 0x4duy;
0x7duy; 0x6auy; 0xd2uy; 0x64uy; 0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_key | val test2_key:lbytes 4 | val test2_key:lbytes 4 | let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 90,
"start_col": 0,
"start_line": 87
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 4 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_key:lbytes 4 =
| let l = List.Tot.map u8_from_UInt8 [0x4auy; 0x65uy; 0x66uy; 0x65uy] in
assert_norm (List.Tot.length l == 4);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_expected256 | val test4_expected256:lbytes 32 | val test4_expected256:lbytes 32 | let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 276,
"start_col": 0,
"start_line": 268
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy; 0xa4uy; 0xccuy; 0x81uy; 0x98uy;
0x99uy; 0xf2uy; 0x08uy; 0x3auy; 0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_expected384 | val test2_expected384:lbytes 48 | val test2_expected384:lbytes 48 | let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 136,
"start_col": 0,
"start_line": 126
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy; 0x61uy; 0x7fuy; 0x78uy; 0xd2uy;
0xb5uy; 0x8auy; 0x6buy; 0x1buy; 0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy; 0x8euy; 0x22uy; 0x40uy; 0xcauy;
0x5euy; 0x69uy; 0xe2uy; 0xc7uy; 0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_expected224 | val test5_expected224:lbytes 16 | val test5_expected224:lbytes 16 | let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 335,
"start_col": 0,
"start_line": 329
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 16 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_expected224:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy; 0xc9uy; 0x88uy; 0xbcuy; 0xdbuy;
0x9fuy; 0xcauy; 0x6fuy; 0xa8uy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_expected256 | val test2_expected256:lbytes 32 | val test2_expected256:lbytes 32 | let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 123,
"start_col": 0,
"start_line": 115
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy; 0x6auy; 0x04uy; 0x24uy; 0x26uy;
0x08uy; 0x95uy; 0x75uy; 0xc7uy; 0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
LowParse.Low.BoundedInt.fst | LowParse.Low.BoundedInt.serialize32_bounded_integer_le_3 | val serialize32_bounded_integer_le_3 : serializer32 (serialize_bounded_integer_le 3) | val serialize32_bounded_integer_le_3 : serializer32 (serialize_bounded_integer_le 3) | let serialize32_bounded_integer_le_3
= fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out pos (pos `U32.add` 1ul) (B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1) `Seq.equal` Seq.create 1 lo);
3ul | {
"file_name": "src/lowparse/LowParse.Low.BoundedInt.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 5,
"end_line": 403,
"start_col": 0,
"start_line": 385
} | module LowParse.Low.BoundedInt
open LowParse.Low.Combinators
module Seq = FStar.Seq
module U8 = FStar.UInt8
module U16 = FStar.UInt16
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module HS = FStar.HyperStack
module B = LowStar.Buffer
module E = LowParse.Endianness.BitFields
module BF = LowParse.BitFields
module LE = LowParse.Low.Endianness
module Cast = FStar.Int.Cast
friend LowParse.Spec.BoundedInt
inline_for_extraction
let mul256 (x: U16.t) : Tot (y: U32.t { U32.v y == 256 `Prims.op_Multiply` U16.v x }) =
assert_norm (pow2 8 == 256);
FStar.Math.Lemmas.pow2_lt_compat 32 24;
FStar.Math.Lemmas.pow2_lt_compat 24 16;
FStar.Math.Lemmas.pow2_lt_compat 16 8;
FStar.Math.Lemmas.pow2_plus 8 16;
FStar.Math.Lemmas.small_mod (U16.v x `Prims.op_Multiply` 256) (pow2 32);
FStar.UInt.shift_left_value_lemma #32 (U16.v x) 8;
Cast.uint16_to_uint32 x `U32.shift_left` 8ul
inline_for_extraction
let div256 (x: U32.t) : Tot (y: U32.t { U32.v y == U32.v x / 256 }) =
assert_norm (pow2 8 == 256);
FStar.UInt.shift_right_value_lemma #32 (U32.v x) 8;
x `U32.shift_right` 8ul
(* bounded integers *)
let read_bounded_integer_1 () =
[@inline_let]
let _ =
decode_bounded_integer_injective 1
in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (decode_bounded_integer 1) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.index_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 1));
let r = B.index input pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_2 () =
[@inline_let] let _ =
decode_bounded_integer_injective 2
in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (decode_bounded_integer 2) () (fun #rrel #rel input pos ->
let h = HST.get () in
let r = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_3 () =
[@inline_let] let _ =
decode_bounded_integer_injective 3
in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (decode_bounded_integer 3) () (fun #rrel #rel input pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3)) 2;
E.reveal_be_to_n (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
let lo = B.index input (pos `U32.add` 2ul) in
let hi = LE.load16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 2));
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_4 () =
[@inline_let] let _ =
decode_bounded_integer_injective 4
in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (decode_bounded_integer 4) () (fun #rrel #rel input pos ->
let h = HST.get () in
E.lemma_be_to_n_is_bounded (Seq.slice (B.as_seq h input) (U32.v pos) (U32.v pos + 4));
LE.load32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) input pos
)
let read_bounded_integer_ct
i #rrel #rel sl pos
= let h = HST.get () in
valid_total_constant_size h (parse_bounded_integer (U32.v i)) (U32.v i) sl pos;
valid_facts (parse_bounded_integer (U32.v i)) h sl pos;
valid_total_constant_size h parse_u32 4 sl pos;
valid_facts parse_u32 h sl pos;
decode_bounded_integer_injective (U32.v i);
parse_u32_spec (bytes_of_slice_from h sl pos);
E.bitfield_be_to_n_slice (Seq.slice (bytes_of_slice_from h sl pos) 0 4) 0 (U32.v i);
let r = LE.load32_be_i sl.base pos in
BF.uint32.BF.get_bitfield_gen r (8ul `U32.mul` (4ul `U32.sub` i)) 32ul
let serialize32_bounded_integer_1 () =
fun (v: bounded_integer 1) #rrel #rel out pos ->
bounded_integer_prop_equiv 1 v;
E.index_n_to_be 1 (U32.v v) 0;
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 v);
1ul
let serialize32_bounded_integer_2 () =
fun (v: bounded_integer 2) #rrel #rel out pos ->
bounded_integer_prop_equiv 2 v;
let h = HST.get () in
let v' = (Cast.uint32_to_uint16 v) in
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v';
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v v') h h';
2ul
#push-options "--z3rlimit 16"
let serialize32_bounded_integer_3 () =
fun (v: bounded_integer 3) #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_be 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) (pos `U32.add` 2ul) lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos) (U32.v pos + 2);
LE.writable_store_pre out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1;
LE.store16_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos) 2 (fun s -> E.be_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out (pos `U32.add` 2ul) (pos `U32.add` 3ul) (B.loc_buffer_from_to out pos (pos `U32.add` 2ul)) h1 h2;
assert (Seq.slice (B.as_seq h2 out) (U32.v pos + 2) (U32.v pos + 3) `Seq.equal` Seq.create 1 lo);
3ul
#pop-options
let serialize32_bounded_integer_4 () =
fun (v: bounded_integer 4) #rrel #rel out pos ->
bounded_integer_prop_equiv 4 v;
let h = HST.get () in
LE.writable_store_pre out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h;
LE.store32_be_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) out pos v;
let h' = HST.get () in
LE.store_post_modifies out (U32.v pos) 4 (fun s -> E.be_to_n s == U32.v v) h h';
4ul
inline_for_extraction
let write_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_writer_strong (serialize_bounded_int32 (U32.v min32) (U32.v max32)))
= [@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
write_synth
(write_filter
(write_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(fun x -> x)
()
let write_bounded_int32_1
min32 max32
= write_bounded_int32' min32 max32 1
let write_bounded_int32_2
min32 max32
= write_bounded_int32' min32 max32 2
let write_bounded_int32_3
min32 max32
= write_bounded_int32' min32 max32 3
let write_bounded_int32_4
min32 max32
= write_bounded_int32' min32 max32 4
inline_for_extraction
let read_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (leaf_reader (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
read_inline_synth
(parse_filter (parse_bounded_integer sz) (in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
(fun x -> x)
(read_filter
(read_bounded_integer sz)
(in_bounds min max))
()
let read_bounded_int32_1
min32 max32
= read_bounded_int32' min32 max32 1
let read_bounded_int32_2
min32 max32
= read_bounded_int32' min32 max32 2
let read_bounded_int32_3
min32 max32
= read_bounded_int32' min32 max32 3
let read_bounded_int32_4
min32 max32
= read_bounded_int32' min32 max32 4
inline_for_extraction
let validate_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (validator (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
validate_synth
(validate_filter
(validate_bounded_integer sz)
(read_bounded_integer sz)
(in_bounds min max)
(fun x -> not (x `U32.lt` min32 || max32 `U32.lt` x))
)
(fun x -> (x <: bounded_int32 min max))
()
let validate_bounded_int32_1
min32 max32
= validate_bounded_int32' min32 max32 1
let validate_bounded_int32_2
min32 max32
= validate_bounded_int32' min32 max32 2
let validate_bounded_int32_3
min32 max32
= validate_bounded_int32' min32 max32 3
let validate_bounded_int32_4
min32 max32
= validate_bounded_int32' min32 max32 4
inline_for_extraction
let jump_bounded_int32'
(min32: U32.t)
(max32: U32.t { 0 < U32.v max32 /\ U32.v min32 <= U32.v max32 /\ U32.v max32 < 4294967296 })
(sz: nat { sz == log256' (U32.v max32) })
: Tot (jumper (parse_bounded_int32 (U32.v min32) (U32.v max32)))
=
[@inline_let]
let min = U32.v min32 in
[@inline_let]
let max = U32.v max32 in
jump_synth
(jump_filter
(jump_bounded_integer sz)
(in_bounds min max))
(fun x -> (x <: bounded_int32 min max))
()
let jump_bounded_int32_1
min32 max32
= jump_bounded_int32' min32 max32 1
let jump_bounded_int32_2
min32 max32
= jump_bounded_int32' min32 max32 2
let jump_bounded_int32_3
min32 max32
= jump_bounded_int32' min32 max32 3
let jump_bounded_int32_4
min32 max32
= jump_bounded_int32' min32 max32 4
let read_bounded_integer_le_1 =
[@inline_let] let _ = bounded_integer_of_le_injective 1 in
make_total_constant_size_reader 1 1ul #(bounded_integer 1) (bounded_integer_of_le 1) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.index_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1)) 0;
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 1));
let r = B.index b pos in
Cast.uint8_to_uint32 r
)
let read_bounded_integer_le_2 =
[@inline_let] let _ = bounded_integer_of_le_injective 2 in
make_total_constant_size_reader 2 2ul #(bounded_integer 2) (bounded_integer_of_le 2) () (fun #rrel #rel b pos ->
let h = HST.get () in
let r = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 2));
Cast.uint16_to_uint32 r
)
#push-options "--z3rlimit 16"
let read_bounded_integer_le_3 =
[@inline_let] let _ = bounded_integer_of_le_injective 3 in
make_total_constant_size_reader 3 3ul #(bounded_integer 3) (bounded_integer_of_le 3) () (fun #rrel #rel b pos ->
let h = HST.get () in
Seq.lemma_split (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3)) 1;
E.reveal_le_to_n (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
let lo = B.index b pos in
let hi = LE.load16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b (pos `U32.add` 1ul) in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos + 1) (U32.v pos + 3));
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 3));
assert_norm (pow2 8 == 256);
Cast.uint8_to_uint32 lo `U32.add` (mul256 hi)
)
#pop-options
let read_bounded_integer_le_4 =
[@inline_let] let _ = bounded_integer_of_le_injective 4 in
make_total_constant_size_reader 4 4ul #(bounded_integer 4) (bounded_integer_of_le 4) () (fun #rrel #rel b pos ->
let h = HST.get () in
E.lemma_le_to_n_is_bounded (Seq.slice (B.as_seq h b) (U32.v pos) (U32.v pos + 4));
LE.load32_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos
)
let read_u16_le =
[@inline_let] let _ = synth_u16_le_injective in
read_inline_synth'
_
synth_u16_le
read_bounded_integer_le_2
()
let read_u32_le =
read_inline_synth'
_
synth_u32_le
read_bounded_integer_le_4
()
let serialize32_bounded_integer_le_1
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 1 x;
E.index_n_to_le 1 (U32.v x) 0;
mbuffer_upd b (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 1)) pos (Cast.uint32_to_uint8 x);
1ul
let write_bounded_integer_le_1
= leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_1 ()
#push-options "--z3rlimit 20"
let serialize32_bounded_integer_le_2
= fun x #rrel #rel b pos ->
bounded_integer_prop_equiv 2 x;
let h = HST.get () in
let x' = (Cast.uint32_to_uint16 x) in
LE.writable_store_pre b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h;
LE.store16_le_i (* #(Ghost.hide rrel) #(Ghost.hide rel) *) b pos x';
let h' = HST.get () in
LE.store_post_modifies b (U32.v pos) 2 (fun s -> E.le_to_n s == U16.v x') h h';
2ul
#pop-options
let write_bounded_integer_le_2 = leaf_writer_strong_of_serializer32 serialize32_bounded_integer_le_2 ()
#push-options "--z3rlimit 16" | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.BoundedInt.fst.checked",
"LowParse.Low.Endianness.fst.checked",
"LowParse.Low.Combinators.fsti.checked",
"LowParse.Endianness.BitFields.fst.checked",
"LowParse.BitFields.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.UInt16.fsti.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Ghost.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Low.BoundedInt.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowParse.Low.Endianness",
"short_module": "LE"
},
{
"abbrev": true,
"full_module": "LowParse.BitFields",
"short_module": "BF"
},
{
"abbrev": true,
"full_module": "LowParse.Endianness.BitFields",
"short_module": "E"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt16",
"short_module": "U16"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Combinators",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "LowStar.Monotonic.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Low.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Spec.BoundedInt",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 16,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | LowParse.Low.Base.serializer32 (LowParse.Spec.BoundedInt.serialize_bounded_integer_le 3) | Prims.Tot | [
"total"
] | [] | [
"LowParse.Spec.BoundedInt.bounded_integer",
"LowStar.Monotonic.Buffer.srel",
"LowParse.Bytes.byte",
"LowStar.Monotonic.Buffer.mbuffer",
"FStar.UInt32.t",
"FStar.UInt32.__uint_to_t",
"Prims.unit",
"Prims._assert",
"FStar.Seq.Base.equal",
"FStar.Seq.Base.slice",
"LowStar.Monotonic.Buffer.as_seq",
"FStar.UInt32.v",
"Prims.op_Addition",
"FStar.Seq.Base.create",
"LowStar.Monotonic.Buffer.modifies_buffer_from_to_elim",
"FStar.UInt32.add",
"LowStar.Monotonic.Buffer.loc_buffer_from_to",
"LowParse.Low.Endianness.store_post_modifies",
"FStar.Seq.Base.seq",
"Prims.eq2",
"Prims.int",
"Prims.l_or",
"Prims.b2t",
"Prims.op_GreaterThanOrEqual",
"FStar.UInt.size",
"FStar.UInt16.n",
"FStar.Endianness.le_to_n",
"FStar.UInt16.v",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"LowStar.Endianness.store16_le_i",
"LowParse.Low.Endianness.writable_store_pre",
"LowParse.Low.Base.writable_weaken",
"FStar.UInt16.t",
"Prims.op_Equality",
"Prims.op_Modulus",
"Prims.pow2",
"FStar.Int.Cast.uint32_to_uint16",
"FStar.Math.Lemmas.small_mod",
"Prims.op_Division",
"LowParse.Low.BoundedInt.div256",
"LowParse.Low.Base.mbuffer_upd",
"FStar.Ghost.hide",
"Prims.nat",
"FStar.UInt8.t",
"FStar.UInt8.v",
"FStar.Int.Cast.uint32_to_uint8",
"FStar.Pervasives.assert_norm",
"LowParse.Endianness.reveal_n_to_le",
"LowParse.Spec.BoundedInt.bounded_integer_prop_equiv"
] | [] | false | false | false | false | false | let serialize32_bounded_integer_le_3 =
| fun v #rrel #rel out pos ->
bounded_integer_prop_equiv 3 v;
E.reveal_n_to_le 3 (U32.v v);
assert_norm (pow2 8 == 256);
let lo = Cast.uint32_to_uint8 v in
mbuffer_upd out (Ghost.hide (U32.v pos)) (Ghost.hide (U32.v pos + 3)) pos lo;
let hi' = div256 v in
FStar.Math.Lemmas.small_mod (U32.v hi') (pow2 16);
let hi = Cast.uint32_to_uint16 hi' in
let h1 = HST.get () in
LE.writable_weaken out (U32.v pos) (U32.v pos + 3) h1 (U32.v pos + 1) (U32.v pos + 3);
LE.writable_store_pre out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1;
LE.store16_le_i out (pos `U32.add` 1ul) hi;
let h2 = HST.get () in
LE.store_post_modifies out (U32.v pos + 1) 2 (fun s -> E.le_to_n s == U16.v hi) h1 h2;
B.modifies_buffer_from_to_elim out
pos
(pos `U32.add` 1ul)
(B.loc_buffer_from_to out (pos `U32.add` 1ul) (pos `U32.add` 3ul))
h1
h2;
assert ((Seq.slice (B.as_seq h2 out) (U32.v pos) (U32.v pos + 1)) `Seq.equal` (Seq.create 1 lo));
3ul | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_expected512 | val test3_expected512:lbytes 64 | val test3_expected512:lbytes 64 | let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 227,
"start_col": 0,
"start_line": 215
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy; 0xefuy; 0xb0uy; 0xf0uy; 0x75uy;
0x6cuy; 0x89uy; 0x0buy; 0xe9uy; 0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy; 0xbfuy; 0x3euy; 0x84uy; 0x82uy;
0x79uy; 0xa7uy; 0x22uy; 0xc8uy; 0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy; 0x74uy; 0x27uy; 0x88uy; 0x59uy;
0xe1uy; 0x32uy; 0x92uy; 0xfbuy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_data | val test5_data:lbytes 20 | val test5_data:lbytes 20 | let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 326,
"start_col": 0,
"start_line": 319
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 20 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_data:lbytes 20 =
| let l =
List.Tot.map u8_from_UInt8
[
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy; 0x68uy; 0x20uy; 0x54uy; 0x72uy;
0x75uy; 0x6euy; 0x63uy; 0x61uy; 0x74uy; 0x69uy; 0x6fuy; 0x6euy
]
in
assert_norm (List.Tot.length l == 20);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test1_expected512 | val test1_expected512:lbytes 64 | val test1_expected512:lbytes 64 | let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 82,
"start_col": 0,
"start_line": 70
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test1_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy; 0x4fuy; 0xf0uy; 0xb4uy; 0x24uy;
0x1auy; 0x1duy; 0x6cuy; 0xb0uy; 0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy; 0xdauy; 0xa8uy; 0x33uy; 0xb7uy;
0xd6uy; 0xb8uy; 0xa7uy; 0x02uy; 0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy; 0x2euy; 0x69uy; 0x6cuy; 0x20uy;
0x3auy; 0x12uy; 0x68uy; 0x54uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_expected224 | val test4_expected224:lbytes 28 | val test4_expected224:lbytes 28 | let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 265,
"start_col": 0,
"start_line": 257
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy; 0x6auy; 0x2auy; 0xbcuy; 0x1buy;
0xb3uy; 0x82uy; 0x62uy; 0x7cuy; 0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_expected256 | val test5_expected256:lbytes 16 | val test5_expected256:lbytes 16 | let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 344,
"start_col": 0,
"start_line": 338
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 16 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_expected256:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy; 0x6euy; 0x0cuy; 0x79uy; 0x6cuy;
0x29uy; 0x55uy; 0x55uy; 0x2buy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_expected384 | val test5_expected384:lbytes 16 | val test5_expected384:lbytes 16 | let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 353,
"start_col": 0,
"start_line": 347
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 16 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_expected384:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy; 0xa4uy; 0x6euy; 0xfcuy; 0x61uy;
0x9buy; 0xaeuy; 0xf8uy; 0x97uy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test2_expected512 | val test2_expected512:lbytes 64 | val test2_expected512:lbytes 64 | let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 151,
"start_col": 0,
"start_line": 139
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test2_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy; 0xe3uy; 0x95uy; 0xfbuy; 0xe7uy;
0x3buy; 0x56uy; 0xe0uy; 0xa3uy; 0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy; 0x97uy; 0x58uy; 0xbfuy; 0x75uy;
0xc0uy; 0x5auy; 0x99uy; 0x4auy; 0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy; 0x63uy; 0x6euy; 0x07uy; 0x0auy;
0x38uy; 0xbcuy; 0xe7uy; 0x37uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_expected512 | val test4_expected512:lbytes 64 | val test4_expected512:lbytes 64 | let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 304,
"start_col": 0,
"start_line": 292
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy; 0x90uy; 0xe5uy; 0xa8uy; 0xc5uy;
0xf6uy; 0x1duy; 0x4auy; 0xf7uy; 0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy; 0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy;
0x1auy; 0xa2uy; 0x5euy; 0xb4uy; 0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy; 0xe2uy; 0xaduy; 0xebuy; 0xebuy;
0x10uy; 0xa2uy; 0x98uy; 0xdduy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test5_expected512 | val test5_expected512:lbytes 16 | val test5_expected512:lbytes 16 | let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 362,
"start_col": 0,
"start_line": 356
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 16 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test5_expected512:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy; 0x1duy; 0x41uy; 0x79uy; 0xbcuy;
0x89uy; 0x1duy; 0x87uy; 0xa6uy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test4_expected384 | val test4_expected384:lbytes 48 | val test4_expected384:lbytes 48 | let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 289,
"start_col": 0,
"start_line": 279
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test4_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy; 0x19uy; 0x33uy; 0xabuy; 0x62uy;
0x90uy; 0xafuy; 0x6cuy; 0xa7uy; 0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy; 0x68uy; 0x01uy; 0xdduy; 0x23uy;
0xc4uy; 0xa7uy; 0xd6uy; 0x79uy; 0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test3_expected384 | val test3_expected384:lbytes 48 | val test3_expected384:lbytes 48 | let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 212,
"start_col": 0,
"start_line": 202
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test3_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy; 0x0auy; 0xa2uy; 0xacuy; 0xe0uy;
0x14uy; 0xc8uy; 0xa8uy; 0x6fuy; 0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy; 0x2auy; 0x5auy; 0xb3uy; 0x9duy;
0xc1uy; 0x38uy; 0x14uy; 0xb9uy; 0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_key | val test6_key:lbytes 131 | val test6_key:lbytes 131 | let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 388,
"start_col": 0,
"start_line": 367
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 131 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_key:lbytes 131 =
| let l =
List.Tot.map u8_from_UInt8
[
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy
]
in
assert_norm (List.Tot.length l == 131);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_data | val test6_data:lbytes 54 | val test6_data:lbytes 54 | let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 402,
"start_col": 0,
"start_line": 391
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 54 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_data:lbytes 54 =
| let l =
List.Tot.map u8_from_UInt8
[
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x4cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x4buy; 0x65uy;
0x79uy; 0x20uy; 0x2duy; 0x20uy; 0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
]
in
assert_norm (List.Tot.length l == 54);
of_list l | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.lemma_poly1305_equiv_r | val lemma_poly1305_equiv_r (k: key)
: Lemma
(ensures
(let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff == S.poly1305_encode_r key_bytes)) | val lemma_poly1305_equiv_r (k: key)
: Lemma
(ensures
(let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff == S.poly1305_encode_r key_bytes)) | let lemma_poly1305_equiv_r (k:key) : Lemma
(ensures (
let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff == S.poly1305_encode_r key_bytes
))
=
let key_bytes:S.block = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let mask = 0x0ffffffc0ffffffc0ffffffc0fffffff in
let rv = iand key_r mask in
let lo = uint_from_bytes_le (sub key_bytes 0 8) in
let hi = uint_from_bytes_le (sub key_bytes 8 8) in
let mask0 = u64 0x0ffffffc0fffffff in
let mask1 = u64 0x0ffffffc0ffffffc in
let mlo = logand lo mask0 in
let mhi = logand hi mask1 in
assert_norm (pow2 128 < prime);
let rs:felem = to_felem (uint_v mhi * pow2 64 + uint_v mlo) in
assert_norm (rs == S.poly1305_encode_r key_bytes);
let v_mask0:nat64 = 0x0ffffffc0fffffff in
let v_mask1:nat64 = 0x0ffffffc0ffffffc in
let v_lo:nat64 = uint_v lo in
let v_hi:nat64 = uint_v hi in
let lowerUpper128 = Vale.Poly1305.Math.lowerUpper128 in
let v_lo_hi:nat128 = lowerUpper128 v_lo v_hi in
let v_mask_0_1:nat128 = lowerUpper128 v_mask0 v_mask1 in
let z0 = iand v_lo v_mask0 in
let z1 = iand v_hi v_mask1 in
let z = lowerUpper128 z0 z1 in
let and64 = UInt.logand #64 in
calc (==) {
rv;
== {}
iand key_r mask;
== {Hacl.Impl.Poly1305.Lemmas.uint_from_bytes_le_lemma key_bytes}
iand (pow2 64 * v_hi + v_lo) mask;
== {Vale.Poly1305.Math.lowerUpper128_reveal ()}
iand v_lo_hi v_mask_0_1;
== {Vale.Poly1305.Math.lemma_lowerUpper128_and v_lo_hi v_lo v_hi v_mask_0_1 v_mask0 v_mask1 z z0 z1}
z;
== {Vale.Poly1305.Math.lowerUpper128_reveal ()}
z1 * pow2 64 + z0;
== {Vale.Arch.TypesNative.reveal_iand_all 64}
and64 v_hi v_mask1 * pow2 64 + and64 v_lo v_mask0;
== {Lib.IntTypes.logand_spec hi mask1; Lib.IntTypes.logand_spec lo mask0}
uint_v mhi * pow2 64 + uint_v mlo;
== {}
rs;
} | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 3,
"end_line": 174,
"start_col": 0,
"start_line": 123
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd
unfold let fmul = S.fmul
unfold let to_felem = S.to_felem
unfold let modp = V.modp
unfold let mod2_128 = V.mod2_128
#set-options "--z3rlimit 150 --max_fuel 1 --max_ifuel 1"
let rec lemma_poly1305_equiv_rec (text:bytes) (acc0:felem) (r:felem) (k:nat) : Lemma
(requires k <= length text / size_block)
(ensures (
let f = S.poly1305_update1 r size_block in
let repeat_f = repeat_blocks_f size_block text f (length text / size_block) in
let pad = pow2 (8 * size_block) in
V.poly1305_hash_blocks acc0 pad r (block_fun text) k == repeati k repeat_f acc0
))
(decreases k)
=
let inp = block_fun text in
let f = S.poly1305_update1 r size_block in
let len = length text in
let nb = len / size_block in
let repeat_f = repeat_blocks_f size_block text f nb in
let pad = pow2 (8 * size_block) in
assert_norm (pow2 128 + pow2 128 < prime);
if k = 0 then
Lib.LoopCombinators.eq_repeati0 nb repeat_f acc0
else
(
let kk = k - 1 in
let hh = V.poly1305_hash_blocks acc0 pad r inp kk in
let r0:felem = repeati kk repeat_f acc0 in
let block = Seq.slice text (kk * size_block) (kk * size_block + size_block) in
calc (==) {
V.poly1305_hash_blocks acc0 pad r inp k;
== {}
modp ((hh + pad + inp kk) * r);
== {assert_norm (modp ((hh + pad + inp kk) * r) == (hh + pad + inp kk) * r % prime)}
(hh + pad + inp kk) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (hh + pad + inp kk) r prime}
((hh + pad + inp kk) % prime) * r % prime;
== {lemma_poly1305_equiv_rec text acc0 r kk}
((pad + inp kk + r0) % prime) * r % prime;
== {assert_norm (fmul (fadd (pad + inp kk) r0) r == ((pad + inp kk + r0) % prime) * r % prime)}
fmul (fadd (pad + inp kk) r0) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (pad + inp kk) r0 prime }
fmul (fadd (fadd pad (inp kk)) r0) r;
== {}
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
};
calc (==) {
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
== {}
f block (repeati kk repeat_f acc0);
== {}
repeat_f kk (repeati kk repeat_f acc0);
== {Lib.LoopCombinators.unfold_repeati nb repeat_f acc0 kk}
repeati k repeat_f acc0;
}
)
let lemma_poly1305_equiv_last (text:bytes) (r:felem) (hBlocks:felem) : Lemma
(ensures (
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) == S.poly1305_update1 r nExtra last hBlocks
))
=
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
let x = nat_from_bytes_le last in
Math.Lemmas.pow2_le_compat 128 (8 * nExtra);
FStar.Math.Lemmas.modulo_lemma x padLast;
assert_norm (x + padLast < prime);
calc (==) {
modp ((hBlocks + padLast + inp nb % padLast) * r);
== {}
modp ((x + padLast + hBlocks) * r);
== {assert_norm (modp ((x + padLast + hBlocks) * r) == (x + padLast + hBlocks) * r % prime)}
(x + padLast + hBlocks) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (x + padLast + hBlocks) r prime}
((x + padLast + hBlocks) % prime) * r % prime;
== {assert_norm (((x + padLast + hBlocks) % prime) * r % prime == fmul (fadd (x + padLast) hBlocks) r)}
fmul (fadd (x + padLast) hBlocks) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (x + padLast) hBlocks prime }
fmul (fadd (fadd x padLast) hBlocks) r;
== {}
S.poly1305_update1 r nExtra last hBlocks;
} | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 150,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | k: Vale.Poly1305.Equiv.key
-> FStar.Pervasives.Lemma
(ensures
(let key_bytes = FStar.Seq.Base.slice k 0 16 in
let key_r = Vale.Poly1305.Equiv.nat_from_bytes_le key_bytes in
Vale.Poly1305.Equiv.iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff ==
Spec.Poly1305.poly1305_encode_r key_bytes)) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Vale.Poly1305.Equiv.key",
"FStar.Calc.calc_finish",
"Vale.Def.Words_s.natN",
"Vale.Def.Words_s.pow2_128",
"Prims.eq2",
"Prims.Cons",
"FStar.Preorder.relation",
"Prims.Nil",
"Prims.unit",
"FStar.Calc.calc_step",
"Prims.op_Addition",
"FStar.Mul.op_Star",
"Vale.Poly1305.Equiv.uint_v",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"Prims.pow2",
"Vale.Poly1305.Equiv.iand",
"FStar.Calc.calc_init",
"FStar.Calc.calc_pack",
"Prims.squash",
"Hacl.Impl.Poly1305.Lemmas.uint_from_bytes_le_lemma",
"Vale.Poly1305.Math.lowerUpper128_reveal",
"Vale.Poly1305.Math.lemma_lowerUpper128_and",
"Vale.Arch.TypesNative.reveal_iand_all",
"Lib.IntTypes.logand_spec",
"FStar.UInt.uint_t",
"FStar.UInt.logand",
"Vale.Def.Words_s.nat128",
"Vale.Def.Words_s.pow2_64",
"Vale.Def.Words_s.nat64",
"Vale.Poly1305.Math.lowerUpper128",
"FStar.Pervasives.assert_norm",
"Spec.Poly1305.felem",
"Spec.Poly1305.poly1305_encode_r",
"Vale.Poly1305.Equiv.to_felem",
"Prims.b2t",
"Prims.op_LessThan",
"Vale.Poly1305.Equiv.prime",
"Lib.IntTypes.int_t",
"Vale.Poly1305.Equiv.logand",
"Prims.int",
"Lib.IntTypes.range",
"Lib.IntTypes.v",
"Vale.Poly1305.Equiv.u64",
"Vale.Poly1305.Equiv.uint_from_bytes_le",
"Vale.Poly1305.Equiv.sub",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U8",
"Spec.Poly1305.size_block",
"Vale.Poly1305.Equiv.nat_from_bytes_le",
"Spec.Poly1305.block",
"FStar.Seq.Base.slice",
"Prims.l_True",
"Prims.nat",
"Prims.l_or",
"Spec.Poly1305.prime",
"FStar.Seq.Base.seq",
"FStar.Pervasives.pattern"
] | [] | false | false | true | false | false | let lemma_poly1305_equiv_r (k: key)
: Lemma
(ensures
(let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff == S.poly1305_encode_r key_bytes)) =
| let key_bytes:S.block = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let mask = 0x0ffffffc0ffffffc0ffffffc0fffffff in
let rv = iand key_r mask in
let lo = uint_from_bytes_le (sub key_bytes 0 8) in
let hi = uint_from_bytes_le (sub key_bytes 8 8) in
let mask0 = u64 0x0ffffffc0fffffff in
let mask1 = u64 0x0ffffffc0ffffffc in
let mlo = logand lo mask0 in
let mhi = logand hi mask1 in
assert_norm (pow2 128 < prime);
let rs:felem = to_felem (uint_v mhi * pow2 64 + uint_v mlo) in
assert_norm (rs == S.poly1305_encode_r key_bytes);
let v_mask0:nat64 = 0x0ffffffc0fffffff in
let v_mask1:nat64 = 0x0ffffffc0ffffffc in
let v_lo:nat64 = uint_v lo in
let v_hi:nat64 = uint_v hi in
let lowerUpper128 = Vale.Poly1305.Math.lowerUpper128 in
let v_lo_hi:nat128 = lowerUpper128 v_lo v_hi in
let v_mask_0_1:nat128 = lowerUpper128 v_mask0 v_mask1 in
let z0 = iand v_lo v_mask0 in
let z1 = iand v_hi v_mask1 in
let z = lowerUpper128 z0 z1 in
let and64 = UInt.logand #64 in
calc ( == ) {
rv;
( == ) { () }
iand key_r mask;
( == ) { Hacl.Impl.Poly1305.Lemmas.uint_from_bytes_le_lemma key_bytes }
iand (pow2 64 * v_hi + v_lo) mask;
( == ) { Vale.Poly1305.Math.lowerUpper128_reveal () }
iand v_lo_hi v_mask_0_1;
( == ) { Vale.Poly1305.Math.lemma_lowerUpper128_and v_lo_hi
v_lo
v_hi
v_mask_0_1
v_mask0
v_mask1
z
z0
z1 }
z;
( == ) { Vale.Poly1305.Math.lowerUpper128_reveal () }
z1 * pow2 64 + z0;
( == ) { Vale.Arch.TypesNative.reveal_iand_all 64 }
and64 v_hi v_mask1 * pow2 64 + and64 v_lo v_mask0;
( == ) { (Lib.IntTypes.logand_spec hi mask1;
Lib.IntTypes.logand_spec lo mask0) }
uint_v mhi * pow2 64 + uint_v mlo;
( == ) { () }
rs;
} | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_expected256 | val test6_expected256:lbytes 32 | val test6_expected256:lbytes 32 | let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 424,
"start_col": 0,
"start_line": 416
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy; 0x0duy; 0x8auy; 0x26uy; 0xaauy;
0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy; 0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test | val test : _: Prims.unit -> FStar.All.ALL Prims.bool | let test () =
let res = List.for_all test_one test_vectors in
if res then begin IO.print_string "\n\nHMAC: Success!\n"; true end
else begin IO.print_string "\n\nHMAC: Failure :(\n"; false end | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 64,
"end_line": 616,
"start_col": 0,
"start_line": 613
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test7_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy;
0x35uy; 0x1euy; 0x2fuy; 0x25uy; 0x4euy; 0x8fuy; 0xd3uy; 0x2cuy;
0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy;
0xa6uy; 0x78uy; 0xccuy; 0x31uy; 0xe7uy; 0x99uy; 0x17uy; 0x6duy;
0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test7_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xe3uy; 0x7buy; 0x6auy; 0x77uy; 0x5duy; 0xc8uy; 0x7duy; 0xbauy;
0xa4uy; 0xdfuy; 0xa9uy; 0xf9uy; 0x6euy; 0x5euy; 0x3fuy; 0xfduy;
0xdeuy; 0xbduy; 0x71uy; 0xf8uy; 0x86uy; 0x72uy; 0x89uy; 0x86uy;
0x5duy; 0xf5uy; 0xa3uy; 0x2duy; 0x20uy; 0xcduy; 0xc9uy; 0x44uy;
0xb6uy; 0x02uy; 0x2cuy; 0xacuy; 0x3cuy; 0x49uy; 0x82uy; 0xb1uy;
0x0duy; 0x5euy; 0xebuy; 0x55uy; 0xc3uy; 0xe4uy; 0xdeuy; 0x15uy;
0x13uy; 0x46uy; 0x76uy; 0xfbuy; 0x6duy; 0xe0uy; 0x44uy; 0x60uy;
0x65uy; 0xc9uy; 0x74uy; 0x40uy; 0xfauy; 0x8cuy; 0x6auy; 0x58uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
let _: squash (pow2 32 < pow2 61 /\ pow2 32 < pow2 125) =
Math.Lemmas.pow2_lt_compat 61 32;
Math.Lemmas.pow2_lt_compat 125 32
noeq type vec =
| Vec :
a:fixed_len_alg
-> key:bytes{HMAC.keysized a (Seq.length key)}
-> data:bytes{(Seq.length data + block_length a) `less_than_max_input_length` a}
-> expected:bytes{length expected <= hash_length a} -> vec
let test_vectors : list vec = [
Vec SHA2_224 test1_key test1_data test1_expected224;
Vec SHA2_256 test1_key test1_data test1_expected256;
Vec SHA2_384 test1_key test1_data test1_expected384;
Vec SHA2_512 test1_key test1_data test1_expected512;
Vec SHA2_224 test2_key test2_data test2_expected224;
Vec SHA2_256 test2_key test2_data test2_expected256;
Vec SHA2_384 test2_key test2_data test2_expected384;
Vec SHA2_512 test2_key test2_data test2_expected512;
Vec SHA2_224 test3_key test3_data test3_expected224;
Vec SHA2_256 test3_key test3_data test3_expected256;
Vec SHA2_384 test3_key test3_data test3_expected384;
Vec SHA2_512 test3_key test3_data test3_expected512;
Vec SHA2_224 test4_key test4_data test4_expected224;
Vec SHA2_256 test4_key test4_data test4_expected256;
Vec SHA2_384 test4_key test4_data test4_expected384;
Vec SHA2_512 test4_key test4_data test4_expected512;
Vec SHA2_224 test5_key test5_data test5_expected224;
Vec SHA2_256 test5_key test5_data test5_expected256;
Vec SHA2_384 test5_key test5_data test5_expected384;
Vec SHA2_512 test5_key test5_data test5_expected512;
Vec SHA2_224 test6_key test6_data test6_expected224;
Vec SHA2_256 test6_key test6_data test6_expected256;
Vec SHA2_384 test6_key test6_data test6_expected384;
Vec SHA2_512 test6_key test6_data test6_expected512;
Vec SHA2_224 test7_key test7_data test7_expected224;
Vec SHA2_256 test7_key test7_data test7_expected256;
Vec SHA2_384 test7_key test7_data test7_expected384;
Vec SHA2_512 test7_key test7_data test7_expected512 ]
let test_one (v:vec) =
let Vec a key data expected = v in
let computed = Seq.slice (HMAC.hmac a key data) 0 (length expected) in
PS.print_compare true (length expected) expected computed | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | _: Prims.unit -> FStar.All.ALL Prims.bool | FStar.All.ALL | [] | [] | [
"Prims.unit",
"Prims.bool",
"FStar.IO.print_string",
"FStar.List.for_all",
"Spec.HMAC.Test.vec",
"Spec.HMAC.Test.test_one",
"Spec.HMAC.Test.test_vectors"
] | [] | false | true | false | false | false | let test () =
| let res = List.for_all test_one test_vectors in
if res
then
(IO.print_string "\n\nHMAC: Success!\n";
true)
else
(IO.print_string "\n\nHMAC: Failure :(\n";
false) | false |
|
Spec.HMAC.Test.fst | Spec.HMAC.Test.test_one | val test_one : v: Spec.HMAC.Test.vec -> FStar.All.ALL Prims.bool | let test_one (v:vec) =
let Vec a key data expected = v in
let computed = Seq.slice (HMAC.hmac a key data) 0 (length expected) in
PS.print_compare true (length expected) expected computed | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 59,
"end_line": 610,
"start_col": 0,
"start_line": 607
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test7_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy;
0x35uy; 0x1euy; 0x2fuy; 0x25uy; 0x4euy; 0x8fuy; 0xd3uy; 0x2cuy;
0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy;
0xa6uy; 0x78uy; 0xccuy; 0x31uy; 0xe7uy; 0x99uy; 0x17uy; 0x6duy;
0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test7_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xe3uy; 0x7buy; 0x6auy; 0x77uy; 0x5duy; 0xc8uy; 0x7duy; 0xbauy;
0xa4uy; 0xdfuy; 0xa9uy; 0xf9uy; 0x6euy; 0x5euy; 0x3fuy; 0xfduy;
0xdeuy; 0xbduy; 0x71uy; 0xf8uy; 0x86uy; 0x72uy; 0x89uy; 0x86uy;
0x5duy; 0xf5uy; 0xa3uy; 0x2duy; 0x20uy; 0xcduy; 0xc9uy; 0x44uy;
0xb6uy; 0x02uy; 0x2cuy; 0xacuy; 0x3cuy; 0x49uy; 0x82uy; 0xb1uy;
0x0duy; 0x5euy; 0xebuy; 0x55uy; 0xc3uy; 0xe4uy; 0xdeuy; 0x15uy;
0x13uy; 0x46uy; 0x76uy; 0xfbuy; 0x6duy; 0xe0uy; 0x44uy; 0x60uy;
0x65uy; 0xc9uy; 0x74uy; 0x40uy; 0xfauy; 0x8cuy; 0x6auy; 0x58uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
let _: squash (pow2 32 < pow2 61 /\ pow2 32 < pow2 125) =
Math.Lemmas.pow2_lt_compat 61 32;
Math.Lemmas.pow2_lt_compat 125 32
noeq type vec =
| Vec :
a:fixed_len_alg
-> key:bytes{HMAC.keysized a (Seq.length key)}
-> data:bytes{(Seq.length data + block_length a) `less_than_max_input_length` a}
-> expected:bytes{length expected <= hash_length a} -> vec
let test_vectors : list vec = [
Vec SHA2_224 test1_key test1_data test1_expected224;
Vec SHA2_256 test1_key test1_data test1_expected256;
Vec SHA2_384 test1_key test1_data test1_expected384;
Vec SHA2_512 test1_key test1_data test1_expected512;
Vec SHA2_224 test2_key test2_data test2_expected224;
Vec SHA2_256 test2_key test2_data test2_expected256;
Vec SHA2_384 test2_key test2_data test2_expected384;
Vec SHA2_512 test2_key test2_data test2_expected512;
Vec SHA2_224 test3_key test3_data test3_expected224;
Vec SHA2_256 test3_key test3_data test3_expected256;
Vec SHA2_384 test3_key test3_data test3_expected384;
Vec SHA2_512 test3_key test3_data test3_expected512;
Vec SHA2_224 test4_key test4_data test4_expected224;
Vec SHA2_256 test4_key test4_data test4_expected256;
Vec SHA2_384 test4_key test4_data test4_expected384;
Vec SHA2_512 test4_key test4_data test4_expected512;
Vec SHA2_224 test5_key test5_data test5_expected224;
Vec SHA2_256 test5_key test5_data test5_expected256;
Vec SHA2_384 test5_key test5_data test5_expected384;
Vec SHA2_512 test5_key test5_data test5_expected512;
Vec SHA2_224 test6_key test6_data test6_expected224;
Vec SHA2_256 test6_key test6_data test6_expected256;
Vec SHA2_384 test6_key test6_data test6_expected384;
Vec SHA2_512 test6_key test6_data test6_expected512;
Vec SHA2_224 test7_key test7_data test7_expected224;
Vec SHA2_256 test7_key test7_data test7_expected256;
Vec SHA2_384 test7_key test7_data test7_expected384;
Vec SHA2_512 test7_key test7_data test7_expected512 ] | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | v: Spec.HMAC.Test.vec -> FStar.All.ALL Prims.bool | FStar.All.ALL | [] | [] | [
"Spec.HMAC.Test.vec",
"Spec.Hash.Definitions.fixed_len_alg",
"Spec.Hash.Definitions.bytes",
"Spec.Agile.HMAC.keysized",
"FStar.Seq.Base.length",
"Lib.IntTypes.uint8",
"Prims.b2t",
"Spec.Hash.Definitions.less_than_max_input_length",
"Prims.op_Addition",
"Spec.Hash.Definitions.block_length",
"Prims.op_LessThanOrEqual",
"Lib.Sequence.length",
"Spec.Hash.Definitions.hash_length",
"Lib.PrintSequence.print_compare",
"Prims.bool",
"FStar.Seq.Base.seq",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"FStar.Seq.Base.slice",
"Spec.Agile.HMAC.hmac"
] | [] | false | true | false | false | false | let test_one (v: vec) =
| let Vec a key data expected = v in
let computed = Seq.slice (HMAC.hmac a key data) 0 (length expected) in
PS.print_compare true (length expected) expected computed | false |
|
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_key | val test7_key:lbytes 131 | val test7_key:lbytes 131 | let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 478,
"start_col": 0,
"start_line": 457
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7 | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 131 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_key:lbytes 131 =
| let l =
List.Tot.map u8_from_UInt8
[
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy
]
in
assert_norm (List.Tot.length l == 131);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_expected256 | val test7_expected256:lbytes 32 | val test7_expected256:lbytes 32 | let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 526,
"start_col": 0,
"start_line": 518
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 32 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_expected256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy; 0x27uy; 0x63uy; 0x5fuy; 0xbcuy;
0xd5uy; 0xb0uy; 0xe9uy; 0x44uy; 0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_expected512 | val test7_expected512:lbytes 64 | val test7_expected512:lbytes 64 | let test7_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xe3uy; 0x7buy; 0x6auy; 0x77uy; 0x5duy; 0xc8uy; 0x7duy; 0xbauy;
0xa4uy; 0xdfuy; 0xa9uy; 0xf9uy; 0x6euy; 0x5euy; 0x3fuy; 0xfduy;
0xdeuy; 0xbduy; 0x71uy; 0xf8uy; 0x86uy; 0x72uy; 0x89uy; 0x86uy;
0x5duy; 0xf5uy; 0xa3uy; 0x2duy; 0x20uy; 0xcduy; 0xc9uy; 0x44uy;
0xb6uy; 0x02uy; 0x2cuy; 0xacuy; 0x3cuy; 0x49uy; 0x82uy; 0xb1uy;
0x0duy; 0x5euy; 0xebuy; 0x55uy; 0xc3uy; 0xe4uy; 0xdeuy; 0x15uy;
0x13uy; 0x46uy; 0x76uy; 0xfbuy; 0x6duy; 0xe0uy; 0x44uy; 0x60uy;
0x65uy; 0xc9uy; 0x74uy; 0x40uy; 0xfauy; 0x8cuy; 0x6auy; 0x58uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 554,
"start_col": 0,
"start_line": 542
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test7_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy;
0x35uy; 0x1euy; 0x2fuy; 0x25uy; 0x4euy; 0x8fuy; 0xd3uy; 0x2cuy;
0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy;
0xa6uy; 0x78uy; 0xccuy; 0x31uy; 0xe7uy; 0x99uy; 0x17uy; 0x6duy;
0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xe3uy; 0x7buy; 0x6auy; 0x77uy; 0x5duy; 0xc8uy; 0x7duy; 0xbauy; 0xa4uy; 0xdfuy; 0xa9uy; 0xf9uy;
0x6euy; 0x5euy; 0x3fuy; 0xfduy; 0xdeuy; 0xbduy; 0x71uy; 0xf8uy; 0x86uy; 0x72uy; 0x89uy; 0x86uy;
0x5duy; 0xf5uy; 0xa3uy; 0x2duy; 0x20uy; 0xcduy; 0xc9uy; 0x44uy; 0xb6uy; 0x02uy; 0x2cuy; 0xacuy;
0x3cuy; 0x49uy; 0x82uy; 0xb1uy; 0x0duy; 0x5euy; 0xebuy; 0x55uy; 0xc3uy; 0xe4uy; 0xdeuy; 0x15uy;
0x13uy; 0x46uy; 0x76uy; 0xfbuy; 0x6duy; 0xe0uy; 0x44uy; 0x60uy; 0x65uy; 0xc9uy; 0x74uy; 0x40uy;
0xfauy; 0x8cuy; 0x6auy; 0x58uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_data | val test7_data:lbytes 152 | val test7_data:lbytes 152 | let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 504,
"start_col": 0,
"start_line": 481
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 152 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_data:lbytes 152 =
| let l =
List.Tot.map u8_from_UInt8
[
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy; 0x61uy; 0x20uy; 0x74uy; 0x65uy;
0x73uy; 0x74uy; 0x20uy; 0x75uy; 0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy; 0x61uy; 0x72uy; 0x67uy;
0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy; 0x61uy; 0x74uy; 0x61uy; 0x2euy;
0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy; 0x20uy; 0x68uy; 0x61uy; 0x73uy;
0x68uy; 0x65uy; 0x64uy; 0x20uy; 0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy; 0x64uy; 0x20uy; 0x62uy; 0x79uy;
0x20uy; 0x74uy; 0x68uy; 0x65uy; 0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
]
in
assert_norm (List.Tot.length l == 152);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_expected384 | val test6_expected384:lbytes 48 | val test6_expected384:lbytes 48 | let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 437,
"start_col": 0,
"start_line": 427
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy; 0x88uy; 0xd2uy; 0xc6uy; 0x3auy;
0x04uy; 0x1buy; 0xc5uy; 0xb4uy; 0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy; 0x0cuy; 0x2euy; 0xf6uy; 0xabuy;
0x40uy; 0x30uy; 0xfeuy; 0x82uy; 0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_eval_lemma | val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)] | val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)] | let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 47,
"end_line": 183,
"start_col": 0,
"start_line": 180
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (3, 3, 3, 3, 3)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{ Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (10, 10, 10, 10, 10) /\
r5 == Hacl.Spec.Poly1305.Field32xN.precomp_r5 r }
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.feval5 (Hacl.Spec.Poly1305.Field32xN.mul_felem5 f1 r r5) ==
Lib.Sequence.map2 Hacl.Spec.Poly1305.Vec.pfmul
(Hacl.Spec.Poly1305.Field32xN.feval5 f1)
(Hacl.Spec.Poly1305.Field32xN.feval5 r))
[SMTPat (Hacl.Spec.Poly1305.Field32xN.mul_felem5 f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Prims.l_and",
"Prims.eq2",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Lib.Sequence.eq_intro",
"Hacl.Spec.Poly1305.Vec.pfelem",
"Hacl.Spec.Poly1305.Field32xN.feval5",
"Hacl.Spec.Poly1305.Field32xN.mul_felem5",
"Prims.unit",
"FStar.Classical.forall_intro",
"Prims.b2t",
"Prims.op_LessThan",
"Lib.Sequence.op_String_Access",
"Hacl.Spec.Poly1305.Vec.pfmul",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_eval_lemma_i",
"Lib.Sequence.lseq",
"Prims.l_Forall",
"Prims.l_imp",
"Lib.Sequence.index",
"Lib.Sequence.map2"
] | [] | false | false | true | false | false | let mul_felem5_eval_lemma #w f1 r r5 =
| let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_expected224 | val test7_expected224:lbytes 28 | val test7_expected224:lbytes 28 | let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 515,
"start_col": 0,
"start_line": 507
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy; 0x3fuy; 0x54uy; 0xd5uy; 0x17uy;
0xd0uy; 0xb3uy; 0x9duy; 0xbduy; 0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_expected224 | val test6_expected224:lbytes 28 | val test6_expected224:lbytes 28 | let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 413,
"start_col": 0,
"start_line": 405
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 28 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_expected224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy; 0xaeuy; 0xbeuy; 0x9buy; 0x2duy;
0x6fuy; 0x0duy; 0xbcuy; 0xe2uy; 0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_feval_is_fas_nat | val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i]) | val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i]) | let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 62,
"end_line": 35,
"start_col": 0,
"start_line": 34
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_less5 f (Prims.pow2 128)}
-> FStar.Pervasives.Lemma
(ensures
forall (i: Prims.nat).
i < w ==>
(Hacl.Spec.Poly1305.Field32xN.fas_nat5 f).[ i ] ==
(Hacl.Spec.Poly1305.Field32xN.feval5 f).[ i ]) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_less5",
"Prims.pow2",
"FStar.Classical.forall_intro",
"Lib.IntTypes.size_nat",
"Prims.b2t",
"Prims.op_LessThan",
"Prims.eq2",
"Prims.nat",
"Prims.l_or",
"Prims.l_and",
"Spec.Poly1305.prime",
"Hacl.Spec.Poly1305.Vec.pfelem",
"FStar.Seq.Base.index",
"Lib.Sequence.to_seq",
"Hacl.Spec.Poly1305.Field32xN.feval5",
"Hacl.Spec.Poly1305.Field32xN.fas_nat5",
"Lib.Sequence.op_String_Access",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_feval_is_fas_nat_i",
"Prims.unit"
] | [] | false | false | true | false | false | let lemma_feval_is_fas_nat #w f =
| FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f) | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test7_expected384 | val test7_expected384:lbytes 48 | val test7_expected384:lbytes 48 | let test7_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy;
0x35uy; 0x1euy; 0x2fuy; 0x25uy; 0x4euy; 0x8fuy; 0xd3uy; 0x2cuy;
0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy;
0xa6uy; 0x78uy; 0xccuy; 0x31uy; 0xe7uy; 0x99uy; 0x17uy; 0x6duy;
0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 539,
"start_col": 0,
"start_line": 529
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 48 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test7_expected384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy; 0x35uy; 0x1euy; 0x2fuy; 0x25uy;
0x4euy; 0x8fuy; 0xd3uy; 0x2cuy; 0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy; 0xa6uy; 0x78uy; 0xccuy; 0x31uy;
0xe7uy; 0x99uy; 0x17uy; 0x6duy; 0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.lemma_poly1305_equiv_last | val lemma_poly1305_equiv_last (text: bytes) (r hBlocks: felem)
: Lemma
(ensures
(let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) ==
S.poly1305_update1 r nExtra last hBlocks)) | val lemma_poly1305_equiv_last (text: bytes) (r hBlocks: felem)
: Lemma
(ensures
(let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) ==
S.poly1305_update1 r nExtra last hBlocks)) | let lemma_poly1305_equiv_last (text:bytes) (r:felem) (hBlocks:felem) : Lemma
(ensures (
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) == S.poly1305_update1 r nExtra last hBlocks
))
=
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
let x = nat_from_bytes_le last in
Math.Lemmas.pow2_le_compat 128 (8 * nExtra);
FStar.Math.Lemmas.modulo_lemma x padLast;
assert_norm (x + padLast < prime);
calc (==) {
modp ((hBlocks + padLast + inp nb % padLast) * r);
== {}
modp ((x + padLast + hBlocks) * r);
== {assert_norm (modp ((x + padLast + hBlocks) * r) == (x + padLast + hBlocks) * r % prime)}
(x + padLast + hBlocks) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (x + padLast + hBlocks) r prime}
((x + padLast + hBlocks) % prime) * r % prime;
== {assert_norm (((x + padLast + hBlocks) % prime) * r % prime == fmul (fadd (x + padLast) hBlocks) r)}
fmul (fadd (x + padLast) hBlocks) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (x + padLast) hBlocks prime }
fmul (fadd (fadd x padLast) hBlocks) r;
== {}
S.poly1305_update1 r nExtra last hBlocks;
} | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 3,
"end_line": 121,
"start_col": 0,
"start_line": 86
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd
unfold let fmul = S.fmul
unfold let to_felem = S.to_felem
unfold let modp = V.modp
unfold let mod2_128 = V.mod2_128
#set-options "--z3rlimit 150 --max_fuel 1 --max_ifuel 1"
let rec lemma_poly1305_equiv_rec (text:bytes) (acc0:felem) (r:felem) (k:nat) : Lemma
(requires k <= length text / size_block)
(ensures (
let f = S.poly1305_update1 r size_block in
let repeat_f = repeat_blocks_f size_block text f (length text / size_block) in
let pad = pow2 (8 * size_block) in
V.poly1305_hash_blocks acc0 pad r (block_fun text) k == repeati k repeat_f acc0
))
(decreases k)
=
let inp = block_fun text in
let f = S.poly1305_update1 r size_block in
let len = length text in
let nb = len / size_block in
let repeat_f = repeat_blocks_f size_block text f nb in
let pad = pow2 (8 * size_block) in
assert_norm (pow2 128 + pow2 128 < prime);
if k = 0 then
Lib.LoopCombinators.eq_repeati0 nb repeat_f acc0
else
(
let kk = k - 1 in
let hh = V.poly1305_hash_blocks acc0 pad r inp kk in
let r0:felem = repeati kk repeat_f acc0 in
let block = Seq.slice text (kk * size_block) (kk * size_block + size_block) in
calc (==) {
V.poly1305_hash_blocks acc0 pad r inp k;
== {}
modp ((hh + pad + inp kk) * r);
== {assert_norm (modp ((hh + pad + inp kk) * r) == (hh + pad + inp kk) * r % prime)}
(hh + pad + inp kk) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (hh + pad + inp kk) r prime}
((hh + pad + inp kk) % prime) * r % prime;
== {lemma_poly1305_equiv_rec text acc0 r kk}
((pad + inp kk + r0) % prime) * r % prime;
== {assert_norm (fmul (fadd (pad + inp kk) r0) r == ((pad + inp kk + r0) % prime) * r % prime)}
fmul (fadd (pad + inp kk) r0) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (pad + inp kk) r0 prime }
fmul (fadd (fadd pad (inp kk)) r0) r;
== {}
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
};
calc (==) {
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
== {}
f block (repeati kk repeat_f acc0);
== {}
repeat_f kk (repeati kk repeat_f acc0);
== {Lib.LoopCombinators.unfold_repeati nb repeat_f acc0 kk}
repeati k repeat_f acc0;
}
) | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 150,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
text: Vale.Poly1305.Equiv.bytes ->
r: Vale.Poly1305.Equiv.felem ->
hBlocks: Vale.Poly1305.Equiv.felem
-> FStar.Pervasives.Lemma
(ensures
(let inp = Vale.Poly1305.Equiv.block_fun text in
let len = FStar.Seq.Base.length text in
let nb = len / Vale.Poly1305.Equiv.size_block in
let last = FStar.Seq.Base.slice text (nb * Vale.Poly1305.Equiv.size_block) len in
let nExtra = len % Vale.Poly1305.Equiv.size_block in
let padLast = Prims.pow2 (nExtra * 8) in
Vale.Poly1305.Equiv.modp ((hBlocks + padLast + inp nb % padLast) * r) ==
Spec.Poly1305.poly1305_update1 r nExtra last hBlocks)) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Vale.Poly1305.Equiv.bytes",
"Vale.Poly1305.Equiv.felem",
"FStar.Calc.calc_finish",
"Prims.int",
"Prims.eq2",
"Vale.Poly1305.Equiv.modp",
"FStar.Mul.op_Star",
"Prims.op_Addition",
"Prims.op_Modulus",
"Spec.Poly1305.poly1305_update1",
"Prims.Cons",
"FStar.Preorder.relation",
"Prims.Nil",
"Prims.unit",
"FStar.Calc.calc_step",
"Vale.Poly1305.Equiv.fmul",
"Vale.Poly1305.Equiv.fadd",
"Vale.Poly1305.Equiv.prime",
"FStar.Calc.calc_init",
"FStar.Calc.calc_pack",
"Prims.squash",
"FStar.Pervasives.assert_norm",
"FStar.Math.Lemmas.lemma_mod_mul_distr_l",
"FStar.Math.Lemmas.lemma_mod_plus_distr_l",
"Prims.b2t",
"Prims.op_LessThan",
"FStar.Math.Lemmas.modulo_lemma",
"FStar.Math.Lemmas.pow2_le_compat",
"Prims.nat",
"Prims.pow2",
"Prims.op_Multiply",
"Lib.Sequence.length",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Vale.Poly1305.Equiv.nat_from_bytes_le",
"Prims.pos",
"Vale.Poly1305.Equiv.size_block",
"FStar.Seq.Base.seq",
"FStar.Seq.Base.slice",
"Lib.IntTypes.uint_t",
"Prims.op_Division",
"FStar.Seq.Base.length",
"Vale.Def.Words_s.nat128",
"Vale.Poly1305.Equiv.block_fun",
"Prims.l_True",
"FStar.Pervasives.pattern"
] | [] | false | false | true | false | false | let lemma_poly1305_equiv_last (text: bytes) (r hBlocks: felem)
: Lemma
(ensures
(let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) ==
S.poly1305_update1 r nExtra last hBlocks)) =
| let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
let x = nat_from_bytes_le last in
Math.Lemmas.pow2_le_compat 128 (8 * nExtra);
FStar.Math.Lemmas.modulo_lemma x padLast;
assert_norm (x + padLast < prime);
calc ( == ) {
modp ((hBlocks + padLast + inp nb % padLast) * r);
( == ) { () }
modp ((x + padLast + hBlocks) * r);
( == ) { assert_norm (modp ((x + padLast + hBlocks) * r) == (x + padLast + hBlocks) * r % prime) }
(x + padLast + hBlocks) * r % prime;
( == ) { FStar.Math.Lemmas.lemma_mod_mul_distr_l (x + padLast + hBlocks) r prime }
((x + padLast + hBlocks) % prime) * r % prime;
( == ) { assert_norm (((x + padLast + hBlocks) % prime) * r % prime ==
fmul (fadd (x + padLast) hBlocks) r) }
fmul (fadd (x + padLast) hBlocks) r;
( == ) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (x + padLast) hBlocks prime }
fmul (fadd (fadd x padLast) hBlocks) r;
( == ) { () }
S.poly1305_update1 r nExtra last hBlocks;
} | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_fits_lemma | val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)] | val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)] | let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 116,
"end_line": 125,
"start_col": 0,
"start_line": 111
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (3, 3, 3, 3, 3)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (10, 10, 10, 10, 10)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_wide_fits5 (Hacl.Spec.Poly1305.Field32xN.mul_felem5 f1
r
r5)
(126,
102,
78,
54,
30)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.mul_felem5 f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_add_felem5_fits_lemma",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.smul_add_felem5",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_felem5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.smul_felem5"
] | [] | false | false | true | false | false | let mul_felem5_fits_lemma #w f1 r r5 =
| let r0, r1, r2, r3, r4 = r in
let f10, f11, f12, f13, f14 = f1 in
let r50, r51, r52, r53, r54 = r5 in
let a0, a1, a2, a3, a4 = smul_felem5 #w f10 (r0, r1, r2, r3, r4) in
smul_felem5_fits_lemma #w #3 #(2, 2, 2, 2, 2) f10 (r0, r1, r2, r3, r4);
let a10, a11, a12, a13, a14 = smul_add_felem5 #w f11 (r54, r0, r1, r2, r3) (a0, a1, a2, a3, a4) in
smul_add_felem5_fits_lemma #w
#3
#(10, 2, 2, 2, 2)
#(6, 6, 6, 6, 6)
f11
(r54, r0, r1, r2, r3)
(a0, a1, a2, a3, a4);
let a20, a21, a22, a23, a24 =
smul_add_felem5 #w f12 (r53, r54, r0, r1, r2) (a10, a11, a12, a13, a14)
in
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 2, 2, 2)
#(36, 12, 12, 12, 12)
f12
(r53, r54, r0, r1, r2)
(a10, a11, a12, a13, a14);
let a30, a31, a32, a33, a34 =
smul_add_felem5 #w f13 (r52, r53, r54, r0, r1) (a20, a21, a22, a23, a24)
in
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 10, 2, 2)
#(66, 42, 18, 18, 18)
f13
(r52, r53, r54, r0, r1)
(a20, a21, a22, a23, a24);
let a40, a41, a42, a43, a44 =
smul_add_felem5 #w f14 (r51, r52, r53, r54, r0) (a30, a31, a32, a33, a34)
in
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 10, 10, 2)
#(96, 72, 48, 24, 24)
f14
(r51, r52, r53, r54, r0)
(a30, a31, a32, a33, a34) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_feval_is_fas_nat_i | val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i]) | val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i]) | let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 70,
"end_line": 27,
"start_col": 0,
"start_line": 24
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_less5 f (Prims.pow2 128)} ->
i: Lib.IntTypes.size_nat{i < w}
-> FStar.Pervasives.Lemma
(ensures
(Hacl.Spec.Poly1305.Field32xN.feval5 f).[ i ] ==
(Hacl.Spec.Poly1305.Field32xN.fas_nat5 f).[ i ]) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_less5",
"Prims.pow2",
"Lib.IntTypes.size_nat",
"Prims.b2t",
"Prims.op_LessThan",
"FStar.Math.Lemmas.modulo_lemma",
"Hacl.Spec.Poly1305.Field32xN.as_nat5",
"Lib.Sequence.op_String_Access",
"Hacl.Spec.Poly1305.Field32xN.tup64_5",
"Hacl.Spec.Poly1305.Field32xN.transpose",
"Hacl.Spec.Poly1305.Vec.prime",
"Prims.unit",
"Prims._assert",
"Prims.eq2",
"Prims.int",
"Hacl.Spec.Poly1305.Vec.pfelem",
"Hacl.Spec.Poly1305.Field32xN.feval5",
"Prims.op_Modulus",
"FStar.Pervasives.assert_norm"
] | [] | true | false | true | false | false | let lemma_feval_is_fas_nat_i #w f i =
| assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[ i ] == (as_nat5 (transpose f).[ i ]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[ i ]) Vec.prime | false |
Steel.HigherReference.fst | Steel.HigherReference.read_refine | val read_refine (#a:Type) (#p:perm) (q:a -> vprop) (r:ref a)
: SteelT a (h_exists (fun (v:a) -> pts_to r p v `star` q v))
(fun v -> pts_to r p v `star` q v) | val read_refine (#a:Type) (#p:perm) (q:a -> vprop) (r:ref a)
: SteelT a (h_exists (fun (v:a) -> pts_to r p v `star` q v))
(fun v -> pts_to r p v `star` q v) | let read_refine (#a:Type) (#p:perm) (q:a -> vprop) (r:ref a)
: SteelT a (h_exists (fun (v:a) -> pts_to r p v `star` q v))
(fun v -> pts_to r p v `star` q v)
= let vs:erased a = witness_exists () in
rewrite_slprop (pts_to r p (Ghost.hide (Ghost.reveal vs))) (pts_to r p vs) (fun _ -> ());
let v = read r in
rewrite_slprop (q vs) (q v) (fun _ -> ());
return v | {
"file_name": "lib/steel/Steel.HigherReference.fst",
"git_rev": "f984200f79bdc452374ae994a5ca837496476c41",
"git_url": "https://github.com/FStarLang/steel.git",
"project_name": "steel"
} | {
"end_col": 12,
"end_line": 185,
"start_col": 0,
"start_line": 175
} | (*
Copyright 2020 Microsoft Research
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*)
module Steel.HigherReference
open FStar.Ghost
open Steel.Memory
open Steel.Effect.Atomic
open Steel.Effect
open FStar.PCM
open Steel.PCMFrac
open FStar.Real
module RP = Steel.PCMReference
#set-options "--ide_id_info_off"
module Mem = Steel.Memory
let ref a = Mem.ref (fractional a) pcm_frac
let null #a = Mem.null #(fractional a) #pcm_frac
let is_null #a r = Mem.is_null #(fractional a) #pcm_frac r
let perm_ok p : prop = (p.v <=. one == true) /\ True
let pts_to_raw_sl (#a:Type) (r:ref a) (p:perm) (v:erased a) : slprop =
Mem.pts_to r (Some (Ghost.reveal v, p))
let pts_to_raw (#a:Type) (r:ref a) (p:perm) (v:erased a) : vprop =
to_vprop (Mem.pts_to r (Some (Ghost.reveal v, p)))
[@@__reduce__]
let pts_to' (#a:Type u#1) (r:ref a) (p:perm) (v:erased a) : vprop = pts_to_raw r p v `star` pure (perm_ok p)
let pts_to_sl #a r p v = hp_of (pts_to' r p v)
let abcd_acbd (a b c d:slprop)
: Lemma (Mem.(((a `star` b) `star` (c `star` d)) `equiv`
((a `star` c) `star` (b `star` d))))
= let open Steel.Memory in
calc (equiv) {
((a `star` b) `star` (c `star` d));
(equiv) { star_associative a b (c `star` d) }
((a `star` (b `star` (c `star` d))));
(equiv) { star_associative b c d;
star_congruence a (b `star` (c `star` d))
a ((b `star` c) `star` d) }
(a `star` ((b `star` c) `star` d));
(equiv) { star_commutative b c;
star_congruence (b `star` c) d (c `star` b) d;
star_congruence a ((b `star` c) `star` d)
a ((c `star` b) `star` d) }
(a `star` ((c `star` b) `star` d));
(equiv) { star_associative c b d;
star_congruence a ((c `star` b) `star` d)
a (c `star` (b `star` d)) }
(a `star` (c `star` (b `star` d)));
(equiv) { star_associative a c (b `star` d) }
((a `star` c) `star` (b `star` d));
}
let pts_to_ref_injective
(#a: Type u#1)
(r: ref a)
(p0 p1:perm)
(v0 v1:a)
(m:mem)
: Lemma
(requires
interp (pts_to_sl r p0 v0 `Mem.star` pts_to_sl r p1 v1) m)
(ensures v0 == v1)
= let open Steel.Memory in
abcd_acbd (hp_of (pts_to_raw r p0 v0))
(pure (perm_ok p0))
(hp_of (pts_to_raw r p1 v1))
(pure (perm_ok p1));
Mem.affine_star (hp_of (pts_to_raw r p0 v0) `star` hp_of (pts_to_raw r p1 v1))
(pure (perm_ok p0) `star` pure (perm_ok p1)) m;
Mem.pts_to_compatible r (Some (Ghost.reveal v0, p0))
(Some (Ghost.reveal v1, p1))
m
let pts_to_not_null (#a:Type u#1)
(r:ref a)
(p:perm)
(v:a)
(m:mem)
: Lemma (requires interp (pts_to_sl r p v) m)
(ensures r =!= null)
= Mem.affine_star (hp_of (pts_to_raw r p v)) (Mem.pure (perm_ok p)) m;
Mem.pts_to_not_null r (Some (Ghost.reveal v, p)) m
let pts_to_witinv (#a:Type) (r:ref a) (p:perm) : Lemma (is_witness_invariant (pts_to_sl r p)) =
let aux (x y : erased a) (m:mem)
: Lemma (requires (interp (pts_to_sl r p x) m /\ interp (pts_to_sl r p y) m))
(ensures (x == y))
=
Mem.pts_to_join r (Some (Ghost.reveal x, p)) (Some (Ghost.reveal y, p)) m
in
Classical.forall_intro_3 (fun x y -> Classical.move_requires (aux x y))
let higher_ref_pts_to_injective_eq #a #opened #p0 #p1 #v0 #v1 r =
extract_info_raw (pts_to r p0 v0 `star` pts_to r p1 v1) (v0 == v1)
(fun m -> pts_to_ref_injective r p0 p1 v0 v1 m);
rewrite_slprop (pts_to r p1 v1) (pts_to r p1 v0) (fun _ -> ())
let pts_to_framon (#a:Type) (r:ref a) (p:perm) : Lemma (is_frame_monotonic (pts_to_sl r p)) =
pts_to_witinv r p
let intro_pts_to (p:perm) #a #uses (#v:erased a) (r:ref a)
: SteelGhost unit uses
(pts_to_raw r p v)
(fun _ -> pts_to r p v)
(requires fun _ -> perm_ok p)
(ensures fun _ _ _ -> True)
= intro_pure (perm_ok p);
rewrite_slprop (pts_to' r p v) (pts_to r p v) (fun _ -> ())
let pts_to_perm
#_ #_ #p #v r
= rewrite_slprop (pts_to r p v) (pts_to' r p v) (fun _ -> ());
elim_pure (perm_ok p);
intro_pure (perm_ok p);
rewrite_slprop (pts_to' r p v) (pts_to r p v) (fun _ -> ())
let alloc #a x =
let v = Some (x, full_perm) in
assert (FStar.PCM.composable pcm_frac v None);
assert (compatible pcm_frac v v);
let r = RP.alloc v in
rewrite_slprop (RP.pts_to r v) (pts_to r full_perm x)
(fun m ->
emp_unit (hp_of (pts_to_raw r full_perm x));
pure_star_interp (hp_of (pts_to_raw r full_perm x)) (perm_ok full_perm) m
);
extract_info_raw (pts_to r full_perm x) (~ (is_null r))
(fun m -> pts_to_not_null r full_perm x m);
return r
let read (#a:Type) (#p:perm) (#v:erased a) (r:ref a)
= let v1 : erased (fractional a) = Ghost.hide (Some (Ghost.reveal v, p)) in
rewrite_slprop (pts_to r p v) (RP.pts_to r v1 `star` pure (perm_ok p)) (fun _ -> ());
elim_pure (perm_ok p);
let v2 = RP.read r v1 in
rewrite_slprop (RP.pts_to r v1) (pts_to r p v)
(fun m ->
emp_unit (hp_of (pts_to_raw r p v));
pure_star_interp (hp_of (pts_to_raw r p v)) (perm_ok p) m);
assert (compatible pcm_frac v1 v2);
let Some (x, _) = v2 in
rewrite_slprop (pts_to r p v) (pts_to r p x) (fun _ -> ());
return x
let atomic_read (#opened:_) (#a:Type) (#p:perm) (#v:erased a) (r:ref a)
= let v1 : erased (fractional a) = Ghost.hide (Some (Ghost.reveal v, p)) in
rewrite_slprop (pts_to r p v) (RP.pts_to r v1 `star` pure (perm_ok p)) (fun _ -> ());
elim_pure (perm_ok p);
let v2 = RP.atomic_read r v1 in
rewrite_slprop (RP.pts_to r v1) (pts_to r p v)
(fun m ->
emp_unit (hp_of (pts_to_raw r p v));
pure_star_interp (hp_of (pts_to_raw r p v)) (perm_ok p) m);
assert (compatible pcm_frac v1 v2);
let Some (x, _) = v2 in
rewrite_slprop (pts_to r p v) (pts_to r p x) (fun _ -> ());
return x | {
"checked_file": "/",
"dependencies": [
"Steel.PCMReference.fsti.checked",
"Steel.PCMFrac.fst.checked",
"Steel.Memory.fsti.checked",
"Steel.Effect.Atomic.fsti.checked",
"Steel.Effect.fsti.checked",
"prims.fst.checked",
"FStar.Real.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.PCM.fst.checked",
"FStar.NMSTTotal.fst.checked",
"FStar.Ghost.fsti.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Steel.HigherReference.fst"
} | [
{
"abbrev": true,
"full_module": "Steel.Memory",
"short_module": "Mem"
},
{
"abbrev": true,
"full_module": "Steel.PCMReference",
"short_module": "RP"
},
{
"abbrev": false,
"full_module": "FStar.Real",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.PCMFrac",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.PCM",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.Effect.Atomic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.Memory",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Ghost",
"short_module": null
},
{
"abbrev": true,
"full_module": "Steel.Memory",
"short_module": "Mem"
},
{
"abbrev": false,
"full_module": "Steel.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.Effect.Atomic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.Memory",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Ghost",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel.FractionalPermission",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | q: (_: a -> Steel.Effect.Common.vprop) -> r: Steel.HigherReference.ref a -> Steel.Effect.SteelT a | Steel.Effect.SteelT | [] | [] | [
"Steel.FractionalPermission.perm",
"Steel.Effect.Common.vprop",
"Steel.HigherReference.ref",
"Steel.Effect.Atomic.return",
"FStar.Ghost.hide",
"FStar.Set.set",
"Steel.Memory.iname",
"FStar.Set.empty",
"Steel.Effect.Common.VStar",
"Steel.HigherReference.pts_to",
"Prims.unit",
"Steel.Effect.Atomic.rewrite_slprop",
"FStar.Ghost.reveal",
"Steel.Memory.mem",
"Steel.HigherReference.read",
"FStar.Ghost.erased",
"Steel.Effect.Atomic.witness_exists",
"Steel.Effect.Atomic.h_exists",
"Steel.Effect.Common.star"
] | [] | false | true | false | false | false | let read_refine (#a: Type) (#p: perm) (q: (a -> vprop)) (r: ref a)
: SteelT a
(h_exists (fun (v: a) -> (pts_to r p v) `star` (q v)))
(fun v -> (pts_to r p v) `star` (q v)) =
| let vs:erased a = witness_exists () in
rewrite_slprop (pts_to r p (Ghost.hide (Ghost.reveal vs))) (pts_to r p vs) (fun _ -> ());
let v = read r in
rewrite_slprop (q vs) (q v) (fun _ -> ());
return v | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd5_eval_lemma | val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)] | val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)] | let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2)) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 62,
"end_line": 100,
"start_col": 0,
"start_line": 97
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (2, 2, 2, 2, 2)} ->
f2:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f2 (1, 1, 1, 1, 1)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.feval5 (Hacl.Spec.Poly1305.Field32xN.fadd5 f1 f2) ==
Lib.Sequence.map2 Hacl.Spec.Poly1305.Vec.pfadd
(Hacl.Spec.Poly1305.Field32xN.feval5 f1)
(Hacl.Spec.Poly1305.Field32xN.feval5 f2))
[SMTPat (Hacl.Spec.Poly1305.Field32xN.fadd5 f1 f2)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Lib.Sequence.eq_intro",
"Hacl.Spec.Poly1305.Vec.pfelem",
"Hacl.Spec.Poly1305.Field32xN.feval5",
"Lib.Sequence.map2",
"Hacl.Spec.Poly1305.Vec.pfadd",
"Prims.unit",
"FStar.Classical.forall_intro",
"Prims.b2t",
"Prims.op_LessThan",
"Prims.eq2",
"Lib.Sequence.op_String_Access",
"Hacl.Spec.Poly1305.Field32xN.fadd5",
"Hacl.Poly1305.Field32xN.Lemmas0.fadd5_eval_lemma_i"
] | [] | false | false | true | false | false | let fadd5_eval_lemma #w f1 f2 =
| let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2)) | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test6_expected512 | val test6_expected512:lbytes 64 | val test6_expected512:lbytes 64 | let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 452,
"start_col": 0,
"start_line": 440
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Lib.Sequence.lseq (Lib.IntTypes.int_t Lib.IntTypes.U8 Lib.IntTypes.SEC) 64 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.of_list",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.unit",
"FStar.Pervasives.assert_norm",
"Prims.eq2",
"Prims.int",
"FStar.List.Tot.Base.length",
"Prims.list",
"FStar.List.Tot.Base.map",
"FStar.UInt8.t",
"Lib.RawIntTypes.u8_from_UInt8",
"Prims.Cons",
"FStar.UInt8.__uint_to_t",
"Prims.Nil"
] | [] | false | false | false | false | false | let test6_expected512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy; 0xb7uy; 0x14uy; 0x93uy; 0xc1uy;
0xdduy; 0x7buy; 0xe8uy; 0xb4uy; 0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy; 0x6buy; 0x56uy; 0xd0uy; 0x37uy;
0xe0uy; 0x5fuy; 0x25uy; 0x98uy; 0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy; 0x8buy; 0x91uy; 0x5auy; 0x98uy;
0x5duy; 0x78uy; 0x65uy; 0x98uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r5_eval_lemma | val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)] | val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)] | let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 37,
"end_line": 213,
"start_col": 0,
"start_line": 209
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (3, 3, 3, 3, 3)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{ Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (10, 10, 10, 10, 10) /\
r5 == Hacl.Spec.Poly1305.Field32xN.precomp_r5 r }
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.feval5 (Hacl.Spec.Poly1305.Field32xN.fmul_r5 f1 r r5) ==
Lib.Sequence.map2 Hacl.Spec.Poly1305.Vec.pfmul
(Hacl.Spec.Poly1305.Field32xN.feval5 f1)
(Hacl.Spec.Poly1305.Field32xN.feval5 r))
[SMTPat (Hacl.Spec.Poly1305.Field32xN.fmul_r5 f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Prims.l_and",
"Prims.eq2",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_wide_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.carry_wide_felem5",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.mul_felem5"
] | [] | true | false | true | false | false | let fmul_r5_eval_lemma #w f1 r r5 =
| let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r5_fits_lemma | val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)] | val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)] | let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 37,
"end_line": 198,
"start_col": 0,
"start_line": 194
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (3, 3, 3, 3, 3)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (10, 10, 10, 10, 10)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.fmul_r5 f1 r r5)
(1,
2,
1,
1,
2)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.fmul_r5 f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_wide_felem5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.carry_wide_felem5",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.mul_felem5"
] | [] | true | false | true | false | false | let fmul_r5_fits_lemma #w f1 r r5 =
| let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.reduce_felem5_eval_lemma | val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)] | val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)] | let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 51,
"end_line": 266,
"start_col": 0,
"start_line": 261
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f (2, 2, 2, 2, 2)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.reduce_felem5 f)
(1,
1,
1,
1,
1) /\
(Hacl.Spec.Poly1305.Field32xN.feval5 f).[ 0 ] ==
(Hacl.Spec.Poly1305.Field32xN.fas_nat5 (Hacl.Spec.Poly1305.Field32xN.reduce_felem5 f)).[ 0 ]
) [SMTPat (Hacl.Spec.Poly1305.Field32xN.reduce_felem5 f)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Poly1305.Field32xN.Lemmas1.subtract_p5_felem5_lemma",
"Hacl.Spec.Poly1305.Field32xN.carry_full_felem5",
"Prims.unit",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_reduce_felem5_lemma",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_full_felem5_fits_lemma",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_full_felem5_eval_lemma"
] | [] | true | false | true | false | false | let reduce_felem5_eval_lemma #w f =
| carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.precomp_r5_zeros | val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w)) | val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w)) | let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 62,
"end_line": 69,
"start_col": 0,
"start_line": 62
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | w: Hacl.Spec.Poly1305.Field32xN.lanes
-> FStar.Pervasives.Lemma
(ensures
(let r =
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w
in
Hacl.Spec.Poly1305.Field32xN.precomp_r5 r ==
(Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w,
Hacl.Spec.Poly1305.Field32xN.zero w))) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Lib.IntVector.vecv_extensionality",
"Lib.IntTypes.U64",
"Lib.IntVector.vec_smul_mod",
"Hacl.Spec.Poly1305.Field32xN.zero",
"Lib.IntTypes.u64",
"Prims.unit",
"Lib.Sequence.eq_intro",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.SEC",
"Lib.IntVector.vec_v",
"FStar.Classical.forall_intro",
"Prims.nat",
"Prims.b2t",
"Prims.op_LessThan",
"Prims.eq2",
"Prims.l_or",
"FStar.Seq.Base.index",
"Lib.Sequence.to_seq",
"Lib.IntTypes.range_t",
"Lib.IntTypes.v",
"Lib.Sequence.op_String_Access",
"Prims.l_True",
"Prims.squash",
"Lib.IntTypes.int_t",
"Lib.IntTypes.mk_int",
"Prims.int",
"Lib.IntTypes.range",
"Lib.Sequence.index",
"Prims.Nil",
"FStar.Pervasives.pattern",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"FStar.Pervasives.Native.tuple5",
"FStar.Pervasives.Native.Mktuple5"
] | [] | false | false | true | false | false | let precomp_r5_zeros w =
| let r = (zero w, zero w, zero w, zero w, zero w) in
let r0, r1, r2, r3, r4 = precomp_r5 r in
let aux (i: nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[ i ] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd_mul_r5_eval_lemma | val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 37,
"end_line": 250,
"start_col": 0,
"start_line": 244
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
acc:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 acc (2, 2, 2, 2, 2)} ->
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (1, 1, 1, 1, 1)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (1, 1, 1, 1, 1)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{ Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (5, 5, 5, 5, 5) /\
r5 == Hacl.Spec.Poly1305.Field32xN.precomp_r5 r }
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.feval5 (Hacl.Spec.Poly1305.Field32xN.fadd_mul_r5 acc f1 r r5) ==
Lib.Sequence.map2 Hacl.Spec.Poly1305.Vec.pfmul
(Lib.Sequence.map2 Hacl.Spec.Poly1305.Vec.pfadd
(Hacl.Spec.Poly1305.Field32xN.feval5 acc)
(Hacl.Spec.Poly1305.Field32xN.feval5 f1))
(Hacl.Spec.Poly1305.Field32xN.feval5 r))
[SMTPat (Hacl.Spec.Poly1305.Field32xN.fadd_mul_r5 acc f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Prims.l_and",
"Prims.eq2",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_wide_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.carry_wide_felem5",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.mul_felem5",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.fadd5"
] | [] | true | false | true | false | false | let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
| let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd_mul_r5_fits_lemma | val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 37,
"end_line": 231,
"start_col": 0,
"start_line": 225
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
acc:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 acc (2, 2, 2, 2, 2)} ->
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (1, 1, 1, 1, 1)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (1, 1, 1, 1, 1)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (5, 5, 5, 5, 5)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.fadd_mul_r5 acc
f1
r
r5)
(1,
2,
1,
1,
2)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.fadd_mul_r5 acc f1 r r5)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Poly1305.Field32xN.Lemmas1.carry_wide_felem5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.carry_wide_felem5",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.mul_felem5",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.fadd5"
] | [] | true | false | true | false | false | let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
| let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fadd5_fits_lemma | val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)] | val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)] | let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24 | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 27,
"end_line": 87,
"start_col": 0,
"start_line": 79
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (2, 2, 2, 2, 2)} ->
f2:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f2 (1, 1, 1, 1, 1)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.fadd5 f1 f2)
(3,
3,
3,
3,
3)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.fadd5 f1 f2)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Lib.IntVector.vec_add_mod_lemma",
"Lib.IntTypes.U64",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.fadd5"
] | [] | false | false | true | false | false | let fadd5_fits_lemma #w f1 f2 =
| let f10, f11, f12, f13, f14 = f1 in
let f20, f21, f22, f23, f24 = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24 | false |
Hacl.Impl.Ed25519.PointDecompress.fst | Hacl.Impl.Ed25519.PointDecompress.point_decompress | val point_decompress:
out:point
-> s:lbuffer uint8 32ul ->
Stack bool
(requires fun h -> live h out /\ live h s)
(ensures fun h0 b h1 -> modifies (loc out) h0 h1 /\
(b ==> F51.point_inv_t h1 out) /\
(b <==> Some? (Spec.Ed25519.point_decompress (as_seq h0 s))) /\
(b ==> (F51.point_eval h1 out == Some?.v (Spec.Ed25519.point_decompress (as_seq h0 s))))
) | val point_decompress:
out:point
-> s:lbuffer uint8 32ul ->
Stack bool
(requires fun h -> live h out /\ live h s)
(ensures fun h0 b h1 -> modifies (loc out) h0 h1 /\
(b ==> F51.point_inv_t h1 out) /\
(b <==> Some? (Spec.Ed25519.point_decompress (as_seq h0 s))) /\
(b ==> (F51.point_eval h1 out == Some?.v (Spec.Ed25519.point_decompress (as_seq h0 s))))
) | let point_decompress out s =
push_frame();
let tmp = create 10ul (u64 0) in
let res = point_decompress_ out s tmp in
pop_frame();
res | {
"file_name": "code/ed25519/Hacl.Impl.Ed25519.PointDecompress.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 5,
"end_line": 107,
"start_col": 0,
"start_line": 102
} | module Hacl.Impl.Ed25519.PointDecompress
module ST = FStar.HyperStack.ST
open FStar.HyperStack.All
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
open Lib.ByteSequence
open Hacl.Bignum25519
module F51 = Hacl.Impl.Ed25519.Field51
module SC = Spec.Curve25519
module SE = Spec.Ed25519
#set-options "--z3rlimit 30 --max_fuel 0 --max_ifuel 0"
inline_for_extraction noextract
val most_significant_bit:
s:lbuffer uint8 32ul ->
Stack uint64
(requires fun h -> live h s)
(ensures fun h0 z h1 -> h0 == h1 /\
(v z = 0 \/ v z = 1) /\
v z == (nat_from_bytes_le (as_seq h0 s) / pow2 255) % 2
)
open FStar.Calc
let most_significant_bit s =
let s31 = s.(31ul) in
let z = s31 >>. 7ul in
(**) let h0 = ST.get() in
(**) FStar.Math.Lemmas.lemma_div_lt_nat (v s31) 8 7;
(**) uints_from_bytes_le_nat_lemma #U8 #SEC #32 (as_seq h0 s);
(**) nat_from_intseq_le_slice_lemma (as_seq h0 s) 31;
(**) nat_from_intseq_le_lemma0 (Seq.slice (as_seq h0 s) 31 32);
(**) assert_norm (31 * 8 == 248);
(**) FStar.Math.Lemmas.lemma_div_mod_plus (nat_from_intseq_le (Seq.slice (as_seq h0 s) 0 31))
(v s31) (pow2 248);
(**) FStar.Math.Lemmas.small_div (nat_from_intseq_le (Seq.slice (as_seq h0 s) 0 31)) (pow2 248);
(**) FStar.Math.Lemmas.division_multiplication_lemma (nat_from_bytes_le (as_seq h0 s)) (pow2 248) (pow2 7);
(**) assert_norm (pow2 248 * pow2 7 = pow2 255);
(**) FStar.Math.Lemmas.small_mod (v s31 / pow2 7) 2;
to_u64 z
inline_for_extraction noextract
val point_decompress_:
out:point
-> s:lbuffer uint8 32ul
-> tmp:lbuffer uint64 10ul ->
Stack bool
(requires fun h ->
live h out /\ live h s /\ live h tmp /\
disjoint s tmp /\ disjoint out tmp /\
F51.mul_inv_t h (gsub tmp 5ul 5ul)
)
(ensures fun h0 b h1 -> modifies (loc out |+| loc tmp) h0 h1 /\
(b <==> Some? (SE.point_decompress (as_seq h0 s))) /\
(b ==> F51.point_inv_t h1 out) /\
(b ==> (F51.point_eval h1 out == Some?.v (SE.point_decompress (as_seq h0 s))))
)
#push-options "--z3rlimit 50"
let point_decompress_ out s tmp =
let y = sub tmp 0ul 5ul in
let x = sub tmp 5ul 5ul in
let sign = most_significant_bit s in
load_51 y s;
let z = Hacl.Impl.Ed25519.RecoverX.recover_x x y sign in
let res =
if z = false then false
else (
let outx = getx out in
let outy = gety out in
let outz = getz out in
let outt = gett out in
copy outx x;
copy outy y;
make_one outz;
fmul outt x y;
true
) in
res
val point_decompress:
out:point
-> s:lbuffer uint8 32ul ->
Stack bool
(requires fun h -> live h out /\ live h s)
(ensures fun h0 b h1 -> modifies (loc out) h0 h1 /\
(b ==> F51.point_inv_t h1 out) /\
(b <==> Some? (Spec.Ed25519.point_decompress (as_seq h0 s))) /\
(b ==> (F51.point_eval h1 out == Some?.v (Spec.Ed25519.point_decompress (as_seq h0 s))))
) | {
"checked_file": "/",
"dependencies": [
"Spec.Ed25519.fst.checked",
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.Ed25519.RecoverX.fst.checked",
"Hacl.Impl.Ed25519.Field51.fst.checked",
"Hacl.Bignum25519.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.Ed25519.PointDecompress.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Calc",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.Ed25519",
"short_module": "SE"
},
{
"abbrev": true,
"full_module": "Spec.Curve25519",
"short_module": "SC"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Ed25519.Field51",
"short_module": "F51"
},
{
"abbrev": false,
"full_module": "Hacl.Bignum25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Ed25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Ed25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | out: Hacl.Bignum25519.point -> s: Lib.Buffer.lbuffer Lib.IntTypes.uint8 32ul
-> FStar.HyperStack.ST.Stack Prims.bool | FStar.HyperStack.ST.Stack | [] | [] | [
"Hacl.Bignum25519.point",
"Lib.Buffer.lbuffer",
"Lib.IntTypes.uint8",
"FStar.UInt32.__uint_to_t",
"Prims.bool",
"Prims.unit",
"FStar.HyperStack.ST.pop_frame",
"Hacl.Impl.Ed25519.PointDecompress.point_decompress_",
"Lib.Buffer.lbuffer_t",
"Lib.Buffer.MUT",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.UInt32.uint_to_t",
"FStar.UInt32.t",
"Lib.Buffer.create",
"Lib.IntTypes.uint64",
"Lib.IntTypes.u64",
"FStar.HyperStack.ST.push_frame"
] | [] | false | true | false | false | false | let point_decompress out s =
| push_frame ();
let tmp = create 10ul (u64 0) in
let res = point_decompress_ out s tmp in
pop_frame ();
res | false |
Spec.HMAC.Test.fst | Spec.HMAC.Test.test_vectors | val test_vectors:list vec | val test_vectors:list vec | let test_vectors : list vec = [
Vec SHA2_224 test1_key test1_data test1_expected224;
Vec SHA2_256 test1_key test1_data test1_expected256;
Vec SHA2_384 test1_key test1_data test1_expected384;
Vec SHA2_512 test1_key test1_data test1_expected512;
Vec SHA2_224 test2_key test2_data test2_expected224;
Vec SHA2_256 test2_key test2_data test2_expected256;
Vec SHA2_384 test2_key test2_data test2_expected384;
Vec SHA2_512 test2_key test2_data test2_expected512;
Vec SHA2_224 test3_key test3_data test3_expected224;
Vec SHA2_256 test3_key test3_data test3_expected256;
Vec SHA2_384 test3_key test3_data test3_expected384;
Vec SHA2_512 test3_key test3_data test3_expected512;
Vec SHA2_224 test4_key test4_data test4_expected224;
Vec SHA2_256 test4_key test4_data test4_expected256;
Vec SHA2_384 test4_key test4_data test4_expected384;
Vec SHA2_512 test4_key test4_data test4_expected512;
Vec SHA2_224 test5_key test5_data test5_expected224;
Vec SHA2_256 test5_key test5_data test5_expected256;
Vec SHA2_384 test5_key test5_data test5_expected384;
Vec SHA2_512 test5_key test5_data test5_expected512;
Vec SHA2_224 test6_key test6_data test6_expected224;
Vec SHA2_256 test6_key test6_data test6_expected256;
Vec SHA2_384 test6_key test6_data test6_expected384;
Vec SHA2_512 test6_key test6_data test6_expected512;
Vec SHA2_224 test7_key test7_data test7_expected224;
Vec SHA2_256 test7_key test7_data test7_expected256;
Vec SHA2_384 test7_key test7_data test7_expected384;
Vec SHA2_512 test7_key test7_data test7_expected512 ] | {
"file_name": "specs/tests/Spec.HMAC.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 55,
"end_line": 604,
"start_col": 0,
"start_line": 570
} | module Spec.HMAC.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
open Spec.Hash.Definitions
module HMAC = Spec.Agile.HMAC
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test 1
let test1_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy; 0x0buy;
0x0buy; 0x0buy; 0x0buy; 0x0buy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test1_data : lbytes 8 =
let l = List.Tot.map u8_from_UInt8 [
0x48uy; 0x69uy; 0x20uy; 0x54uy; 0x68uy; 0x65uy; 0x72uy; 0x65uy
] in
assert_norm (List.Tot.length l == 8);
of_list l
let test1_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x89uy; 0x6fuy; 0xb1uy; 0x12uy; 0x8auy; 0xbbuy; 0xdfuy; 0x19uy;
0x68uy; 0x32uy; 0x10uy; 0x7cuy; 0xd4uy; 0x9duy; 0xf3uy; 0x3fuy;
0x47uy; 0xb4uy; 0xb1uy; 0x16uy; 0x99uy; 0x12uy; 0xbauy; 0x4fuy;
0x53uy; 0x68uy; 0x4buy; 0x22uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0x34uy; 0x4cuy; 0x61uy; 0xd8uy; 0xdbuy; 0x38uy; 0x53uy;
0x5cuy; 0xa8uy; 0xafuy; 0xceuy; 0xafuy; 0x0buy; 0xf1uy; 0x2buy;
0x88uy; 0x1duy; 0xc2uy; 0x00uy; 0xc9uy; 0x83uy; 0x3duy; 0xa7uy;
0x26uy; 0xe9uy; 0x37uy; 0x6cuy; 0x2euy; 0x32uy; 0xcfuy; 0xf7uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xd0uy; 0x39uy; 0x44uy; 0xd8uy; 0x48uy; 0x95uy; 0x62uy;
0x6buy; 0x08uy; 0x25uy; 0xf4uy; 0xabuy; 0x46uy; 0x90uy; 0x7fuy;
0x15uy; 0xf9uy; 0xdauy; 0xdbuy; 0xe4uy; 0x10uy; 0x1euy; 0xc6uy;
0x82uy; 0xaauy; 0x03uy; 0x4cuy; 0x7cuy; 0xebuy; 0xc5uy; 0x9cuy;
0xfauy; 0xeauy; 0x9euy; 0xa9uy; 0x07uy; 0x6euy; 0xdeuy; 0x7fuy;
0x4auy; 0xf1uy; 0x52uy; 0xe8uy; 0xb2uy; 0xfauy; 0x9cuy; 0xb6uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x87uy; 0xaauy; 0x7cuy; 0xdeuy; 0xa5uy; 0xefuy; 0x61uy; 0x9duy;
0x4fuy; 0xf0uy; 0xb4uy; 0x24uy; 0x1auy; 0x1duy; 0x6cuy; 0xb0uy;
0x23uy; 0x79uy; 0xf4uy; 0xe2uy; 0xceuy; 0x4euy; 0xc2uy; 0x78uy;
0x7auy; 0xd0uy; 0xb3uy; 0x05uy; 0x45uy; 0xe1uy; 0x7cuy; 0xdeuy;
0xdauy; 0xa8uy; 0x33uy; 0xb7uy; 0xd6uy; 0xb8uy; 0xa7uy; 0x02uy;
0x03uy; 0x8buy; 0x27uy; 0x4euy; 0xaeuy; 0xa3uy; 0xf4uy; 0xe4uy;
0xbeuy; 0x9duy; 0x91uy; 0x4euy; 0xebuy; 0x61uy; 0xf1uy; 0x70uy;
0x2euy; 0x69uy; 0x6cuy; 0x20uy; 0x3auy; 0x12uy; 0x68uy; 0x54uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 2
let test2_key : lbytes 4 =
let l = List.Tot.map u8_from_UInt8 [ 0x4auy; 0x65uy; 0x66uy; 0x65uy ] in
assert_norm (List.Tot.length l == 4);
of_list l
let test2_data : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x68uy; 0x61uy; 0x74uy; 0x20uy; 0x64uy; 0x6fuy; 0x20uy;
0x79uy; 0x61uy; 0x20uy; 0x77uy; 0x61uy; 0x6euy; 0x74uy; 0x20uy;
0x66uy; 0x6fuy; 0x72uy; 0x20uy; 0x6euy; 0x6fuy; 0x74uy; 0x68uy;
0x69uy; 0x6euy; 0x67uy; 0x3fuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0x0euy; 0x01uy; 0x09uy; 0x8buy; 0xc6uy; 0xdbuy; 0xbfuy;
0x45uy; 0x69uy; 0x0fuy; 0x3auy; 0x7euy; 0x9euy; 0x6duy; 0x0fuy;
0x8buy; 0xbeuy; 0xa2uy; 0xa3uy; 0x9euy; 0x61uy; 0x48uy; 0x00uy;
0x8fuy; 0xd0uy; 0x5euy; 0x44uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x5buy; 0xdcuy; 0xc1uy; 0x46uy; 0xbfuy; 0x60uy; 0x75uy; 0x4euy;
0x6auy; 0x04uy; 0x24uy; 0x26uy; 0x08uy; 0x95uy; 0x75uy; 0xc7uy;
0x5auy; 0x00uy; 0x3fuy; 0x08uy; 0x9duy; 0x27uy; 0x39uy; 0x83uy;
0x9duy; 0xecuy; 0x58uy; 0xb9uy; 0x64uy; 0xecuy; 0x38uy; 0x43uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0x45uy; 0xd2uy; 0xe3uy; 0x76uy; 0x48uy; 0x40uy; 0x31uy;
0x61uy; 0x7fuy; 0x78uy; 0xd2uy; 0xb5uy; 0x8auy; 0x6buy; 0x1buy;
0x9cuy; 0x7euy; 0xf4uy; 0x64uy; 0xf5uy; 0xa0uy; 0x1buy; 0x47uy;
0xe4uy; 0x2euy; 0xc3uy; 0x73uy; 0x63uy; 0x22uy; 0x44uy; 0x5euy;
0x8euy; 0x22uy; 0x40uy; 0xcauy; 0x5euy; 0x69uy; 0xe2uy; 0xc7uy;
0x8buy; 0x32uy; 0x39uy; 0xecuy; 0xfauy; 0xb2uy; 0x16uy; 0x49uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x16uy; 0x4buy; 0x7auy; 0x7buy; 0xfcuy; 0xf8uy; 0x19uy; 0xe2uy;
0xe3uy; 0x95uy; 0xfbuy; 0xe7uy; 0x3buy; 0x56uy; 0xe0uy; 0xa3uy;
0x87uy; 0xbduy; 0x64uy; 0x22uy; 0x2euy; 0x83uy; 0x1fuy; 0xd6uy;
0x10uy; 0x27uy; 0x0cuy; 0xd7uy; 0xeauy; 0x25uy; 0x05uy; 0x54uy;
0x97uy; 0x58uy; 0xbfuy; 0x75uy; 0xc0uy; 0x5auy; 0x99uy; 0x4auy;
0x6duy; 0x03uy; 0x4fuy; 0x65uy; 0xf8uy; 0xf0uy; 0xe6uy; 0xfduy;
0xcauy; 0xeauy; 0xb1uy; 0xa3uy; 0x4duy; 0x4auy; 0x6buy; 0x4buy;
0x63uy; 0x6euy; 0x07uy; 0x0auy; 0x38uy; 0xbcuy; 0xe7uy; 0x37uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 3
let test3_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test3_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy; 0xdduy;
0xdduy; 0xdduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test3_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0xb3uy; 0xcbuy; 0x35uy; 0x88uy; 0xc6uy; 0xc1uy; 0xf6uy;
0xffuy; 0xa9uy; 0x69uy; 0x4duy; 0x7duy; 0x6auy; 0xd2uy; 0x64uy;
0x93uy; 0x65uy; 0xb0uy; 0xc1uy; 0xf6uy; 0x5duy; 0x69uy; 0xd1uy;
0xecuy; 0x83uy; 0x33uy; 0xeauy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x77uy; 0x3euy; 0xa9uy; 0x1euy; 0x36uy; 0x80uy; 0x0euy; 0x46uy;
0x85uy; 0x4duy; 0xb8uy; 0xebuy; 0xd0uy; 0x91uy; 0x81uy; 0xa7uy;
0x29uy; 0x59uy; 0x09uy; 0x8buy; 0x3euy; 0xf8uy; 0xc1uy; 0x22uy;
0xd9uy; 0x63uy; 0x55uy; 0x14uy; 0xceuy; 0xd5uy; 0x65uy; 0xfeuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x88uy; 0x06uy; 0x26uy; 0x08uy; 0xd3uy; 0xe6uy; 0xaduy; 0x8auy;
0x0auy; 0xa2uy; 0xacuy; 0xe0uy; 0x14uy; 0xc8uy; 0xa8uy; 0x6fuy;
0x0auy; 0xa6uy; 0x35uy; 0xd9uy; 0x47uy; 0xacuy; 0x9fuy; 0xebuy;
0xe8uy; 0x3euy; 0xf4uy; 0xe5uy; 0x59uy; 0x66uy; 0x14uy; 0x4buy;
0x2auy; 0x5auy; 0xb3uy; 0x9duy; 0xc1uy; 0x38uy; 0x14uy; 0xb9uy;
0x4euy; 0x3auy; 0xb6uy; 0xe1uy; 0x01uy; 0xa3uy; 0x4fuy; 0x27uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xfauy; 0x73uy; 0xb0uy; 0x08uy; 0x9duy; 0x56uy; 0xa2uy; 0x84uy;
0xefuy; 0xb0uy; 0xf0uy; 0x75uy; 0x6cuy; 0x89uy; 0x0buy; 0xe9uy;
0xb1uy; 0xb5uy; 0xdbuy; 0xdduy; 0x8euy; 0xe8uy; 0x1auy; 0x36uy;
0x55uy; 0xf8uy; 0x3euy; 0x33uy; 0xb2uy; 0x27uy; 0x9duy; 0x39uy;
0xbfuy; 0x3euy; 0x84uy; 0x82uy; 0x79uy; 0xa7uy; 0x22uy; 0xc8uy;
0x06uy; 0xb4uy; 0x85uy; 0xa4uy; 0x7euy; 0x67uy; 0xc8uy; 0x07uy;
0xb9uy; 0x46uy; 0xa3uy; 0x37uy; 0xbeuy; 0xe8uy; 0x94uy; 0x26uy;
0x74uy; 0x27uy; 0x88uy; 0x59uy; 0xe1uy; 0x32uy; 0x92uy; 0xfbuy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 4
let test4_key : lbytes 25 =
let l = List.Tot.map u8_from_UInt8 [
0x01uy; 0x02uy; 0x03uy; 0x04uy; 0x05uy; 0x06uy; 0x07uy; 0x08uy;
0x09uy; 0x0auy; 0x0buy; 0x0cuy; 0x0duy; 0x0euy; 0x0fuy; 0x10uy;
0x11uy; 0x12uy; 0x13uy; 0x14uy; 0x15uy; 0x16uy; 0x17uy; 0x18uy;
0x19uy
] in
assert_norm (List.Tot.length l == 25);
of_list l
let test4_data : lbytes 50 =
let l = List.Tot.map u8_from_UInt8 [
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy; 0xcduy;
0xcduy; 0xcduy
] in
assert_norm (List.Tot.length l == 50);
of_list l
let test4_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6cuy; 0x11uy; 0x50uy; 0x68uy; 0x74uy; 0x01uy; 0x3cuy; 0xacuy;
0x6auy; 0x2auy; 0xbcuy; 0x1buy; 0xb3uy; 0x82uy; 0x62uy; 0x7cuy;
0xecuy; 0x6auy; 0x90uy; 0xd8uy; 0x6euy; 0xfcuy; 0x01uy; 0x2duy;
0xe7uy; 0xafuy; 0xecuy; 0x5auy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x82uy; 0x55uy; 0x8auy; 0x38uy; 0x9auy; 0x44uy; 0x3cuy; 0x0euy;
0xa4uy; 0xccuy; 0x81uy; 0x98uy; 0x99uy; 0xf2uy; 0x08uy; 0x3auy;
0x85uy; 0xf0uy; 0xfauy; 0xa3uy; 0xe5uy; 0x78uy; 0xf8uy; 0x07uy;
0x7auy; 0x2euy; 0x3fuy; 0xf4uy; 0x67uy; 0x29uy; 0x66uy; 0x5buy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x3euy; 0x8auy; 0x69uy; 0xb7uy; 0x78uy; 0x3cuy; 0x25uy; 0x85uy;
0x19uy; 0x33uy; 0xabuy; 0x62uy; 0x90uy; 0xafuy; 0x6cuy; 0xa7uy;
0x7auy; 0x99uy; 0x81uy; 0x48uy; 0x08uy; 0x50uy; 0x00uy; 0x9cuy;
0xc5uy; 0x57uy; 0x7cuy; 0x6euy; 0x1fuy; 0x57uy; 0x3buy; 0x4euy;
0x68uy; 0x01uy; 0xdduy; 0x23uy; 0xc4uy; 0xa7uy; 0xd6uy; 0x79uy;
0xccuy; 0xf8uy; 0xa3uy; 0x86uy; 0xc6uy; 0x74uy; 0xcfuy; 0xfbuy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb0uy; 0xbauy; 0x46uy; 0x56uy; 0x37uy; 0x45uy; 0x8cuy; 0x69uy;
0x90uy; 0xe5uy; 0xa8uy; 0xc5uy; 0xf6uy; 0x1duy; 0x4auy; 0xf7uy;
0xe5uy; 0x76uy; 0xd9uy; 0x7fuy; 0xf9uy; 0x4buy; 0x87uy; 0x2duy;
0xe7uy; 0x6fuy; 0x80uy; 0x50uy; 0x36uy; 0x1euy; 0xe3uy; 0xdbuy;
0xa9uy; 0x1cuy; 0xa5uy; 0xc1uy; 0x1auy; 0xa2uy; 0x5euy; 0xb4uy;
0xd6uy; 0x79uy; 0x27uy; 0x5cuy; 0xc5uy; 0x78uy; 0x80uy; 0x63uy;
0xa5uy; 0xf1uy; 0x97uy; 0x41uy; 0x12uy; 0x0cuy; 0x4fuy; 0x2duy;
0xe2uy; 0xaduy; 0xebuy; 0xebuy; 0x10uy; 0xa2uy; 0x98uy; 0xdduy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 5
let test5_key : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy;
0x0cuy; 0x0cuy; 0x0cuy; 0x0cuy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_data : lbytes 20 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x57uy; 0x69uy; 0x74uy;
0x68uy; 0x20uy; 0x54uy; 0x72uy; 0x75uy; 0x6euy; 0x63uy; 0x61uy;
0x74uy; 0x69uy; 0x6fuy; 0x6euy
] in
assert_norm (List.Tot.length l == 20);
of_list l
let test5_expected224 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x0euy; 0x2auy; 0xeauy; 0x68uy; 0xa9uy; 0x0cuy; 0x8duy; 0x37uy;
0xc9uy; 0x88uy; 0xbcuy; 0xdbuy; 0x9fuy; 0xcauy; 0x6fuy; 0xa8uy;
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected256 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xa3uy; 0xb6uy; 0x16uy; 0x74uy; 0x73uy; 0x10uy; 0x0euy; 0xe0uy;
0x6euy; 0x0cuy; 0x79uy; 0x6cuy; 0x29uy; 0x55uy; 0x55uy; 0x2buy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected384 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0xbfuy; 0x34uy; 0xc3uy; 0x50uy; 0x3buy; 0x2auy; 0x23uy;
0xa4uy; 0x6euy; 0xfcuy; 0x61uy; 0x9buy; 0xaeuy; 0xf8uy; 0x97uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
let test5_expected512 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0x5fuy; 0xaduy; 0x62uy; 0x71uy; 0x58uy; 0x0auy; 0x53uy;
0x1duy; 0x41uy; 0x79uy; 0xbcuy; 0x89uy; 0x1duy; 0x87uy; 0xa6uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test 6
let test6_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test6_data : lbytes 54 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x55uy; 0x73uy; 0x69uy;
0x6euy; 0x67uy; 0x20uy; 0x4cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy;
0x72uy; 0x20uy; 0x54uy; 0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x42uy;
0x6cuy; 0x6fuy; 0x63uy; 0x6buy; 0x2duy; 0x53uy; 0x69uy; 0x7auy;
0x65uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy; 0x20uy; 0x2duy; 0x20uy;
0x48uy; 0x61uy; 0x73uy; 0x68uy; 0x20uy; 0x4buy; 0x65uy; 0x79uy;
0x20uy; 0x46uy; 0x69uy; 0x72uy; 0x73uy; 0x74uy
] in
assert_norm (List.Tot.length l == 54);
of_list l
let test6_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x95uy; 0xe9uy; 0xa0uy; 0xdbuy; 0x96uy; 0x20uy; 0x95uy; 0xaduy;
0xaeuy; 0xbeuy; 0x9buy; 0x2duy; 0x6fuy; 0x0duy; 0xbcuy; 0xe2uy;
0xd4uy; 0x99uy; 0xf1uy; 0x12uy; 0xf2uy; 0xd2uy; 0xb7uy; 0x27uy;
0x3fuy; 0xa6uy; 0x87uy; 0x0euy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test6_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x60uy; 0xe4uy; 0x31uy; 0x59uy; 0x1euy; 0xe0uy; 0xb6uy; 0x7fuy;
0x0duy; 0x8auy; 0x26uy; 0xaauy; 0xcbuy; 0xf5uy; 0xb7uy; 0x7fuy;
0x8euy; 0x0buy; 0xc6uy; 0x21uy; 0x37uy; 0x28uy; 0xc5uy; 0x14uy;
0x05uy; 0x46uy; 0x04uy; 0x0fuy; 0x0euy; 0xe3uy; 0x7fuy; 0x54uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test6_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x4euy; 0xceuy; 0x08uy; 0x44uy; 0x85uy; 0x81uy; 0x3euy; 0x90uy;
0x88uy; 0xd2uy; 0xc6uy; 0x3auy; 0x04uy; 0x1buy; 0xc5uy; 0xb4uy;
0x4fuy; 0x9euy; 0xf1uy; 0x01uy; 0x2auy; 0x2buy; 0x58uy; 0x8fuy;
0x3cuy; 0xd1uy; 0x1fuy; 0x05uy; 0x03uy; 0x3auy; 0xc4uy; 0xc6uy;
0x0cuy; 0x2euy; 0xf6uy; 0xabuy; 0x40uy; 0x30uy; 0xfeuy; 0x82uy;
0x96uy; 0x24uy; 0x8duy; 0xf1uy; 0x63uy; 0xf4uy; 0x49uy; 0x52uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test6_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x80uy; 0xb2uy; 0x42uy; 0x63uy; 0xc7uy; 0xc1uy; 0xa3uy; 0xebuy;
0xb7uy; 0x14uy; 0x93uy; 0xc1uy; 0xdduy; 0x7buy; 0xe8uy; 0xb4uy;
0x9buy; 0x46uy; 0xd1uy; 0xf4uy; 0x1buy; 0x4auy; 0xeeuy; 0xc1uy;
0x12uy; 0x1buy; 0x01uy; 0x37uy; 0x83uy; 0xf8uy; 0xf3uy; 0x52uy;
0x6buy; 0x56uy; 0xd0uy; 0x37uy; 0xe0uy; 0x5fuy; 0x25uy; 0x98uy;
0xbduy; 0x0fuy; 0xd2uy; 0x21uy; 0x5duy; 0x6auy; 0x1euy; 0x52uy;
0x95uy; 0xe6uy; 0x4fuy; 0x73uy; 0xf6uy; 0x3fuy; 0x0auy; 0xecuy;
0x8buy; 0x91uy; 0x5auy; 0x98uy; 0x5duy; 0x78uy; 0x65uy; 0x98uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test 7
let test7_key : lbytes 131 =
let l = List.Tot.map u8_from_UInt8 [
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy; 0xaauy;
0xaauy; 0xaauy; 0xaauy
] in
assert_norm (List.Tot.length l == 131);
of_list l
let test7_data : lbytes 152 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x68uy; 0x69uy; 0x73uy; 0x20uy; 0x69uy; 0x73uy; 0x20uy;
0x61uy; 0x20uy; 0x74uy; 0x65uy; 0x73uy; 0x74uy; 0x20uy; 0x75uy;
0x73uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x61uy; 0x20uy; 0x6cuy;
0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy; 0x68uy;
0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy; 0x6buy;
0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x6buy; 0x65uy;
0x79uy; 0x20uy; 0x61uy; 0x6euy; 0x64uy; 0x20uy; 0x61uy; 0x20uy;
0x6cuy; 0x61uy; 0x72uy; 0x67uy; 0x65uy; 0x72uy; 0x20uy; 0x74uy;
0x68uy; 0x61uy; 0x6euy; 0x20uy; 0x62uy; 0x6cuy; 0x6fuy; 0x63uy;
0x6buy; 0x2duy; 0x73uy; 0x69uy; 0x7auy; 0x65uy; 0x20uy; 0x64uy;
0x61uy; 0x74uy; 0x61uy; 0x2euy; 0x20uy; 0x54uy; 0x68uy; 0x65uy;
0x20uy; 0x6buy; 0x65uy; 0x79uy; 0x20uy; 0x6euy; 0x65uy; 0x65uy;
0x64uy; 0x73uy; 0x20uy; 0x74uy; 0x6fuy; 0x20uy; 0x62uy; 0x65uy;
0x20uy; 0x68uy; 0x61uy; 0x73uy; 0x68uy; 0x65uy; 0x64uy; 0x20uy;
0x62uy; 0x65uy; 0x66uy; 0x6fuy; 0x72uy; 0x65uy; 0x20uy; 0x62uy;
0x65uy; 0x69uy; 0x6euy; 0x67uy; 0x20uy; 0x75uy; 0x73uy; 0x65uy;
0x64uy; 0x20uy; 0x62uy; 0x79uy; 0x20uy; 0x74uy; 0x68uy; 0x65uy;
0x20uy; 0x48uy; 0x4duy; 0x41uy; 0x43uy; 0x20uy; 0x61uy; 0x6cuy;
0x67uy; 0x6fuy; 0x72uy; 0x69uy; 0x74uy; 0x68uy; 0x6duy; 0x2euy
] in
assert_norm (List.Tot.length l == 152);
of_list l
let test7_expected224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x85uy; 0x41uy; 0x66uy; 0xacuy; 0x5duy; 0x9fuy; 0x02uy;
0x3fuy; 0x54uy; 0xd5uy; 0x17uy; 0xd0uy; 0xb3uy; 0x9duy; 0xbduy;
0x94uy; 0x67uy; 0x70uy; 0xdbuy; 0x9cuy; 0x2buy; 0x95uy; 0xc9uy;
0xf6uy; 0xf5uy; 0x65uy; 0xd1uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test7_expected256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x9buy; 0x09uy; 0xffuy; 0xa7uy; 0x1buy; 0x94uy; 0x2fuy; 0xcbuy;
0x27uy; 0x63uy; 0x5fuy; 0xbcuy; 0xd5uy; 0xb0uy; 0xe9uy; 0x44uy;
0xbfuy; 0xdcuy; 0x63uy; 0x64uy; 0x4fuy; 0x07uy; 0x13uy; 0x93uy;
0x8auy; 0x7fuy; 0x51uy; 0x53uy; 0x5cuy; 0x3auy; 0x35uy; 0xe2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test7_expected384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x66uy; 0x17uy; 0x17uy; 0x8euy; 0x94uy; 0x1fuy; 0x02uy; 0x0duy;
0x35uy; 0x1euy; 0x2fuy; 0x25uy; 0x4euy; 0x8fuy; 0xd3uy; 0x2cuy;
0x60uy; 0x24uy; 0x20uy; 0xfeuy; 0xb0uy; 0xb8uy; 0xfbuy; 0x9auy;
0xdcuy; 0xceuy; 0xbbuy; 0x82uy; 0x46uy; 0x1euy; 0x99uy; 0xc5uy;
0xa6uy; 0x78uy; 0xccuy; 0x31uy; 0xe7uy; 0x99uy; 0x17uy; 0x6duy;
0x38uy; 0x60uy; 0xe6uy; 0x11uy; 0x0cuy; 0x46uy; 0x52uy; 0x3euy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test7_expected512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xe3uy; 0x7buy; 0x6auy; 0x77uy; 0x5duy; 0xc8uy; 0x7duy; 0xbauy;
0xa4uy; 0xdfuy; 0xa9uy; 0xf9uy; 0x6euy; 0x5euy; 0x3fuy; 0xfduy;
0xdeuy; 0xbduy; 0x71uy; 0xf8uy; 0x86uy; 0x72uy; 0x89uy; 0x86uy;
0x5duy; 0xf5uy; 0xa3uy; 0x2duy; 0x20uy; 0xcduy; 0xc9uy; 0x44uy;
0xb6uy; 0x02uy; 0x2cuy; 0xacuy; 0x3cuy; 0x49uy; 0x82uy; 0xb1uy;
0x0duy; 0x5euy; 0xebuy; 0x55uy; 0xc3uy; 0xe4uy; 0xdeuy; 0x15uy;
0x13uy; 0x46uy; 0x76uy; 0xfbuy; 0x6duy; 0xe0uy; 0x44uy; 0x60uy;
0x65uy; 0xc9uy; 0x74uy; 0x40uy; 0xfauy; 0x8cuy; 0x6auy; 0x58uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
let _: squash (pow2 32 < pow2 61 /\ pow2 32 < pow2 125) =
Math.Lemmas.pow2_lt_compat 61 32;
Math.Lemmas.pow2_lt_compat 125 32
noeq type vec =
| Vec :
a:fixed_len_alg
-> key:bytes{HMAC.keysized a (Seq.length key)}
-> data:bytes{(Seq.length data + block_length a) `less_than_max_input_length` a}
-> expected:bytes{length expected <= hash_length a} -> vec | {
"checked_file": "/",
"dependencies": [
"Spec.Hash.Definitions.fst.checked",
"Spec.Agile.HMAC.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.RawIntTypes.fsti.checked",
"Lib.PrintSequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.HMAC.Test.fst"
} | [
{
"abbrev": true,
"full_module": "Spec.Agile.HMAC",
"short_module": "HMAC"
},
{
"abbrev": false,
"full_module": "Spec.Hash.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Lib.PrintSequence",
"short_module": "PS"
},
{
"abbrev": false,
"full_module": "Lib.ByteSequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.RawIntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.HMAC",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 0,
"initial_ifuel": 0,
"max_fuel": 0,
"max_ifuel": 0,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Prims.list Spec.HMAC.Test.vec | Prims.Tot | [
"total"
] | [] | [
"Prims.Cons",
"Spec.HMAC.Test.vec",
"Spec.HMAC.Test.Vec",
"Spec.Hash.Definitions.SHA2_224",
"Spec.HMAC.Test.test1_key",
"Spec.HMAC.Test.test1_data",
"Spec.HMAC.Test.test1_expected224",
"Spec.Hash.Definitions.SHA2_256",
"Spec.HMAC.Test.test1_expected256",
"Spec.Hash.Definitions.SHA2_384",
"Spec.HMAC.Test.test1_expected384",
"Spec.Hash.Definitions.SHA2_512",
"Spec.HMAC.Test.test1_expected512",
"Spec.HMAC.Test.test2_key",
"Spec.HMAC.Test.test2_data",
"Spec.HMAC.Test.test2_expected224",
"Spec.HMAC.Test.test2_expected256",
"Spec.HMAC.Test.test2_expected384",
"Spec.HMAC.Test.test2_expected512",
"Spec.HMAC.Test.test3_key",
"Spec.HMAC.Test.test3_data",
"Spec.HMAC.Test.test3_expected224",
"Spec.HMAC.Test.test3_expected256",
"Spec.HMAC.Test.test3_expected384",
"Spec.HMAC.Test.test3_expected512",
"Spec.HMAC.Test.test4_key",
"Spec.HMAC.Test.test4_data",
"Spec.HMAC.Test.test4_expected224",
"Spec.HMAC.Test.test4_expected256",
"Spec.HMAC.Test.test4_expected384",
"Spec.HMAC.Test.test4_expected512",
"Spec.HMAC.Test.test5_key",
"Spec.HMAC.Test.test5_data",
"Spec.HMAC.Test.test5_expected224",
"Spec.HMAC.Test.test5_expected256",
"Spec.HMAC.Test.test5_expected384",
"Spec.HMAC.Test.test5_expected512",
"Spec.HMAC.Test.test6_key",
"Spec.HMAC.Test.test6_data",
"Spec.HMAC.Test.test6_expected224",
"Spec.HMAC.Test.test6_expected256",
"Spec.HMAC.Test.test6_expected384",
"Spec.HMAC.Test.test6_expected512",
"Spec.HMAC.Test.test7_key",
"Spec.HMAC.Test.test7_data",
"Spec.HMAC.Test.test7_expected224",
"Spec.HMAC.Test.test7_expected256",
"Spec.HMAC.Test.test7_expected384",
"Spec.HMAC.Test.test7_expected512",
"Prims.Nil"
] | [] | false | false | false | true | false | let test_vectors:list vec =
| [
Vec SHA2_224 test1_key test1_data test1_expected224;
Vec SHA2_256 test1_key test1_data test1_expected256;
Vec SHA2_384 test1_key test1_data test1_expected384;
Vec SHA2_512 test1_key test1_data test1_expected512;
Vec SHA2_224 test2_key test2_data test2_expected224;
Vec SHA2_256 test2_key test2_data test2_expected256;
Vec SHA2_384 test2_key test2_data test2_expected384;
Vec SHA2_512 test2_key test2_data test2_expected512;
Vec SHA2_224 test3_key test3_data test3_expected224;
Vec SHA2_256 test3_key test3_data test3_expected256;
Vec SHA2_384 test3_key test3_data test3_expected384;
Vec SHA2_512 test3_key test3_data test3_expected512;
Vec SHA2_224 test4_key test4_data test4_expected224;
Vec SHA2_256 test4_key test4_data test4_expected256;
Vec SHA2_384 test4_key test4_data test4_expected384;
Vec SHA2_512 test4_key test4_data test4_expected512;
Vec SHA2_224 test5_key test5_data test5_expected224;
Vec SHA2_256 test5_key test5_data test5_expected256;
Vec SHA2_384 test5_key test5_data test5_expected384;
Vec SHA2_512 test5_key test5_data test5_expected512;
Vec SHA2_224 test6_key test6_data test6_expected224;
Vec SHA2_256 test6_key test6_data test6_expected256;
Vec SHA2_384 test6_key test6_data test6_expected384;
Vec SHA2_512 test6_key test6_data test6_expected512;
Vec SHA2_224 test7_key test7_data test7_expected224;
Vec SHA2_256 test7_key test7_data test7_expected256;
Vec SHA2_384 test7_key test7_data test7_expected384;
Vec SHA2_512 test7_key test7_data test7_expected512
] | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.store_felem5_lemma | val store_felem5_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (1, 1, 1, 1, 1)} ->
Lemma
(let (lo, hi) = store_felem5 f in
v hi * pow2 64 + v lo == (fas_nat5 f).[0] % pow2 128)
[SMTPat (store_felem5 f)] | val store_felem5_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (1, 1, 1, 1, 1)} ->
Lemma
(let (lo, hi) = store_felem5 f in
v hi * pow2 64 + v lo == (fas_nat5 f).[0] % pow2 128)
[SMTPat (store_felem5 f)] | let store_felem5_lemma #w f =
store_felem5_lemma #w f | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 25,
"end_line": 827,
"start_col": 0,
"start_line": 826
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2))
let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a
#push-options "--z3rlimit 150"
val fmul_r2_normalize51:
a:felem5 2
-> fa1:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 a (1, 2, 1, 1, 2) /\
felem_fits5 fa1 (1, 2, 1, 1, 2) /\
feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1])
(ensures fun out ->
(feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1] /\
felem_fits5 out (2, 4, 2, 2, 4))
let fmul_r2_normalize51 a fa1 =
let (a0, a1, a2, a3, a4) = a in
let (a10, a11, a12, a13, a14) = fa1 in
let o0 = vec_add_mod a0 a10 in
let o1 = vec_add_mod a1 a11 in
let o2 = vec_add_mod a2 a12 in
let o3 = vec_add_mod a3 a13 in
let o4 = vec_add_mod a4 a14 in
let out = (o0, o1, o2, o3, o4) in
let (a0, a1, a2, a3, a4) = as_tup64_i a 0 in
let (a10, a11, a12, a13, a14) = as_tup64_i fa1 0 in
let (o0, o1, o2, o3, o4) = as_tup64_i out 0 in
FStar.Math.Lemmas.modulo_lemma (v a0 + v a10) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a1 + v a11) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a2 + v a12) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a3 + v a13) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a4 + v a14) (pow2 64);
assert (felem_fits5 out (2, 4, 2, 2, 4));
calc (==) {
((feval5 a).[0] + (feval5 a).[1]) % Vec.prime;
(==) { }
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime + as_nat5 (a10, a11, a12, a13, a14) % Vec.prime) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l
(as_nat5 (a0, a1, a2, a3, a4)) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime;
FStar.Math.Lemmas.lemma_mod_plus_distr_r
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime }
(as_nat5 (a0, a1, a2, a3, a4) + as_nat5 (a10, a11, a12, a13, a14)) % Vec.prime;
(==) { }
(feval5 out).[0];
};
out
#pop-options
val fmul_r2_normalize5_lemma:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures
(let out = fmul_r2_normalize5 acc r r2 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_2 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r2_normalize5 acc r r2)]
let fmul_r2_normalize5_lemma acc r r2 =
let a = fmul_r2_normalize50 acc r r2 in
let (a0, a1, a2, a3, a4) = a in
let a10 = vec_interleave_high a0 a0 in
vec_interleave_high_lemma2 a0 a0;
let a11 = vec_interleave_high a1 a1 in
vec_interleave_high_lemma2 a1 a1;
let a12 = vec_interleave_high a2 a2 in
vec_interleave_high_lemma2 a2 a2;
let a13 = vec_interleave_high a3 a3 in
vec_interleave_high_lemma2 a3 a3;
let a14 = vec_interleave_high a4 a4 in
vec_interleave_high_lemma2 a4 a4;
let fa1 = (a10, a11, a12, a13, a14) in
eq_intro (feval5 fa1) (create2 (feval5 a).[1] (feval5 a).[1]);
assert (feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1]);
assert (felem_fits5 fa1 (1, 2, 1, 1, 2));
let out = fmul_r2_normalize51 a fa1 in
assert ((feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1]);
let res = carry_full_felem5 out in
carry_full_felem5_lemma out
val fmul_r4_normalize50:
acc:felem5 4
-> r:felem5 4
-> r2:felem5 4
-> r3:felem5 4
-> r4:felem5 4 ->
Pure (felem5 4)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
felem_fits5 r3 (2, 2, 2, 2, 2) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.fmul (feval5 r) (feval5 r) /\
feval5 r3 == Vec.fmul (feval5 r2) (feval5 r) /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures fun out ->
let fr4321 = create4 (feval5 r4).[0] (feval5 r3).[0] (feval5 r2).[0] (feval5 r).[0] in
feval5 out == Vec.fmul (feval5 acc) fr4321 /\
felem_fits5 out (1, 2, 1, 1, 2))
let fmul_r4_normalize50 acc fr fr2 fr3 fr4 =
let (r10, r11, r12, r13, r14) = fr in
let (r20, r21, r22, r23, r24) = fr2 in
let (r30, r31, r32, r33, r34) = fr3 in
let (r40, r41, r42, r43, r44) = fr4 in
let (a0, a1, a2, a3, a4) = acc in
let v12120 = vec_interleave_low r20 r10 in
vec_interleave_low_lemma_uint64_4 r20 r10;
let v34340 = vec_interleave_low r40 r30 in
vec_interleave_low_lemma_uint64_4 r40 r30;
let r12340 = vec_interleave_low_n 2 v34340 v12120 in
vec_interleave_low_n_lemma_uint64_4_2 v34340 v12120;
let v12121 = vec_interleave_low r21 r11 in
vec_interleave_low_lemma_uint64_4 r21 r11;
let v34341 = vec_interleave_low r41 r31 in
vec_interleave_low_lemma_uint64_4 r41 r31;
let r12341 = vec_interleave_low_n 2 v34341 v12121 in
vec_interleave_low_n_lemma_uint64_4_2 v34341 v12121;
let v12122 = vec_interleave_low r22 r12 in
vec_interleave_low_lemma_uint64_4 r22 r12;
let v34342 = vec_interleave_low r42 r32 in
vec_interleave_low_lemma_uint64_4 r42 r32;
let r12342 = vec_interleave_low_n 2 v34342 v12122 in
vec_interleave_low_n_lemma_uint64_4_2 v34342 v12122;
let v12123 = vec_interleave_low r23 r13 in
vec_interleave_low_lemma_uint64_4 r23 r13;
let v34343 = vec_interleave_low r43 r33 in
vec_interleave_low_lemma_uint64_4 r43 r33;
let r12343 = vec_interleave_low_n 2 v34343 v12123 in
vec_interleave_low_n_lemma_uint64_4_2 v34343 v12123;
let v12124 = vec_interleave_low r24 r14 in
vec_interleave_low_lemma_uint64_4 r24 r14;
let v34344 = vec_interleave_low r44 r34 in
vec_interleave_low_lemma_uint64_4 r44 r34;
let r12344 = vec_interleave_low_n 2 v34344 v12124 in
vec_interleave_low_n_lemma_uint64_4_2 v34344 v12124;
let fr1234 = (r12340, r12341, r12342, r12343, r12344) in
eq_intro (feval5 fr1234) (create4 (feval5 fr4).[0] (feval5 fr3).[0] (feval5 fr2).[0] (feval5 fr).[0]);
let fr12345 = precomp_r5 #4 fr1234 in
let out = fmul_r5 #4 acc fr1234 fr12345 in
fmul_r5_eval_lemma acc fr1234 fr12345;
fmul_r5_fits_lemma acc fr1234 fr12345;
out
val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3])
let lemma_fmul_r4_normalize51 #m o =
let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let (o0, o1, o2, o3) = ((vec_v o).[0], (vec_v o).[1], (vec_v o).[2], (vec_v o).[3]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[0] == v o0 + v o2);
assert (v (vec_v v10).[1] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[0] == v (vec_v v10).[1]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64)
val lemma_fmul_r4_normalize51_expand:
v2:felem5 4
-> out:felem5 4 ->
Lemma
(requires
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(uint64xN_v v20).[0] == (uint64xN_v o0).[0] + (uint64xN_v o0).[1] + (uint64xN_v o0).[2] + (uint64xN_v o0).[3] /\
(uint64xN_v v21).[0] == (uint64xN_v o1).[0] + (uint64xN_v o1).[1] + (uint64xN_v o1).[2] + (uint64xN_v o1).[3] /\
(uint64xN_v v22).[0] == (uint64xN_v o2).[0] + (uint64xN_v o2).[1] + (uint64xN_v o2).[2] + (uint64xN_v o2).[3] /\
(uint64xN_v v23).[0] == (uint64xN_v o3).[0] + (uint64xN_v o3).[1] + (uint64xN_v o3).[2] + (uint64xN_v o3).[3] /\
(uint64xN_v v24).[0] == (uint64xN_v o4).[0] + (uint64xN_v o4).[1] + (uint64xN_v o4).[2] + (uint64xN_v o4).[3]))
(ensures
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(feval5 v2).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 out).[0] (feval5 out).[1]) (feval5 out).[2]) (feval5 out).[3]))
let lemma_fmul_r4_normalize51_expand v2 out =
let (v20, v21, v22, v23, v24) = as_tup64_i v2 0 in
let (o0, o1, o2, o3, o4) = out in
calc (==) {
as_nat5 (v20, v21, v22, v23, v24) % Vec.prime;
(==) { }
(as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1) + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1))
(as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) Vec.prime }
((as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1)) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.modulo_distributivity (as_nat5 (as_tup64_i out 0)) (as_nat5 (as_tup64_i out 1)) Vec.prime }
(((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2))
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2)) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime) (as_nat5 (as_tup64_i out 2)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r ((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime)
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime;
};
assert ((feval5 v2).[0] ==
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime)
val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3])
let fmul_r4_normalize51 fa =
let (o0, o1, o2, o3, o4) = fa in
let v00 = vec_interleave_high_n 2 o0 o0 in
let v10 = vec_add_mod o0 v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
lemma_fmul_r4_normalize51 #1 o0;
let v01 = vec_interleave_high_n 2 o1 o1 in
let v11 = vec_add_mod o1 v01 in
let v11h = vec_interleave_high v11 v11 in
let v21 = vec_add_mod v11 v11h in
lemma_fmul_r4_normalize51 #2 o1;
let v02 = vec_interleave_high_n 2 o2 o2 in
let v12 = vec_add_mod o2 v02 in
let v12h = vec_interleave_high v12 v12 in
let v22 = vec_add_mod v12 v12h in
lemma_fmul_r4_normalize51 #1 o2;
let v03 = vec_interleave_high_n 2 o3 o3 in
let v13 = vec_add_mod o3 v03 in
let v13h = vec_interleave_high v13 v13 in
let v23 = vec_add_mod v13 v13h in
lemma_fmul_r4_normalize51 #1 o3;
let v04 = vec_interleave_high_n 2 o4 o4 in
let v14 = vec_add_mod o4 v04 in
let v14h = vec_interleave_high v14 v14 in
let v24 = vec_add_mod v14 v14h in
lemma_fmul_r4_normalize51 #2 o4;
let res = (v20, v21, v22, v23, v24) in
lemma_fmul_r4_normalize51_expand res fa;
res
val fmul_r4_normalize5_lemma:
acc:felem5 4
-> r:felem5 4
-> r_5:felem5 4
-> r4:felem5 4 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
r_5 == precomp_r5 r /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures
(let out = fmul_r4_normalize5 acc r r_5 r4 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_4 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r4_normalize5 acc r r_5 r4)]
#restart-solver
#push-options "--z3rlimit 500"
let fmul_r4_normalize5_lemma acc fr fr_5 fr4 =
let fr2 = fmul_r5 #4 fr fr fr_5 in
let fr3 = fmul_r5 #4 fr2 fr fr_5 in
let out = fmul_r4_normalize50 acc fr fr2 fr3 fr4 in
let v2 = fmul_r4_normalize51 out in
let res = carry_full_felem5 v2 in
carry_full_felem5_lemma v2
#pop-options
val load_felem5_lemma:
#w:lanes
-> lo:uint64xN w
-> hi:uint64xN w ->
Lemma
(let f = load_felem5 #w lo hi in
felem_fits5 f (1, 1, 1, 1, 1) /\
felem_less5 f (pow2 128) /\
feval5 f == createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]))
let load_felem5_lemma #w lo hi =
let f = load_felem5 #w lo hi in
assert_norm (pow2 64 * pow2 64 = pow2 128);
assert_norm (pow2 128 < Vec.prime);
let res = createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) in
match w with
| 1 ->
load_felem5_lemma_i #w lo hi 0;
eq_intro (feval5 f) res
| 2 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
eq_intro (feval5 f) res
| 4 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
load_felem5_lemma_i #w lo hi 2;
load_felem5_lemma_i #w lo hi 3;
eq_intro (feval5 f) res
val load_felem5_4_interleave: lo:uint64xN 4 -> hi:uint64xN 4 -> Lemma
(let m0 = vec_interleave_low_n 2 lo hi in
let m1 = vec_interleave_high_n 2 lo hi in
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
let m4 = vec_interleave_high m0 m1 in
let t0 = vec_interleave_low m0 m1 in
let t3 = vec_interleave_low m2 m3 in
vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3] /\
vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2] /\
t3 == vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
let load_felem5_4_interleave lo hi =
let m0 = vec_interleave_low_n 2 lo hi in
vec_interleave_low_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m0 == create4 (vec_v lo).[0] (vec_v lo).[1] (vec_v hi).[0] (vec_v hi).[1]);
let m1 = vec_interleave_high_n 2 lo hi in
vec_interleave_high_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m1 == create4 (vec_v lo).[2] (vec_v lo).[3] (vec_v hi).[2] (vec_v hi).[3]);
let m4 = vec_interleave_high m0 m1 in
vec_interleave_high_lemma_uint64_4 m0 m1;
//assert (vec_v m4 == create4 (vec_v m0).[1] (vec_v m1).[1] (vec_v m0).[3] (vec_v m1).[3]);
assert (vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3]);
let t0 = vec_interleave_low m0 m1 in
vec_interleave_low_lemma_uint64_4 m0 m1;
//assert (vec_v t0 == create4 (vec_v m0).[0] (vec_v m1).[0] (vec_v m0).[2] (vec_v m1).[2]);
assert (vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2]);
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
vec_shift_right_uint128_small2 m0 48ul;
assert ((vec_v m2).[0] == (((vec_v lo).[0] >>. 48ul) |. ((vec_v lo).[1] <<. 16ul)));
assert ((vec_v m2).[2] == (((vec_v hi).[0] >>. 48ul) |. ((vec_v hi).[1] <<. 16ul)));
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
vec_shift_right_uint128_small2 m1 48ul;
assert ((vec_v m3).[0] == (((vec_v lo).[2] >>. 48ul) |. ((vec_v lo).[3] <<. 16ul)));
assert ((vec_v m3).[2] == (((vec_v hi).[2] >>. 48ul) |. ((vec_v hi).[3] <<. 16ul)));
let t3 = vec_interleave_low m2 m3 in
vec_interleave_low_lemma_uint64_4 m2 m3;
eq_intro (vec_v t3) (vec_v (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul)));
vecv_extensionality t3 (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
noextract
val load_felem5_4_compact: lo:uint64xN 4 -> hi:uint64xN 4 -> felem5 4
let load_felem5_4_compact lo hi =
let mask26 = mask26 4 in
let t3 = vec_or (vec_shift_right lo 48ul) (vec_shift_left hi 16ul) in
let o0 = vec_and lo mask26 in
let o1 = vec_and (vec_shift_right lo 26ul) mask26 in
let o2 = vec_and (vec_shift_right t3 4ul) mask26 in
let o3 = vec_and (vec_shift_right t3 30ul) mask26 in
let o4 = vec_shift_right hi 40ul in
(o0, o1, o2, o3, o4)
val load_felem5_4_compact_lemma_i: lo:uint64xN 4 -> hi:uint64xN 4 -> i:nat{i < 4} ->
Lemma
(let f = as_tup64_i (load_felem5_4_compact lo hi) i in
tup64_fits5 f (1, 1, 1, 1, 1) /\
as_nat5 f < pow2 128 /\
as_nat5 f % Vec.prime == (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i])
let load_felem5_4_compact_lemma_i lo hi i =
assert (as_tup64_i (load_felem5_4_compact lo hi) i == load_tup64_4_compact (vec_v lo).[i] (vec_v hi).[i]);
load_tup64_4_compact_lemma (vec_v lo).[i] (vec_v hi).[i]
val load_felem5_4_lemma: lo:uint64xN 4 -> hi:uint64xN 4 ->
Lemma
(let f = load_felem5_4_compact lo hi in
felem_fits5 f (1, 1, 1, 1, 1) /\
felem_less5 f (pow2 128) /\
feval5 f == createi #Vec.pfelem 4 (fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]))
let load_felem5_4_lemma lo hi =
let f = load_felem5_4_compact lo hi in
assert_norm (pow2 64 * pow2 64 = pow2 128);
assert_norm (pow2 128 < Vec.prime);
let res = createi #Vec.pfelem 4
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) in
load_felem5_4_compact_lemma_i lo hi 0;
load_felem5_4_compact_lemma_i lo hi 1;
load_felem5_4_compact_lemma_i lo hi 2;
load_felem5_4_compact_lemma_i lo hi 3;
eq_intro (feval5 f) res
val load_felem5_le: b:lseq uint8 64 -> Lemma
(let lo0 = vec_from_bytes_le U64 4 (sub b 0 32) in
let hi0 = vec_from_bytes_le U64 4 (sub b 32 32) in
let f = load_felem5_4 lo0 hi0 in
felem_fits5 f (1, 1, 1, 1, 1) /\
felem_less5 f (pow2 128) /\
feval5 f == Vec.load_elem4 b)
let load_felem5_le b =
let lo0 = vec_from_bytes_le U64 4 (sub b 0 32) in
let hi0 = vec_from_bytes_le U64 4 (sub b 32 32) in
let lo1 = vec_interleave_low_n 2 lo0 hi0 in
let hi1 = vec_interleave_high_n 2 lo0 hi0 in
let lo = vec_interleave_low lo1 hi1 in
let hi = vec_interleave_high lo1 hi1 in
let out = load_felem5_4_compact lo hi in
load_felem5_4_interleave lo0 hi0;
assert (out == load_felem5_4 lo0 hi0);
load_felem5_4_lemma lo hi;
Hacl.Impl.Poly1305.Lemmas.uints_from_bytes_le_lemma64_4 b;
eq_intro (feval5 out) (Vec.load_elem4 b)
val load_acc5_2_lemma:
f:felem5 2{felem_fits5 f (2, 2, 2, 2, 2)}
-> e:felem5 2{felem_fits5 e (1, 1, 1, 1, 1)} ->
Lemma
(let res = load_acc5_2 f e in
felem_fits5 res (3, 3, 3, 3, 3) /\
feval5 res == Vec.fadd (create2 (feval5 f).[0] 0) (feval5 e))
[SMTPat (load_acc5_2 f e)]
let load_acc5_2_lemma f e =
let (f0, f1, f2, f3, f4) = f in
let r0 = vec_set f0 1ul (u64 0) in
let r1 = vec_set f1 1ul (u64 0) in
let r2 = vec_set f2 1ul (u64 0) in
let r3 = vec_set f3 1ul (u64 0) in
let r4 = vec_set f4 1ul (u64 0) in
let r = (r0, r1, r2, r3, r4) in
//assert ((feval5 r).[0] == (feval5 f).[0]);
assert ((feval5 r).[1] == 0);
eq_intro (feval5 r) (create2 (feval5 f).[0] 0)
val load_acc5_4_lemma:
f:felem5 4{felem_fits5 f (2, 2, 2, 2, 2)}
-> e:felem5 4{felem_fits5 e (1, 1, 1, 1, 1)} ->
Lemma
(let res = load_acc5_4 f e in
felem_fits5 res (3, 3, 3, 3, 3) /\
feval5 res == Vec.fadd (create4 (feval5 f).[0] 0 0 0) (feval5 e))
[SMTPat (load_acc5_4 f e)]
let load_acc5_4_lemma f e =
let (f0, f1, f2, f3, f4) = f in
let (r0, r1, r2, r3, r4) = (zero 4, zero 4, zero 4, zero 4, zero 4) in
let r = (r0, r1, r2, r3, r4) in
assert ((feval5 r).[1] == 0);
assert ((feval5 r).[2] == 0);
assert ((feval5 r).[3] == 0);
let r0 = vec_set r0 0ul (vec_get f0 0ul) in
let r1 = vec_set r1 0ul (vec_get f1 0ul) in
let r2 = vec_set r2 0ul (vec_get f2 0ul) in
let r3 = vec_set r3 0ul (vec_get f3 0ul) in
let r4 = vec_set r4 0ul (vec_get f4 0ul) in
let r = (r0, r1, r2, r3, r4) in
assert ((feval5 r).[0] == (feval5 f).[0]);
assert ((feval5 r).[1] == 0);
assert ((feval5 r).[2] == 0);
assert ((feval5 r).[3] == 0);
eq_intro (feval5 r) (create4 (feval5 f).[0] 0 0 0)
val store_felem5_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (1, 1, 1, 1, 1)} ->
Lemma
(let (lo, hi) = store_felem5 f in
v hi * pow2 64 + v lo == (fas_nat5 f).[0] % pow2 128)
[SMTPat (store_felem5 f)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f (1, 1, 1, 1, 1)}
-> FStar.Pervasives.Lemma
(ensures
(let _ = Hacl.Spec.Poly1305.Field32xN.store_felem5 f in
(let FStar.Pervasives.Native.Mktuple2 #_ #_ lo hi = _ in
Lib.IntTypes.v hi * Prims.pow2 64 + Lib.IntTypes.v lo ==
(Hacl.Spec.Poly1305.Field32xN.fas_nat5 f).[ 0 ] % Prims.pow2 128)
<:
Type0)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.store_felem5 f)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Hacl.Poly1305.Field32xN.Lemmas2.store_felem5_lemma",
"Prims.unit"
] | [] | true | false | true | false | false | let store_felem5_lemma #w f =
| store_felem5_lemma #w f | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.precomp_r5_fits_lemma2 | val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)] | val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)] | let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 57,
"end_line": 55,
"start_col": 0,
"start_line": 54
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.precomp_r5 r)
(10,
10,
10,
10,
10)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.precomp_r5 r)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"FStar.Classical.forall_intro",
"Prims.b2t",
"Prims.op_LessThan",
"Hacl.Spec.Poly1305.Field32xN.as_tup64_i",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Lib.IntTypes.uint64",
"Prims.l_and",
"Prims.eq2",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"Lib.IntTypes.op_Star_Bang",
"Lib.IntTypes.u64",
"Hacl.Poly1305.Field32xN.Lemmas0.precomp_r5_as_tup64",
"Prims.unit"
] | [] | false | false | true | false | false | let precomp_r5_fits_lemma2 #w r =
| FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r4_normalize51 | val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3]) | val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3]) | let fmul_r4_normalize51 fa =
let (o0, o1, o2, o3, o4) = fa in
let v00 = vec_interleave_high_n 2 o0 o0 in
let v10 = vec_add_mod o0 v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
lemma_fmul_r4_normalize51 #1 o0;
let v01 = vec_interleave_high_n 2 o1 o1 in
let v11 = vec_add_mod o1 v01 in
let v11h = vec_interleave_high v11 v11 in
let v21 = vec_add_mod v11 v11h in
lemma_fmul_r4_normalize51 #2 o1;
let v02 = vec_interleave_high_n 2 o2 o2 in
let v12 = vec_add_mod o2 v02 in
let v12h = vec_interleave_high v12 v12 in
let v22 = vec_add_mod v12 v12h in
lemma_fmul_r4_normalize51 #1 o2;
let v03 = vec_interleave_high_n 2 o3 o3 in
let v13 = vec_add_mod o3 v03 in
let v13h = vec_interleave_high v13 v13 in
let v23 = vec_add_mod v13 v13h in
lemma_fmul_r4_normalize51 #1 o3;
let v04 = vec_interleave_high_n 2 o4 o4 in
let v14 = vec_add_mod o4 v04 in
let v14h = vec_interleave_high v14 v14 in
let v24 = vec_add_mod v14 v14h in
lemma_fmul_r4_normalize51 #2 o4;
let res = (v20, v21, v22, v23, v24) in
lemma_fmul_r4_normalize51_expand res fa;
res | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 5,
"end_line": 591,
"start_col": 0,
"start_line": 558
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2))
let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a
#push-options "--z3rlimit 150"
val fmul_r2_normalize51:
a:felem5 2
-> fa1:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 a (1, 2, 1, 1, 2) /\
felem_fits5 fa1 (1, 2, 1, 1, 2) /\
feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1])
(ensures fun out ->
(feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1] /\
felem_fits5 out (2, 4, 2, 2, 4))
let fmul_r2_normalize51 a fa1 =
let (a0, a1, a2, a3, a4) = a in
let (a10, a11, a12, a13, a14) = fa1 in
let o0 = vec_add_mod a0 a10 in
let o1 = vec_add_mod a1 a11 in
let o2 = vec_add_mod a2 a12 in
let o3 = vec_add_mod a3 a13 in
let o4 = vec_add_mod a4 a14 in
let out = (o0, o1, o2, o3, o4) in
let (a0, a1, a2, a3, a4) = as_tup64_i a 0 in
let (a10, a11, a12, a13, a14) = as_tup64_i fa1 0 in
let (o0, o1, o2, o3, o4) = as_tup64_i out 0 in
FStar.Math.Lemmas.modulo_lemma (v a0 + v a10) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a1 + v a11) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a2 + v a12) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a3 + v a13) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a4 + v a14) (pow2 64);
assert (felem_fits5 out (2, 4, 2, 2, 4));
calc (==) {
((feval5 a).[0] + (feval5 a).[1]) % Vec.prime;
(==) { }
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime + as_nat5 (a10, a11, a12, a13, a14) % Vec.prime) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l
(as_nat5 (a0, a1, a2, a3, a4)) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime;
FStar.Math.Lemmas.lemma_mod_plus_distr_r
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime }
(as_nat5 (a0, a1, a2, a3, a4) + as_nat5 (a10, a11, a12, a13, a14)) % Vec.prime;
(==) { }
(feval5 out).[0];
};
out
#pop-options
val fmul_r2_normalize5_lemma:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures
(let out = fmul_r2_normalize5 acc r r2 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_2 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r2_normalize5 acc r r2)]
let fmul_r2_normalize5_lemma acc r r2 =
let a = fmul_r2_normalize50 acc r r2 in
let (a0, a1, a2, a3, a4) = a in
let a10 = vec_interleave_high a0 a0 in
vec_interleave_high_lemma2 a0 a0;
let a11 = vec_interleave_high a1 a1 in
vec_interleave_high_lemma2 a1 a1;
let a12 = vec_interleave_high a2 a2 in
vec_interleave_high_lemma2 a2 a2;
let a13 = vec_interleave_high a3 a3 in
vec_interleave_high_lemma2 a3 a3;
let a14 = vec_interleave_high a4 a4 in
vec_interleave_high_lemma2 a4 a4;
let fa1 = (a10, a11, a12, a13, a14) in
eq_intro (feval5 fa1) (create2 (feval5 a).[1] (feval5 a).[1]);
assert (feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1]);
assert (felem_fits5 fa1 (1, 2, 1, 1, 2));
let out = fmul_r2_normalize51 a fa1 in
assert ((feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1]);
let res = carry_full_felem5 out in
carry_full_felem5_lemma out
val fmul_r4_normalize50:
acc:felem5 4
-> r:felem5 4
-> r2:felem5 4
-> r3:felem5 4
-> r4:felem5 4 ->
Pure (felem5 4)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
felem_fits5 r3 (2, 2, 2, 2, 2) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.fmul (feval5 r) (feval5 r) /\
feval5 r3 == Vec.fmul (feval5 r2) (feval5 r) /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures fun out ->
let fr4321 = create4 (feval5 r4).[0] (feval5 r3).[0] (feval5 r2).[0] (feval5 r).[0] in
feval5 out == Vec.fmul (feval5 acc) fr4321 /\
felem_fits5 out (1, 2, 1, 1, 2))
let fmul_r4_normalize50 acc fr fr2 fr3 fr4 =
let (r10, r11, r12, r13, r14) = fr in
let (r20, r21, r22, r23, r24) = fr2 in
let (r30, r31, r32, r33, r34) = fr3 in
let (r40, r41, r42, r43, r44) = fr4 in
let (a0, a1, a2, a3, a4) = acc in
let v12120 = vec_interleave_low r20 r10 in
vec_interleave_low_lemma_uint64_4 r20 r10;
let v34340 = vec_interleave_low r40 r30 in
vec_interleave_low_lemma_uint64_4 r40 r30;
let r12340 = vec_interleave_low_n 2 v34340 v12120 in
vec_interleave_low_n_lemma_uint64_4_2 v34340 v12120;
let v12121 = vec_interleave_low r21 r11 in
vec_interleave_low_lemma_uint64_4 r21 r11;
let v34341 = vec_interleave_low r41 r31 in
vec_interleave_low_lemma_uint64_4 r41 r31;
let r12341 = vec_interleave_low_n 2 v34341 v12121 in
vec_interleave_low_n_lemma_uint64_4_2 v34341 v12121;
let v12122 = vec_interleave_low r22 r12 in
vec_interleave_low_lemma_uint64_4 r22 r12;
let v34342 = vec_interleave_low r42 r32 in
vec_interleave_low_lemma_uint64_4 r42 r32;
let r12342 = vec_interleave_low_n 2 v34342 v12122 in
vec_interleave_low_n_lemma_uint64_4_2 v34342 v12122;
let v12123 = vec_interleave_low r23 r13 in
vec_interleave_low_lemma_uint64_4 r23 r13;
let v34343 = vec_interleave_low r43 r33 in
vec_interleave_low_lemma_uint64_4 r43 r33;
let r12343 = vec_interleave_low_n 2 v34343 v12123 in
vec_interleave_low_n_lemma_uint64_4_2 v34343 v12123;
let v12124 = vec_interleave_low r24 r14 in
vec_interleave_low_lemma_uint64_4 r24 r14;
let v34344 = vec_interleave_low r44 r34 in
vec_interleave_low_lemma_uint64_4 r44 r34;
let r12344 = vec_interleave_low_n 2 v34344 v12124 in
vec_interleave_low_n_lemma_uint64_4_2 v34344 v12124;
let fr1234 = (r12340, r12341, r12342, r12343, r12344) in
eq_intro (feval5 fr1234) (create4 (feval5 fr4).[0] (feval5 fr3).[0] (feval5 fr2).[0] (feval5 fr).[0]);
let fr12345 = precomp_r5 #4 fr1234 in
let out = fmul_r5 #4 acc fr1234 fr12345 in
fmul_r5_eval_lemma acc fr1234 fr12345;
fmul_r5_fits_lemma acc fr1234 fr12345;
out
val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3])
let lemma_fmul_r4_normalize51 #m o =
let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let (o0, o1, o2, o3) = ((vec_v o).[0], (vec_v o).[1], (vec_v o).[2], (vec_v o).[3]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[0] == v o0 + v o2);
assert (v (vec_v v10).[1] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[0] == v (vec_v v10).[1]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64)
val lemma_fmul_r4_normalize51_expand:
v2:felem5 4
-> out:felem5 4 ->
Lemma
(requires
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(uint64xN_v v20).[0] == (uint64xN_v o0).[0] + (uint64xN_v o0).[1] + (uint64xN_v o0).[2] + (uint64xN_v o0).[3] /\
(uint64xN_v v21).[0] == (uint64xN_v o1).[0] + (uint64xN_v o1).[1] + (uint64xN_v o1).[2] + (uint64xN_v o1).[3] /\
(uint64xN_v v22).[0] == (uint64xN_v o2).[0] + (uint64xN_v o2).[1] + (uint64xN_v o2).[2] + (uint64xN_v o2).[3] /\
(uint64xN_v v23).[0] == (uint64xN_v o3).[0] + (uint64xN_v o3).[1] + (uint64xN_v o3).[2] + (uint64xN_v o3).[3] /\
(uint64xN_v v24).[0] == (uint64xN_v o4).[0] + (uint64xN_v o4).[1] + (uint64xN_v o4).[2] + (uint64xN_v o4).[3]))
(ensures
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(feval5 v2).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 out).[0] (feval5 out).[1]) (feval5 out).[2]) (feval5 out).[3]))
let lemma_fmul_r4_normalize51_expand v2 out =
let (v20, v21, v22, v23, v24) = as_tup64_i v2 0 in
let (o0, o1, o2, o3, o4) = out in
calc (==) {
as_nat5 (v20, v21, v22, v23, v24) % Vec.prime;
(==) { }
(as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1) + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1))
(as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) Vec.prime }
((as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1)) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.modulo_distributivity (as_nat5 (as_tup64_i out 0)) (as_nat5 (as_tup64_i out 1)) Vec.prime }
(((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2))
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2)) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime) (as_nat5 (as_tup64_i out 2)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r ((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime)
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime;
};
assert ((feval5 v2).[0] ==
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime)
val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | a: Hacl.Spec.Poly1305.Field32xN.felem5 4 -> Prims.Pure (Hacl.Spec.Poly1305.Field32xN.felem5 4) | Prims.Pure | [] | [] | [
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Prims.unit",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_fmul_r4_normalize51_expand",
"FStar.Pervasives.Native.tuple5",
"FStar.Pervasives.Native.Mktuple5",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_fmul_r4_normalize51",
"Lib.IntVector.vec_t",
"Lib.IntTypes.U64",
"Lib.IntVector.vec_add_mod",
"Lib.IntVector.vec_interleave_high",
"Lib.IntVector.vec_interleave_high_n"
] | [] | false | false | false | false | false | let fmul_r4_normalize51 fa =
| let o0, o1, o2, o3, o4 = fa in
let v00 = vec_interleave_high_n 2 o0 o0 in
let v10 = vec_add_mod o0 v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
lemma_fmul_r4_normalize51 #1 o0;
let v01 = vec_interleave_high_n 2 o1 o1 in
let v11 = vec_add_mod o1 v01 in
let v11h = vec_interleave_high v11 v11 in
let v21 = vec_add_mod v11 v11h in
lemma_fmul_r4_normalize51 #2 o1;
let v02 = vec_interleave_high_n 2 o2 o2 in
let v12 = vec_add_mod o2 v02 in
let v12h = vec_interleave_high v12 v12 in
let v22 = vec_add_mod v12 v12h in
lemma_fmul_r4_normalize51 #1 o2;
let v03 = vec_interleave_high_n 2 o3 o3 in
let v13 = vec_add_mod o3 v03 in
let v13h = vec_interleave_high v13 v13 in
let v23 = vec_add_mod v13 v13h in
lemma_fmul_r4_normalize51 #1 o3;
let v04 = vec_interleave_high_n 2 o4 o4 in
let v14 = vec_add_mod o4 v04 in
let v14h = vec_interleave_high v14 v14 in
let v24 = vec_add_mod v14 v14h in
lemma_fmul_r4_normalize51 #2 o4;
let res = (v20, v21, v22, v23, v24) in
lemma_fmul_r4_normalize51_expand res fa;
res | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r2_normalize50 | val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2)) | val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2)) | let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 3,
"end_line": 312,
"start_col": 0,
"start_line": 284
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
acc: Hacl.Spec.Poly1305.Field32xN.felem5 2 ->
r: Hacl.Spec.Poly1305.Field32xN.felem5 2 ->
r2: Hacl.Spec.Poly1305.Field32xN.felem5 2
-> Prims.Pure (Hacl.Spec.Poly1305.Field32xN.felem5 2) | Prims.Pure | [] | [] | [
"Hacl.Spec.Poly1305.Field32xN.felem5",
"FStar.Pervasives.Native.Mktuple3",
"FStar.Pervasives.Native.tuple5",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Prims.unit",
"Prims._assert",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Prims.eq2",
"Lib.Sequence.lseq",
"Hacl.Spec.Poly1305.Vec.pfelem",
"Hacl.Spec.Poly1305.Field32xN.feval5",
"Hacl.Spec.Poly1305.Vec.fmul",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r5_fits_lemma",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.fmul_r5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.fmul_r5",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Lib.Sequence.create2",
"Lib.Sequence.op_String_Access",
"Lib.Sequence.eq_intro",
"Hacl.Spec.Poly1305.Vec.pfmul",
"Lib.IntVector.vec_interleave_low_lemma2",
"Lib.IntTypes.U64",
"Lib.IntVector.vec_t",
"Lib.IntVector.vec_interleave_low"
] | [] | false | false | false | false | false | let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
| let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[ 0 ] == Vec.pfmul ((feval5 fr).[ 0 ]) ((feval5 fr).[ 0 ]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[ 0 ] (feval5 fr).[ 0 ]);
assert (feval5 fr21 == create2 (feval5 fr2).[ 0 ] (feval5 fr).[ 0 ]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.lemma_fmul_r4_normalize51 | val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3]) | val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3]) | let lemma_fmul_r4_normalize51 #m o =
let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let (o0, o1, o2, o3) = ((vec_v o).[0], (vec_v o).[1], (vec_v o).[2], (vec_v o).[3]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[0] == v o0 + v o2);
assert (v (vec_v v10).[1] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[0] == v (vec_v v10).[1]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 70,
"end_line": 505,
"start_col": 0,
"start_line": 491
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2))
let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a
#push-options "--z3rlimit 150"
val fmul_r2_normalize51:
a:felem5 2
-> fa1:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 a (1, 2, 1, 1, 2) /\
felem_fits5 fa1 (1, 2, 1, 1, 2) /\
feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1])
(ensures fun out ->
(feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1] /\
felem_fits5 out (2, 4, 2, 2, 4))
let fmul_r2_normalize51 a fa1 =
let (a0, a1, a2, a3, a4) = a in
let (a10, a11, a12, a13, a14) = fa1 in
let o0 = vec_add_mod a0 a10 in
let o1 = vec_add_mod a1 a11 in
let o2 = vec_add_mod a2 a12 in
let o3 = vec_add_mod a3 a13 in
let o4 = vec_add_mod a4 a14 in
let out = (o0, o1, o2, o3, o4) in
let (a0, a1, a2, a3, a4) = as_tup64_i a 0 in
let (a10, a11, a12, a13, a14) = as_tup64_i fa1 0 in
let (o0, o1, o2, o3, o4) = as_tup64_i out 0 in
FStar.Math.Lemmas.modulo_lemma (v a0 + v a10) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a1 + v a11) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a2 + v a12) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a3 + v a13) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a4 + v a14) (pow2 64);
assert (felem_fits5 out (2, 4, 2, 2, 4));
calc (==) {
((feval5 a).[0] + (feval5 a).[1]) % Vec.prime;
(==) { }
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime + as_nat5 (a10, a11, a12, a13, a14) % Vec.prime) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l
(as_nat5 (a0, a1, a2, a3, a4)) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime;
FStar.Math.Lemmas.lemma_mod_plus_distr_r
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime }
(as_nat5 (a0, a1, a2, a3, a4) + as_nat5 (a10, a11, a12, a13, a14)) % Vec.prime;
(==) { }
(feval5 out).[0];
};
out
#pop-options
val fmul_r2_normalize5_lemma:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures
(let out = fmul_r2_normalize5 acc r r2 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_2 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r2_normalize5 acc r r2)]
let fmul_r2_normalize5_lemma acc r r2 =
let a = fmul_r2_normalize50 acc r r2 in
let (a0, a1, a2, a3, a4) = a in
let a10 = vec_interleave_high a0 a0 in
vec_interleave_high_lemma2 a0 a0;
let a11 = vec_interleave_high a1 a1 in
vec_interleave_high_lemma2 a1 a1;
let a12 = vec_interleave_high a2 a2 in
vec_interleave_high_lemma2 a2 a2;
let a13 = vec_interleave_high a3 a3 in
vec_interleave_high_lemma2 a3 a3;
let a14 = vec_interleave_high a4 a4 in
vec_interleave_high_lemma2 a4 a4;
let fa1 = (a10, a11, a12, a13, a14) in
eq_intro (feval5 fa1) (create2 (feval5 a).[1] (feval5 a).[1]);
assert (feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1]);
assert (felem_fits5 fa1 (1, 2, 1, 1, 2));
let out = fmul_r2_normalize51 a fa1 in
assert ((feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1]);
let res = carry_full_felem5 out in
carry_full_felem5_lemma out
val fmul_r4_normalize50:
acc:felem5 4
-> r:felem5 4
-> r2:felem5 4
-> r3:felem5 4
-> r4:felem5 4 ->
Pure (felem5 4)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
felem_fits5 r3 (2, 2, 2, 2, 2) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.fmul (feval5 r) (feval5 r) /\
feval5 r3 == Vec.fmul (feval5 r2) (feval5 r) /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures fun out ->
let fr4321 = create4 (feval5 r4).[0] (feval5 r3).[0] (feval5 r2).[0] (feval5 r).[0] in
feval5 out == Vec.fmul (feval5 acc) fr4321 /\
felem_fits5 out (1, 2, 1, 1, 2))
let fmul_r4_normalize50 acc fr fr2 fr3 fr4 =
let (r10, r11, r12, r13, r14) = fr in
let (r20, r21, r22, r23, r24) = fr2 in
let (r30, r31, r32, r33, r34) = fr3 in
let (r40, r41, r42, r43, r44) = fr4 in
let (a0, a1, a2, a3, a4) = acc in
let v12120 = vec_interleave_low r20 r10 in
vec_interleave_low_lemma_uint64_4 r20 r10;
let v34340 = vec_interleave_low r40 r30 in
vec_interleave_low_lemma_uint64_4 r40 r30;
let r12340 = vec_interleave_low_n 2 v34340 v12120 in
vec_interleave_low_n_lemma_uint64_4_2 v34340 v12120;
let v12121 = vec_interleave_low r21 r11 in
vec_interleave_low_lemma_uint64_4 r21 r11;
let v34341 = vec_interleave_low r41 r31 in
vec_interleave_low_lemma_uint64_4 r41 r31;
let r12341 = vec_interleave_low_n 2 v34341 v12121 in
vec_interleave_low_n_lemma_uint64_4_2 v34341 v12121;
let v12122 = vec_interleave_low r22 r12 in
vec_interleave_low_lemma_uint64_4 r22 r12;
let v34342 = vec_interleave_low r42 r32 in
vec_interleave_low_lemma_uint64_4 r42 r32;
let r12342 = vec_interleave_low_n 2 v34342 v12122 in
vec_interleave_low_n_lemma_uint64_4_2 v34342 v12122;
let v12123 = vec_interleave_low r23 r13 in
vec_interleave_low_lemma_uint64_4 r23 r13;
let v34343 = vec_interleave_low r43 r33 in
vec_interleave_low_lemma_uint64_4 r43 r33;
let r12343 = vec_interleave_low_n 2 v34343 v12123 in
vec_interleave_low_n_lemma_uint64_4_2 v34343 v12123;
let v12124 = vec_interleave_low r24 r14 in
vec_interleave_low_lemma_uint64_4 r24 r14;
let v34344 = vec_interleave_low r44 r34 in
vec_interleave_low_lemma_uint64_4 r44 r34;
let r12344 = vec_interleave_low_n 2 v34344 v12124 in
vec_interleave_low_n_lemma_uint64_4_2 v34344 v12124;
let fr1234 = (r12340, r12341, r12342, r12343, r12344) in
eq_intro (feval5 fr1234) (create4 (feval5 fr4).[0] (feval5 fr3).[0] (feval5 fr2).[0] (feval5 fr).[0]);
let fr12345 = precomp_r5 #4 fr1234 in
let out = fmul_r5 #4 acc fr1234 fr12345 in
fmul_r5_eval_lemma acc fr1234 fr12345;
fmul_r5_fits_lemma acc fr1234 fr12345;
out
val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | o: Hacl.Spec.Poly1305.Field32xN.uint64xN 4 {Hacl.Spec.Poly1305.Field32xN.felem_fits1 o m}
-> FStar.Pervasives.Lemma
(ensures
(let v00 = Lib.IntVector.vec_interleave_high_n 2 o o in
let v10 = Lib.IntVector.vec_add_mod o v00 in
let v10h = Lib.IntVector.vec_interleave_high v10 v10 in
let v20 = Lib.IntVector.vec_add_mod v10 v10h in
Hacl.Spec.Poly1305.Field32xN.felem_fits1 v20 (4 * m) /\
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v v20).[ 0 ] ==
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v o).[ 0 ] +
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v o).[ 1 ] +
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v o).[ 2 ] +
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v o).[ 3 ])) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.scale32",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Hacl.Spec.Poly1305.Field32xN.felem_fits1",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.Math.Lemmas.modulo_lemma",
"Prims.op_Addition",
"Lib.IntTypes.v",
"Prims.pow2",
"Lib.IntVector.vec_t",
"Lib.IntVector.vec_add_mod",
"Prims.unit",
"Prims._assert",
"Prims.eq2",
"Lib.IntTypes.range_t",
"Lib.Sequence.op_String_Access",
"Lib.IntTypes.uint_t",
"Lib.IntVector.vec_v",
"Lib.IntVector.vec_interleave_high_lemma_uint64_4",
"Lib.IntVector.vec_interleave_high",
"Prims.int",
"Lib.Sequence.lseq",
"Lib.Sequence.create4",
"FStar.Pervasives.Native.tuple4",
"FStar.Pervasives.Native.Mktuple4",
"Lib.IntVector.vec_interleave_high_n_lemma_uint64_4_2",
"Lib.IntVector.vec_interleave_high_n"
] | [] | false | false | true | false | false | let lemma_fmul_r4_normalize51 #m o =
| let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let o0, o1, o2, o3 = ((vec_v o).[ 0 ], (vec_v o).[ 1 ], (vec_v o).[ 2 ], (vec_v o).[ 3 ]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[ 0 ] == v o0 + v o2);
assert (v (vec_v v10).[ 1 ] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[ 0 ] == v (vec_v v10).[ 1 ]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.load_felem5_4_compact_lemma_i | val load_felem5_4_compact_lemma_i: lo:uint64xN 4 -> hi:uint64xN 4 -> i:nat{i < 4} ->
Lemma
(let f = as_tup64_i (load_felem5_4_compact lo hi) i in
tup64_fits5 f (1, 1, 1, 1, 1) /\
as_nat5 f < pow2 128 /\
as_nat5 f % Vec.prime == (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) | val load_felem5_4_compact_lemma_i: lo:uint64xN 4 -> hi:uint64xN 4 -> i:nat{i < 4} ->
Lemma
(let f = as_tup64_i (load_felem5_4_compact lo hi) i in
tup64_fits5 f (1, 1, 1, 1, 1) /\
as_nat5 f < pow2 128 /\
as_nat5 f % Vec.prime == (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) | let load_felem5_4_compact_lemma_i lo hi i =
assert (as_tup64_i (load_felem5_4_compact lo hi) i == load_tup64_4_compact (vec_v lo).[i] (vec_v hi).[i]);
load_tup64_4_compact_lemma (vec_v lo).[i] (vec_v hi).[i] | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 58,
"end_line": 720,
"start_col": 0,
"start_line": 718
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2))
let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a
#push-options "--z3rlimit 150"
val fmul_r2_normalize51:
a:felem5 2
-> fa1:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 a (1, 2, 1, 1, 2) /\
felem_fits5 fa1 (1, 2, 1, 1, 2) /\
feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1])
(ensures fun out ->
(feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1] /\
felem_fits5 out (2, 4, 2, 2, 4))
let fmul_r2_normalize51 a fa1 =
let (a0, a1, a2, a3, a4) = a in
let (a10, a11, a12, a13, a14) = fa1 in
let o0 = vec_add_mod a0 a10 in
let o1 = vec_add_mod a1 a11 in
let o2 = vec_add_mod a2 a12 in
let o3 = vec_add_mod a3 a13 in
let o4 = vec_add_mod a4 a14 in
let out = (o0, o1, o2, o3, o4) in
let (a0, a1, a2, a3, a4) = as_tup64_i a 0 in
let (a10, a11, a12, a13, a14) = as_tup64_i fa1 0 in
let (o0, o1, o2, o3, o4) = as_tup64_i out 0 in
FStar.Math.Lemmas.modulo_lemma (v a0 + v a10) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a1 + v a11) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a2 + v a12) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a3 + v a13) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a4 + v a14) (pow2 64);
assert (felem_fits5 out (2, 4, 2, 2, 4));
calc (==) {
((feval5 a).[0] + (feval5 a).[1]) % Vec.prime;
(==) { }
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime + as_nat5 (a10, a11, a12, a13, a14) % Vec.prime) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l
(as_nat5 (a0, a1, a2, a3, a4)) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime;
FStar.Math.Lemmas.lemma_mod_plus_distr_r
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime }
(as_nat5 (a0, a1, a2, a3, a4) + as_nat5 (a10, a11, a12, a13, a14)) % Vec.prime;
(==) { }
(feval5 out).[0];
};
out
#pop-options
val fmul_r2_normalize5_lemma:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures
(let out = fmul_r2_normalize5 acc r r2 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_2 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r2_normalize5 acc r r2)]
let fmul_r2_normalize5_lemma acc r r2 =
let a = fmul_r2_normalize50 acc r r2 in
let (a0, a1, a2, a3, a4) = a in
let a10 = vec_interleave_high a0 a0 in
vec_interleave_high_lemma2 a0 a0;
let a11 = vec_interleave_high a1 a1 in
vec_interleave_high_lemma2 a1 a1;
let a12 = vec_interleave_high a2 a2 in
vec_interleave_high_lemma2 a2 a2;
let a13 = vec_interleave_high a3 a3 in
vec_interleave_high_lemma2 a3 a3;
let a14 = vec_interleave_high a4 a4 in
vec_interleave_high_lemma2 a4 a4;
let fa1 = (a10, a11, a12, a13, a14) in
eq_intro (feval5 fa1) (create2 (feval5 a).[1] (feval5 a).[1]);
assert (feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1]);
assert (felem_fits5 fa1 (1, 2, 1, 1, 2));
let out = fmul_r2_normalize51 a fa1 in
assert ((feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1]);
let res = carry_full_felem5 out in
carry_full_felem5_lemma out
val fmul_r4_normalize50:
acc:felem5 4
-> r:felem5 4
-> r2:felem5 4
-> r3:felem5 4
-> r4:felem5 4 ->
Pure (felem5 4)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
felem_fits5 r3 (2, 2, 2, 2, 2) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.fmul (feval5 r) (feval5 r) /\
feval5 r3 == Vec.fmul (feval5 r2) (feval5 r) /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures fun out ->
let fr4321 = create4 (feval5 r4).[0] (feval5 r3).[0] (feval5 r2).[0] (feval5 r).[0] in
feval5 out == Vec.fmul (feval5 acc) fr4321 /\
felem_fits5 out (1, 2, 1, 1, 2))
let fmul_r4_normalize50 acc fr fr2 fr3 fr4 =
let (r10, r11, r12, r13, r14) = fr in
let (r20, r21, r22, r23, r24) = fr2 in
let (r30, r31, r32, r33, r34) = fr3 in
let (r40, r41, r42, r43, r44) = fr4 in
let (a0, a1, a2, a3, a4) = acc in
let v12120 = vec_interleave_low r20 r10 in
vec_interleave_low_lemma_uint64_4 r20 r10;
let v34340 = vec_interleave_low r40 r30 in
vec_interleave_low_lemma_uint64_4 r40 r30;
let r12340 = vec_interleave_low_n 2 v34340 v12120 in
vec_interleave_low_n_lemma_uint64_4_2 v34340 v12120;
let v12121 = vec_interleave_low r21 r11 in
vec_interleave_low_lemma_uint64_4 r21 r11;
let v34341 = vec_interleave_low r41 r31 in
vec_interleave_low_lemma_uint64_4 r41 r31;
let r12341 = vec_interleave_low_n 2 v34341 v12121 in
vec_interleave_low_n_lemma_uint64_4_2 v34341 v12121;
let v12122 = vec_interleave_low r22 r12 in
vec_interleave_low_lemma_uint64_4 r22 r12;
let v34342 = vec_interleave_low r42 r32 in
vec_interleave_low_lemma_uint64_4 r42 r32;
let r12342 = vec_interleave_low_n 2 v34342 v12122 in
vec_interleave_low_n_lemma_uint64_4_2 v34342 v12122;
let v12123 = vec_interleave_low r23 r13 in
vec_interleave_low_lemma_uint64_4 r23 r13;
let v34343 = vec_interleave_low r43 r33 in
vec_interleave_low_lemma_uint64_4 r43 r33;
let r12343 = vec_interleave_low_n 2 v34343 v12123 in
vec_interleave_low_n_lemma_uint64_4_2 v34343 v12123;
let v12124 = vec_interleave_low r24 r14 in
vec_interleave_low_lemma_uint64_4 r24 r14;
let v34344 = vec_interleave_low r44 r34 in
vec_interleave_low_lemma_uint64_4 r44 r34;
let r12344 = vec_interleave_low_n 2 v34344 v12124 in
vec_interleave_low_n_lemma_uint64_4_2 v34344 v12124;
let fr1234 = (r12340, r12341, r12342, r12343, r12344) in
eq_intro (feval5 fr1234) (create4 (feval5 fr4).[0] (feval5 fr3).[0] (feval5 fr2).[0] (feval5 fr).[0]);
let fr12345 = precomp_r5 #4 fr1234 in
let out = fmul_r5 #4 acc fr1234 fr12345 in
fmul_r5_eval_lemma acc fr1234 fr12345;
fmul_r5_fits_lemma acc fr1234 fr12345;
out
val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3])
let lemma_fmul_r4_normalize51 #m o =
let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let (o0, o1, o2, o3) = ((vec_v o).[0], (vec_v o).[1], (vec_v o).[2], (vec_v o).[3]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[0] == v o0 + v o2);
assert (v (vec_v v10).[1] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[0] == v (vec_v v10).[1]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64)
val lemma_fmul_r4_normalize51_expand:
v2:felem5 4
-> out:felem5 4 ->
Lemma
(requires
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(uint64xN_v v20).[0] == (uint64xN_v o0).[0] + (uint64xN_v o0).[1] + (uint64xN_v o0).[2] + (uint64xN_v o0).[3] /\
(uint64xN_v v21).[0] == (uint64xN_v o1).[0] + (uint64xN_v o1).[1] + (uint64xN_v o1).[2] + (uint64xN_v o1).[3] /\
(uint64xN_v v22).[0] == (uint64xN_v o2).[0] + (uint64xN_v o2).[1] + (uint64xN_v o2).[2] + (uint64xN_v o2).[3] /\
(uint64xN_v v23).[0] == (uint64xN_v o3).[0] + (uint64xN_v o3).[1] + (uint64xN_v o3).[2] + (uint64xN_v o3).[3] /\
(uint64xN_v v24).[0] == (uint64xN_v o4).[0] + (uint64xN_v o4).[1] + (uint64xN_v o4).[2] + (uint64xN_v o4).[3]))
(ensures
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(feval5 v2).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 out).[0] (feval5 out).[1]) (feval5 out).[2]) (feval5 out).[3]))
let lemma_fmul_r4_normalize51_expand v2 out =
let (v20, v21, v22, v23, v24) = as_tup64_i v2 0 in
let (o0, o1, o2, o3, o4) = out in
calc (==) {
as_nat5 (v20, v21, v22, v23, v24) % Vec.prime;
(==) { }
(as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1) + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1))
(as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) Vec.prime }
((as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1)) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.modulo_distributivity (as_nat5 (as_tup64_i out 0)) (as_nat5 (as_tup64_i out 1)) Vec.prime }
(((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2))
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2)) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime) (as_nat5 (as_tup64_i out 2)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r ((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime)
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime;
};
assert ((feval5 v2).[0] ==
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime)
val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3])
let fmul_r4_normalize51 fa =
let (o0, o1, o2, o3, o4) = fa in
let v00 = vec_interleave_high_n 2 o0 o0 in
let v10 = vec_add_mod o0 v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
lemma_fmul_r4_normalize51 #1 o0;
let v01 = vec_interleave_high_n 2 o1 o1 in
let v11 = vec_add_mod o1 v01 in
let v11h = vec_interleave_high v11 v11 in
let v21 = vec_add_mod v11 v11h in
lemma_fmul_r4_normalize51 #2 o1;
let v02 = vec_interleave_high_n 2 o2 o2 in
let v12 = vec_add_mod o2 v02 in
let v12h = vec_interleave_high v12 v12 in
let v22 = vec_add_mod v12 v12h in
lemma_fmul_r4_normalize51 #1 o2;
let v03 = vec_interleave_high_n 2 o3 o3 in
let v13 = vec_add_mod o3 v03 in
let v13h = vec_interleave_high v13 v13 in
let v23 = vec_add_mod v13 v13h in
lemma_fmul_r4_normalize51 #1 o3;
let v04 = vec_interleave_high_n 2 o4 o4 in
let v14 = vec_add_mod o4 v04 in
let v14h = vec_interleave_high v14 v14 in
let v24 = vec_add_mod v14 v14h in
lemma_fmul_r4_normalize51 #2 o4;
let res = (v20, v21, v22, v23, v24) in
lemma_fmul_r4_normalize51_expand res fa;
res
val fmul_r4_normalize5_lemma:
acc:felem5 4
-> r:felem5 4
-> r_5:felem5 4
-> r4:felem5 4 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
r_5 == precomp_r5 r /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures
(let out = fmul_r4_normalize5 acc r r_5 r4 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_4 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r4_normalize5 acc r r_5 r4)]
#restart-solver
#push-options "--z3rlimit 500"
let fmul_r4_normalize5_lemma acc fr fr_5 fr4 =
let fr2 = fmul_r5 #4 fr fr fr_5 in
let fr3 = fmul_r5 #4 fr2 fr fr_5 in
let out = fmul_r4_normalize50 acc fr fr2 fr3 fr4 in
let v2 = fmul_r4_normalize51 out in
let res = carry_full_felem5 v2 in
carry_full_felem5_lemma v2
#pop-options
val load_felem5_lemma:
#w:lanes
-> lo:uint64xN w
-> hi:uint64xN w ->
Lemma
(let f = load_felem5 #w lo hi in
felem_fits5 f (1, 1, 1, 1, 1) /\
felem_less5 f (pow2 128) /\
feval5 f == createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]))
let load_felem5_lemma #w lo hi =
let f = load_felem5 #w lo hi in
assert_norm (pow2 64 * pow2 64 = pow2 128);
assert_norm (pow2 128 < Vec.prime);
let res = createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) in
match w with
| 1 ->
load_felem5_lemma_i #w lo hi 0;
eq_intro (feval5 f) res
| 2 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
eq_intro (feval5 f) res
| 4 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
load_felem5_lemma_i #w lo hi 2;
load_felem5_lemma_i #w lo hi 3;
eq_intro (feval5 f) res
val load_felem5_4_interleave: lo:uint64xN 4 -> hi:uint64xN 4 -> Lemma
(let m0 = vec_interleave_low_n 2 lo hi in
let m1 = vec_interleave_high_n 2 lo hi in
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
let m4 = vec_interleave_high m0 m1 in
let t0 = vec_interleave_low m0 m1 in
let t3 = vec_interleave_low m2 m3 in
vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3] /\
vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2] /\
t3 == vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
let load_felem5_4_interleave lo hi =
let m0 = vec_interleave_low_n 2 lo hi in
vec_interleave_low_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m0 == create4 (vec_v lo).[0] (vec_v lo).[1] (vec_v hi).[0] (vec_v hi).[1]);
let m1 = vec_interleave_high_n 2 lo hi in
vec_interleave_high_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m1 == create4 (vec_v lo).[2] (vec_v lo).[3] (vec_v hi).[2] (vec_v hi).[3]);
let m4 = vec_interleave_high m0 m1 in
vec_interleave_high_lemma_uint64_4 m0 m1;
//assert (vec_v m4 == create4 (vec_v m0).[1] (vec_v m1).[1] (vec_v m0).[3] (vec_v m1).[3]);
assert (vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3]);
let t0 = vec_interleave_low m0 m1 in
vec_interleave_low_lemma_uint64_4 m0 m1;
//assert (vec_v t0 == create4 (vec_v m0).[0] (vec_v m1).[0] (vec_v m0).[2] (vec_v m1).[2]);
assert (vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2]);
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
vec_shift_right_uint128_small2 m0 48ul;
assert ((vec_v m2).[0] == (((vec_v lo).[0] >>. 48ul) |. ((vec_v lo).[1] <<. 16ul)));
assert ((vec_v m2).[2] == (((vec_v hi).[0] >>. 48ul) |. ((vec_v hi).[1] <<. 16ul)));
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
vec_shift_right_uint128_small2 m1 48ul;
assert ((vec_v m3).[0] == (((vec_v lo).[2] >>. 48ul) |. ((vec_v lo).[3] <<. 16ul)));
assert ((vec_v m3).[2] == (((vec_v hi).[2] >>. 48ul) |. ((vec_v hi).[3] <<. 16ul)));
let t3 = vec_interleave_low m2 m3 in
vec_interleave_low_lemma_uint64_4 m2 m3;
eq_intro (vec_v t3) (vec_v (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul)));
vecv_extensionality t3 (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
noextract
val load_felem5_4_compact: lo:uint64xN 4 -> hi:uint64xN 4 -> felem5 4
let load_felem5_4_compact lo hi =
let mask26 = mask26 4 in
let t3 = vec_or (vec_shift_right lo 48ul) (vec_shift_left hi 16ul) in
let o0 = vec_and lo mask26 in
let o1 = vec_and (vec_shift_right lo 26ul) mask26 in
let o2 = vec_and (vec_shift_right t3 4ul) mask26 in
let o3 = vec_and (vec_shift_right t3 30ul) mask26 in
let o4 = vec_shift_right hi 40ul in
(o0, o1, o2, o3, o4)
val load_felem5_4_compact_lemma_i: lo:uint64xN 4 -> hi:uint64xN 4 -> i:nat{i < 4} ->
Lemma
(let f = as_tup64_i (load_felem5_4_compact lo hi) i in
tup64_fits5 f (1, 1, 1, 1, 1) /\
as_nat5 f < pow2 128 /\
as_nat5 f % Vec.prime == (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
lo: Hacl.Spec.Poly1305.Field32xN.uint64xN 4 ->
hi: Hacl.Spec.Poly1305.Field32xN.uint64xN 4 ->
i: Prims.nat{i < 4}
-> FStar.Pervasives.Lemma
(ensures
(let f =
Hacl.Spec.Poly1305.Field32xN.as_tup64_i (Hacl.Spec.Poly1305.Field32xN.Lemmas.load_felem5_4_compact
lo
hi)
i
in
Hacl.Spec.Poly1305.Field32xN.tup64_fits5 f (1, 1, 1, 1, 1) /\
Hacl.Spec.Poly1305.Field32xN.as_nat5 f < Prims.pow2 128 /\
Hacl.Spec.Poly1305.Field32xN.as_nat5 f % Hacl.Spec.Poly1305.Vec.prime ==
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v hi).[ i ] * Prims.pow2 64 +
(Hacl.Spec.Poly1305.Field32xN.uint64xN_v lo).[ i ])) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Prims.nat",
"Prims.b2t",
"Prims.op_LessThan",
"Hacl.Poly1305.Field32xN.Lemmas2.load_tup64_4_compact_lemma",
"Lib.Sequence.op_String_Access",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"Lib.IntVector.vec_v",
"Prims.unit",
"Prims._assert",
"Prims.eq2",
"Hacl.Spec.Poly1305.Field32xN.tup64_5",
"Hacl.Spec.Poly1305.Field32xN.as_tup64_i",
"Hacl.Spec.Poly1305.Field32xN.Lemmas.load_felem5_4_compact",
"Hacl.Poly1305.Field32xN.Lemmas2.load_tup64_4_compact"
] | [] | true | false | true | false | false | let load_felem5_4_compact_lemma_i lo hi i =
| assert (as_tup64_i (load_felem5_4_compact lo hi) i ==
load_tup64_4_compact (vec_v lo).[ i ] (vec_v hi).[ i ]);
load_tup64_4_compact_lemma (vec_v lo).[ i ] (vec_v hi).[ i ] | false |
Steel.Memory.fst | Steel.Memory.lock_store | val lock_store:Type u#(a + 1) | val lock_store:Type u#(a + 1) | let lock_store : Type u#(a+1) = list (lock_state u#a) | {
"file_name": "lib/steel/Steel.Memory.fst",
"git_rev": "f984200f79bdc452374ae994a5ca837496476c41",
"git_url": "https://github.com/FStarLang/steel.git",
"project_name": "steel"
} | {
"end_col": 53,
"end_line": 26,
"start_col": 0,
"start_line": 26
} | (*
Copyright 2020 Microsoft Research
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*)
module Steel.Memory
module F = FStar.FunctionalExtensionality
open FStar.FunctionalExtensionality
open FStar.PCM
module H = Steel.Heap
noeq
type lock_state : Type u#(a + 1) =
| Invariant : inv:H.slprop u#a -> lock_state | {
"checked_file": "/",
"dependencies": [
"Steel.Preorder.fst.checked",
"Steel.Heap.fsti.checked",
"prims.fst.checked",
"FStar.Witnessed.Core.fsti.checked",
"FStar.Set.fsti.checked",
"FStar.Preorder.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.PCM.fst.checked",
"FStar.NMSTTotal.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.IndefiniteDescription.fsti.checked",
"FStar.Ghost.fsti.checked",
"FStar.FunctionalExtensionality.fsti.checked",
"FStar.Classical.Sugar.fsti.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Steel.Memory.fst"
} | [
{
"abbrev": true,
"full_module": "Steel.Heap",
"short_module": "H"
},
{
"abbrev": false,
"full_module": "FStar.PCM",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.FunctionalExtensionality",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.FunctionalExtensionality",
"short_module": "F"
},
{
"abbrev": false,
"full_module": "FStar.PCM",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Ghost",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Type | Prims.Tot | [
"total"
] | [] | [
"Prims.list",
"Steel.Memory.lock_state"
] | [] | false | false | false | true | true | let lock_store:Type u#(a + 1) =
| list (lock_state u#a) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.load_felem5_4_compact | val load_felem5_4_compact: lo:uint64xN 4 -> hi:uint64xN 4 -> felem5 4 | val load_felem5_4_compact: lo:uint64xN 4 -> hi:uint64xN 4 -> felem5 4 | let load_felem5_4_compact lo hi =
let mask26 = mask26 4 in
let t3 = vec_or (vec_shift_right lo 48ul) (vec_shift_left hi 16ul) in
let o0 = vec_and lo mask26 in
let o1 = vec_and (vec_shift_right lo 26ul) mask26 in
let o2 = vec_and (vec_shift_right t3 4ul) mask26 in
let o3 = vec_and (vec_shift_right t3 30ul) mask26 in
let o4 = vec_shift_right hi 40ul in
(o0, o1, o2, o3, o4) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 22,
"end_line": 709,
"start_col": 0,
"start_line": 701
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i])
let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i)
val mul_felem5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (mul_felem5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_eval_lemma #w f1 r r5 =
let tmp = map2 (Vec.pfmul) (feval5 f1) (feval5 r) in
FStar.Classical.forall_intro (mul_felem5_eval_lemma_i #w f1 r r5);
eq_intro (feval5 (mul_felem5 #w f1 r r5)) tmp
val fmul_r5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_fits5 (fmul_r5 #w f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_fits_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_fits_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fmul_r5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fmul_r5 #w f1 r r5) == map2 (Vec.pfmul) (feval5 f1) (feval5 r))
[SMTPat (fmul_r5 #w f1 r r5)]
let fmul_r5_eval_lemma #w f1 r r5 =
let tmp = mul_felem5 f1 r r5 in
mul_felem5_eval_lemma #w f1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val fadd_mul_r5_fits_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5)} ->
Lemma (felem_fits5 (fadd_mul_r5 acc f1 r r5) (1, 2, 1, 1, 2))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_fits_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_fits_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_fits_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_fits_lemma #w tmp
val fadd_mul_r5_eval_lemma:
#w:lanes
-> acc:felem5 w{felem_fits5 acc (2, 2, 2, 2, 2)}
-> f1:felem5 w{felem_fits5 f1 (1, 1, 1, 1, 1)}
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)}
-> r5:felem5 w{felem_fits5 r5 (5, 5, 5, 5, 5) /\ r5 == precomp_r5 r} ->
Lemma (feval5 (fadd_mul_r5 acc f1 r r5) ==
map2 (Vec.pfmul) (map2 (Vec.pfadd) (feval5 acc) (feval5 f1)) (feval5 r))
[SMTPat (fadd_mul_r5 acc f1 r r5)]
let fadd_mul_r5_eval_lemma #w acc f1 r r5 =
let acc1 = fadd5 acc f1 in
fadd5_eval_lemma #w acc f1;
let tmp = mul_felem5 acc1 r r5 in
mul_felem5_eval_lemma #w acc1 r r5;
let res = carry_wide_felem5 tmp in
carry_wide_felem5_eval_lemma #w tmp
val reduce_felem5_eval_lemma:
#w:lanes
-> f:felem5 w{felem_fits5 f (2, 2, 2, 2, 2)} ->
Lemma
(felem_fits5 (reduce_felem5 f) (1, 1, 1, 1, 1) /\
(feval5 f).[0] == (fas_nat5 (reduce_felem5 f)).[0])
[SMTPat (reduce_felem5 f)]
let reduce_felem5_eval_lemma #w f =
carry_full_felem5_eval_lemma f;
carry_full_felem5_fits_lemma f;
let f = carry_full_felem5 f in
carry_reduce_felem5_lemma #w f;
subtract_p5_felem5_lemma #w (carry_full_felem5 f)
val fmul_r2_normalize50:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures fun a ->
let fr21 = create2 (feval5 r2).[0] (feval5 r).[0] in
feval5 a == Vec.fmul (feval5 acc) fr21 /\
felem_fits5 a (1, 2, 1, 1, 2))
let fmul_r2_normalize50 (a0, a1, a2, a3, a4) (r0, r1, r2, r3, r4) (r20, r21, r22, r23, r24) =
let r210 = vec_interleave_low r20 r0 in
vec_interleave_low_lemma2 r20 r0;
let r211 = vec_interleave_low r21 r1 in
vec_interleave_low_lemma2 r21 r1;
let r212 = vec_interleave_low r22 r2 in
vec_interleave_low_lemma2 r22 r2;
let r213 = vec_interleave_low r23 r3 in
vec_interleave_low_lemma2 r23 r3;
let r214 = vec_interleave_low r24 r4 in
vec_interleave_low_lemma2 r24 r4;
let acc = (a0, a1, a2, a3, a4) in
let fr = (r0, r1, r2, r3, r4) in
let fr2 = (r20, r21, r22, r23, r24) in
assert ((feval5 fr2).[0] == Vec.pfmul ((feval5 fr).[0]) ((feval5 fr).[0]));
let fr21 = (r210, r211, r212, r213, r214) in
eq_intro (feval5 fr21) (create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (feval5 fr21 == create2 (feval5 fr2).[0] (feval5 fr).[0]);
assert (felem_fits5 fr21 (2, 2, 2, 2, 2));
let fr215 = precomp_r5 #2 fr21 in
let a = fmul_r5 #2 acc fr21 fr215 in
fmul_r5_eval_lemma acc fr21 fr215;
fmul_r5_fits_lemma acc fr21 fr215;
assert (feval5 a == Vec.fmul (feval5 acc) (feval5 fr21));
assert (felem_fits5 a (1, 2, 1, 1, 2));
a
#push-options "--z3rlimit 150"
val fmul_r2_normalize51:
a:felem5 2
-> fa1:felem5 2 ->
Pure (felem5 2)
(requires
felem_fits5 a (1, 2, 1, 1, 2) /\
felem_fits5 fa1 (1, 2, 1, 1, 2) /\
feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1])
(ensures fun out ->
(feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1] /\
felem_fits5 out (2, 4, 2, 2, 4))
let fmul_r2_normalize51 a fa1 =
let (a0, a1, a2, a3, a4) = a in
let (a10, a11, a12, a13, a14) = fa1 in
let o0 = vec_add_mod a0 a10 in
let o1 = vec_add_mod a1 a11 in
let o2 = vec_add_mod a2 a12 in
let o3 = vec_add_mod a3 a13 in
let o4 = vec_add_mod a4 a14 in
let out = (o0, o1, o2, o3, o4) in
let (a0, a1, a2, a3, a4) = as_tup64_i a 0 in
let (a10, a11, a12, a13, a14) = as_tup64_i fa1 0 in
let (o0, o1, o2, o3, o4) = as_tup64_i out 0 in
FStar.Math.Lemmas.modulo_lemma (v a0 + v a10) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a1 + v a11) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a2 + v a12) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a3 + v a13) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v a4 + v a14) (pow2 64);
assert (felem_fits5 out (2, 4, 2, 2, 4));
calc (==) {
((feval5 a).[0] + (feval5 a).[1]) % Vec.prime;
(==) { }
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime + as_nat5 (a10, a11, a12, a13, a14) % Vec.prime) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l
(as_nat5 (a0, a1, a2, a3, a4)) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime;
FStar.Math.Lemmas.lemma_mod_plus_distr_r
(as_nat5 (a0, a1, a2, a3, a4) % Vec.prime) (as_nat5 (a10, a11, a12, a13, a14)) Vec.prime }
(as_nat5 (a0, a1, a2, a3, a4) + as_nat5 (a10, a11, a12, a13, a14)) % Vec.prime;
(==) { }
(feval5 out).[0];
};
out
#pop-options
val fmul_r2_normalize5_lemma:
acc:felem5 2
-> r:felem5 2
-> r2:felem5 2 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.compute_r2 (feval5 r).[0])
(ensures
(let out = fmul_r2_normalize5 acc r r2 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_2 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r2_normalize5 acc r r2)]
let fmul_r2_normalize5_lemma acc r r2 =
let a = fmul_r2_normalize50 acc r r2 in
let (a0, a1, a2, a3, a4) = a in
let a10 = vec_interleave_high a0 a0 in
vec_interleave_high_lemma2 a0 a0;
let a11 = vec_interleave_high a1 a1 in
vec_interleave_high_lemma2 a1 a1;
let a12 = vec_interleave_high a2 a2 in
vec_interleave_high_lemma2 a2 a2;
let a13 = vec_interleave_high a3 a3 in
vec_interleave_high_lemma2 a3 a3;
let a14 = vec_interleave_high a4 a4 in
vec_interleave_high_lemma2 a4 a4;
let fa1 = (a10, a11, a12, a13, a14) in
eq_intro (feval5 fa1) (create2 (feval5 a).[1] (feval5 a).[1]);
assert (feval5 fa1 == create2 (feval5 a).[1] (feval5 a).[1]);
assert (felem_fits5 fa1 (1, 2, 1, 1, 2));
let out = fmul_r2_normalize51 a fa1 in
assert ((feval5 out).[0] == Vec.pfadd (feval5 a).[0] (feval5 a).[1]);
let res = carry_full_felem5 out in
carry_full_felem5_lemma out
val fmul_r4_normalize50:
acc:felem5 4
-> r:felem5 4
-> r2:felem5 4
-> r3:felem5 4
-> r4:felem5 4 ->
Pure (felem5 4)
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r2 (2, 2, 2, 2, 2) /\
felem_fits5 r3 (2, 2, 2, 2, 2) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
feval5 r2 == Vec.fmul (feval5 r) (feval5 r) /\
feval5 r3 == Vec.fmul (feval5 r2) (feval5 r) /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures fun out ->
let fr4321 = create4 (feval5 r4).[0] (feval5 r3).[0] (feval5 r2).[0] (feval5 r).[0] in
feval5 out == Vec.fmul (feval5 acc) fr4321 /\
felem_fits5 out (1, 2, 1, 1, 2))
let fmul_r4_normalize50 acc fr fr2 fr3 fr4 =
let (r10, r11, r12, r13, r14) = fr in
let (r20, r21, r22, r23, r24) = fr2 in
let (r30, r31, r32, r33, r34) = fr3 in
let (r40, r41, r42, r43, r44) = fr4 in
let (a0, a1, a2, a3, a4) = acc in
let v12120 = vec_interleave_low r20 r10 in
vec_interleave_low_lemma_uint64_4 r20 r10;
let v34340 = vec_interleave_low r40 r30 in
vec_interleave_low_lemma_uint64_4 r40 r30;
let r12340 = vec_interleave_low_n 2 v34340 v12120 in
vec_interleave_low_n_lemma_uint64_4_2 v34340 v12120;
let v12121 = vec_interleave_low r21 r11 in
vec_interleave_low_lemma_uint64_4 r21 r11;
let v34341 = vec_interleave_low r41 r31 in
vec_interleave_low_lemma_uint64_4 r41 r31;
let r12341 = vec_interleave_low_n 2 v34341 v12121 in
vec_interleave_low_n_lemma_uint64_4_2 v34341 v12121;
let v12122 = vec_interleave_low r22 r12 in
vec_interleave_low_lemma_uint64_4 r22 r12;
let v34342 = vec_interleave_low r42 r32 in
vec_interleave_low_lemma_uint64_4 r42 r32;
let r12342 = vec_interleave_low_n 2 v34342 v12122 in
vec_interleave_low_n_lemma_uint64_4_2 v34342 v12122;
let v12123 = vec_interleave_low r23 r13 in
vec_interleave_low_lemma_uint64_4 r23 r13;
let v34343 = vec_interleave_low r43 r33 in
vec_interleave_low_lemma_uint64_4 r43 r33;
let r12343 = vec_interleave_low_n 2 v34343 v12123 in
vec_interleave_low_n_lemma_uint64_4_2 v34343 v12123;
let v12124 = vec_interleave_low r24 r14 in
vec_interleave_low_lemma_uint64_4 r24 r14;
let v34344 = vec_interleave_low r44 r34 in
vec_interleave_low_lemma_uint64_4 r44 r34;
let r12344 = vec_interleave_low_n 2 v34344 v12124 in
vec_interleave_low_n_lemma_uint64_4_2 v34344 v12124;
let fr1234 = (r12340, r12341, r12342, r12343, r12344) in
eq_intro (feval5 fr1234) (create4 (feval5 fr4).[0] (feval5 fr3).[0] (feval5 fr2).[0] (feval5 fr).[0]);
let fr12345 = precomp_r5 #4 fr1234 in
let out = fmul_r5 #4 acc fr1234 fr12345 in
fmul_r5_eval_lemma acc fr1234 fr12345;
fmul_r5_fits_lemma acc fr1234 fr12345;
out
val lemma_fmul_r4_normalize51:
#m:scale32{m <= 2}
-> o:uint64xN 4{felem_fits1 o m} ->
Lemma
(let v00 = vec_interleave_high_n 2 o o in
let v10 = vec_add_mod o v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
felem_fits1 v20 (4 * m) /\
(uint64xN_v v20).[0] == (uint64xN_v o).[0] + (uint64xN_v o).[1] + (uint64xN_v o).[2] + (uint64xN_v o).[3])
let lemma_fmul_r4_normalize51 #m o =
let v00 = vec_interleave_high_n 2 o o in
vec_interleave_high_n_lemma_uint64_4_2 o o;
let (o0, o1, o2, o3) = ((vec_v o).[0], (vec_v o).[1], (vec_v o).[2], (vec_v o).[3]) in
assert (vec_v v00 == create4 o2 o3 o2 o3);
let v10 = vec_add_mod o v00 in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2) (pow2 64);
FStar.Math.Lemmas.modulo_lemma (v o1 + v o3) (pow2 64);
assert (v (vec_v v10).[0] == v o0 + v o2);
assert (v (vec_v v10).[1] == v o1 + v o3);
let v10h = vec_interleave_high v10 v10 in
vec_interleave_high_lemma_uint64_4 v10 v10;
assert (v (vec_v v10h).[0] == v (vec_v v10).[1]);
let v20 = vec_add_mod v10 v10h in
FStar.Math.Lemmas.modulo_lemma (v o0 + v o2 + v o1 + v o3) (pow2 64)
val lemma_fmul_r4_normalize51_expand:
v2:felem5 4
-> out:felem5 4 ->
Lemma
(requires
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(uint64xN_v v20).[0] == (uint64xN_v o0).[0] + (uint64xN_v o0).[1] + (uint64xN_v o0).[2] + (uint64xN_v o0).[3] /\
(uint64xN_v v21).[0] == (uint64xN_v o1).[0] + (uint64xN_v o1).[1] + (uint64xN_v o1).[2] + (uint64xN_v o1).[3] /\
(uint64xN_v v22).[0] == (uint64xN_v o2).[0] + (uint64xN_v o2).[1] + (uint64xN_v o2).[2] + (uint64xN_v o2).[3] /\
(uint64xN_v v23).[0] == (uint64xN_v o3).[0] + (uint64xN_v o3).[1] + (uint64xN_v o3).[2] + (uint64xN_v o3).[3] /\
(uint64xN_v v24).[0] == (uint64xN_v o4).[0] + (uint64xN_v o4).[1] + (uint64xN_v o4).[2] + (uint64xN_v o4).[3]))
(ensures
(let (v20, v21, v22, v23, v24) = v2 in
let (o0, o1, o2, o3, o4) = out in
(feval5 v2).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 out).[0] (feval5 out).[1]) (feval5 out).[2]) (feval5 out).[3]))
let lemma_fmul_r4_normalize51_expand v2 out =
let (v20, v21, v22, v23, v24) = as_tup64_i v2 0 in
let (o0, o1, o2, o3, o4) = out in
calc (==) {
as_nat5 (v20, v21, v22, v23, v24) % Vec.prime;
(==) { }
(as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1) + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1))
(as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) Vec.prime }
((as_nat5 (as_tup64_i out 0) + as_nat5 (as_tup64_i out 1)) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.modulo_distributivity (as_nat5 (as_tup64_i out 0)) (as_nat5 (as_tup64_i out 1)) Vec.prime }
(((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2) + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_l (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2))
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + as_nat5 (as_tup64_i out 2)) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r (((feval5 out).[0] + (feval5 out).[1]) % Vec.prime) (as_nat5 (as_tup64_i out 2)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + as_nat5 (as_tup64_i out 3)) % Vec.prime;
(==) { FStar.Math.Lemmas.lemma_mod_plus_distr_r ((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime)
(as_nat5 (as_tup64_i out 3)) Vec.prime }
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime;
};
assert ((feval5 v2).[0] ==
((((feval5 out).[0] + (feval5 out).[1]) % Vec.prime + (feval5 out).[2]) % Vec.prime + (feval5 out).[3]) % Vec.prime)
val fmul_r4_normalize51: a:felem5 4 ->
Pure (felem5 4)
(requires felem_fits5 a (1, 2, 1, 1, 2))
(ensures fun res ->
felem_fits5 res (4, 8, 4, 4, 8) /\
(feval5 res).[0] == Vec.pfadd (Vec.pfadd (Vec.pfadd (feval5 a).[0] (feval5 a).[1]) (feval5 a).[2]) (feval5 a).[3])
let fmul_r4_normalize51 fa =
let (o0, o1, o2, o3, o4) = fa in
let v00 = vec_interleave_high_n 2 o0 o0 in
let v10 = vec_add_mod o0 v00 in
let v10h = vec_interleave_high v10 v10 in
let v20 = vec_add_mod v10 v10h in
lemma_fmul_r4_normalize51 #1 o0;
let v01 = vec_interleave_high_n 2 o1 o1 in
let v11 = vec_add_mod o1 v01 in
let v11h = vec_interleave_high v11 v11 in
let v21 = vec_add_mod v11 v11h in
lemma_fmul_r4_normalize51 #2 o1;
let v02 = vec_interleave_high_n 2 o2 o2 in
let v12 = vec_add_mod o2 v02 in
let v12h = vec_interleave_high v12 v12 in
let v22 = vec_add_mod v12 v12h in
lemma_fmul_r4_normalize51 #1 o2;
let v03 = vec_interleave_high_n 2 o3 o3 in
let v13 = vec_add_mod o3 v03 in
let v13h = vec_interleave_high v13 v13 in
let v23 = vec_add_mod v13 v13h in
lemma_fmul_r4_normalize51 #1 o3;
let v04 = vec_interleave_high_n 2 o4 o4 in
let v14 = vec_add_mod o4 v04 in
let v14h = vec_interleave_high v14 v14 in
let v24 = vec_add_mod v14 v14h in
lemma_fmul_r4_normalize51 #2 o4;
let res = (v20, v21, v22, v23, v24) in
lemma_fmul_r4_normalize51_expand res fa;
res
val fmul_r4_normalize5_lemma:
acc:felem5 4
-> r:felem5 4
-> r_5:felem5 4
-> r4:felem5 4 ->
Lemma
(requires
felem_fits5 acc (3, 3, 3, 3, 3) /\
felem_fits5 r (1, 1, 1, 1, 1) /\
felem_fits5 r4 (2, 2, 2, 2, 2) /\
r_5 == precomp_r5 r /\
feval5 r4 == Vec.compute_r4 (feval5 r).[0])
(ensures
(let out = fmul_r4_normalize5 acc r r_5 r4 in
felem_fits5 out (2, 1, 1, 1, 1) /\
(feval5 out).[0] == Vec.normalize_4 (feval5 r).[0] (feval5 acc)))
[SMTPat (fmul_r4_normalize5 acc r r_5 r4)]
#restart-solver
#push-options "--z3rlimit 500"
let fmul_r4_normalize5_lemma acc fr fr_5 fr4 =
let fr2 = fmul_r5 #4 fr fr fr_5 in
let fr3 = fmul_r5 #4 fr2 fr fr_5 in
let out = fmul_r4_normalize50 acc fr fr2 fr3 fr4 in
let v2 = fmul_r4_normalize51 out in
let res = carry_full_felem5 v2 in
carry_full_felem5_lemma v2
#pop-options
val load_felem5_lemma:
#w:lanes
-> lo:uint64xN w
-> hi:uint64xN w ->
Lemma
(let f = load_felem5 #w lo hi in
felem_fits5 f (1, 1, 1, 1, 1) /\
felem_less5 f (pow2 128) /\
feval5 f == createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]))
let load_felem5_lemma #w lo hi =
let f = load_felem5 #w lo hi in
assert_norm (pow2 64 * pow2 64 = pow2 128);
assert_norm (pow2 128 < Vec.prime);
let res = createi #Vec.pfelem w
(fun i -> (uint64xN_v hi).[i] * pow2 64 + (uint64xN_v lo).[i]) in
match w with
| 1 ->
load_felem5_lemma_i #w lo hi 0;
eq_intro (feval5 f) res
| 2 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
eq_intro (feval5 f) res
| 4 ->
load_felem5_lemma_i #w lo hi 0;
load_felem5_lemma_i #w lo hi 1;
load_felem5_lemma_i #w lo hi 2;
load_felem5_lemma_i #w lo hi 3;
eq_intro (feval5 f) res
val load_felem5_4_interleave: lo:uint64xN 4 -> hi:uint64xN 4 -> Lemma
(let m0 = vec_interleave_low_n 2 lo hi in
let m1 = vec_interleave_high_n 2 lo hi in
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
let m4 = vec_interleave_high m0 m1 in
let t0 = vec_interleave_low m0 m1 in
let t3 = vec_interleave_low m2 m3 in
vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3] /\
vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2] /\
t3 == vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
let load_felem5_4_interleave lo hi =
let m0 = vec_interleave_low_n 2 lo hi in
vec_interleave_low_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m0 == create4 (vec_v lo).[0] (vec_v lo).[1] (vec_v hi).[0] (vec_v hi).[1]);
let m1 = vec_interleave_high_n 2 lo hi in
vec_interleave_high_n_lemma_uint64_4_2 lo hi;
//assert (vec_v m1 == create4 (vec_v lo).[2] (vec_v lo).[3] (vec_v hi).[2] (vec_v hi).[3]);
let m4 = vec_interleave_high m0 m1 in
vec_interleave_high_lemma_uint64_4 m0 m1;
//assert (vec_v m4 == create4 (vec_v m0).[1] (vec_v m1).[1] (vec_v m0).[3] (vec_v m1).[3]);
assert (vec_v m4 == create4 (vec_v lo).[1] (vec_v lo).[3] (vec_v hi).[1] (vec_v hi).[3]);
let t0 = vec_interleave_low m0 m1 in
vec_interleave_low_lemma_uint64_4 m0 m1;
//assert (vec_v t0 == create4 (vec_v m0).[0] (vec_v m1).[0] (vec_v m0).[2] (vec_v m1).[2]);
assert (vec_v t0 == create4 (vec_v lo).[0] (vec_v lo).[2] (vec_v hi).[0] (vec_v hi).[2]);
let m2 = cast U64 4 (vec_shift_right (cast U128 2 m0) 48ul) in
vec_shift_right_uint128_small2 m0 48ul;
assert ((vec_v m2).[0] == (((vec_v lo).[0] >>. 48ul) |. ((vec_v lo).[1] <<. 16ul)));
assert ((vec_v m2).[2] == (((vec_v hi).[0] >>. 48ul) |. ((vec_v hi).[1] <<. 16ul)));
let m3 = cast U64 4 (vec_shift_right (cast U128 2 m1) 48ul) in
vec_shift_right_uint128_small2 m1 48ul;
assert ((vec_v m3).[0] == (((vec_v lo).[2] >>. 48ul) |. ((vec_v lo).[3] <<. 16ul)));
assert ((vec_v m3).[2] == (((vec_v hi).[2] >>. 48ul) |. ((vec_v hi).[3] <<. 16ul)));
let t3 = vec_interleave_low m2 m3 in
vec_interleave_low_lemma_uint64_4 m2 m3;
eq_intro (vec_v t3) (vec_v (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul)));
vecv_extensionality t3 (vec_or (vec_shift_right t0 48ul) (vec_shift_left m4 16ul))
noextract | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | lo: Hacl.Spec.Poly1305.Field32xN.uint64xN 4 -> hi: Hacl.Spec.Poly1305.Field32xN.uint64xN 4
-> Hacl.Spec.Poly1305.Field32xN.felem5 4 | Prims.Tot | [
"total"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"FStar.Pervasives.Native.Mktuple5",
"Lib.IntVector.vec_t",
"Lib.IntTypes.U64",
"Prims.eq2",
"Lib.Sequence.lseq",
"Lib.IntTypes.int_t",
"Lib.IntTypes.SEC",
"Lib.IntVector.vec_v",
"Lib.Sequence.map",
"Lib.IntTypes.shift_right_i",
"FStar.UInt32.uint_to_t",
"FStar.UInt32.t",
"Lib.IntVector.vec_shift_right",
"FStar.UInt32.__uint_to_t",
"Lib.IntVector.vec_and",
"Lib.Sequence.map2",
"Lib.IntTypes.logor",
"Lib.IntVector.vec_shift_left",
"Lib.IntVector.vec_or",
"Lib.Sequence.create",
"Lib.IntTypes.mk_int",
"Hacl.Spec.Poly1305.Field32xN.mask26",
"Hacl.Spec.Poly1305.Field32xN.felem5"
] | [] | false | false | false | false | false | let load_felem5_4_compact lo hi =
| let mask26 = mask26 4 in
let t3 = vec_or (vec_shift_right lo 48ul) (vec_shift_left hi 16ul) in
let o0 = vec_and lo mask26 in
let o1 = vec_and (vec_shift_right lo 26ul) mask26 in
let o2 = vec_and (vec_shift_right t3 4ul) mask26 in
let o3 = vec_and (vec_shift_right t3 30ul) mask26 in
let o4 = vec_shift_right hi 40ul in
(o0, o1, o2, o3, o4) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.precomp_r5_fits_lemma | val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)] | val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)] | let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 57,
"end_line": 45,
"start_col": 0,
"start_line": 44
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)] | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (1, 1, 1, 1, 1)}
-> FStar.Pervasives.Lemma
(ensures
Hacl.Spec.Poly1305.Field32xN.felem_fits5 (Hacl.Spec.Poly1305.Field32xN.precomp_r5 r)
(5,
5,
5,
5,
5)) [SMTPat (Hacl.Spec.Poly1305.Field32xN.precomp_r5 r)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"FStar.Classical.forall_intro",
"Prims.b2t",
"Prims.op_LessThan",
"Hacl.Spec.Poly1305.Field32xN.as_tup64_i",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Lib.IntTypes.uint64",
"Prims.l_and",
"Prims.eq2",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"Lib.IntTypes.op_Star_Bang",
"Lib.IntTypes.u64",
"Hacl.Poly1305.Field32xN.Lemmas0.precomp_r5_as_tup64",
"Prims.unit"
] | [] | false | false | true | false | false | let precomp_r5_fits_lemma #w r =
| FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r) | false |
Hacl.Spec.Poly1305.Field32xN.Lemmas.fst | Hacl.Spec.Poly1305.Field32xN.Lemmas.mul_felem5_eval_lemma_i | val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i]) | val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i]) | let mul_felem5_eval_lemma_i #w f1 r r5 i =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_eval_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
assert ((fas_nat5 (a0,a1,a2,a3,a4)).[i] == (uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i]);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_eval_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
assert ((fas_nat5 (a10,a11,a12,a13,a14)).[i] == (fas_nat5 (a0,a1,a2,a3,a4)).[i] + (uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i]);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_eval_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
assert ((fas_nat5 (a20,a21,a22,a23,a24)).[i] == (fas_nat5 (a10,a11,a12,a13,a14)).[i] + (uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i]);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
assert ((fas_nat5 (a30,a31,a32,a33,a34)).[i] == (fas_nat5 (a20,a21,a22,a23,a24)).[i] + (uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i]);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_eval_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] == (fas_nat5 (a30,a31,a32,a33,a34)).[i] + (uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
assert ((fas_nat5 (a40,a41,a42,a43,a44)).[i] ==
(uint64xN_v f10).[i] * (fas_nat5 (r0,r1,r2,r3,r4)).[i] +
(uint64xN_v f11).[i] * (fas_nat5 (r54,r0,r1,r2,r3)).[i] +
(uint64xN_v f12).[i] * (fas_nat5 (r53,r54,r0,r1,r2)).[i] +
(uint64xN_v f13).[i] * (fas_nat5 (r52,r53,r54,r0,r1)).[i] +
(uint64xN_v f14).[i] * (fas_nat5 (r51,r52,r53,r54,r0)).[i]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i) | {
"file_name": "code/poly1305/Hacl.Spec.Poly1305.Field32xN.Lemmas.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 53,
"end_line": 169,
"start_col": 0,
"start_line": 136
} | module Hacl.Spec.Poly1305.Field32xN.Lemmas
open Lib.IntTypes
open Lib.IntVector
open Lib.Sequence
open FStar.Mul
open Hacl.Spec.Poly1305.Field32xN
open Hacl.Poly1305.Field32xN.Lemmas0
open Hacl.Poly1305.Field32xN.Lemmas1
open Hacl.Poly1305.Field32xN.Lemmas2
module Vec = Hacl.Spec.Poly1305.Vec
#set-options "--z3rlimit 100 --max_fuel 0 --initial_ifuel 1 --max_ifuel 1 --using_facts_from '* -FStar.Seq'"
val lemma_feval_is_fas_nat_i:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)}
-> i:size_nat{i < w} ->
Lemma ((feval5 f).[i] == (fas_nat5 f).[i])
let lemma_feval_is_fas_nat_i #w f i =
assert_norm (pow2 128 < Vec.prime);
assert ((feval5 f).[i] == (as_nat5 (transpose f).[i]) % Vec.prime);
FStar.Math.Lemmas.modulo_lemma (as_nat5 (transpose f).[i]) Vec.prime
val lemma_feval_is_fas_nat:
#w:lanes
-> f:felem5 w{felem_less5 f (pow2 128)} ->
Lemma (forall (i:nat). i < w ==> (fas_nat5 f).[i] == (feval5 f).[i])
let lemma_feval_is_fas_nat #w f =
FStar.Classical.forall_intro (lemma_feval_is_fas_nat_i #w f)
val precomp_r5_fits_lemma:
#w:lanes
-> r:felem5 w{felem_fits5 r (1, 1, 1, 1, 1)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (5, 5, 5, 5, 5))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_fits_lemma2:
#w:lanes
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)} ->
Lemma (felem_fits5 (precomp_r5 #w r) (10, 10, 10, 10, 10))
[SMTPat (precomp_r5 #w r)]
let precomp_r5_fits_lemma2 #w r =
FStar.Classical.forall_intro (precomp_r5_as_tup64 #w r)
val precomp_r5_zeros: w:lanes -> Lemma
(let r = (zero w, zero w, zero w, zero w, zero w) in
precomp_r5 r == (zero w, zero w, zero w, zero w, zero w))
let precomp_r5_zeros w =
let r = (zero w, zero w, zero w, zero w, zero w) in
let (r0, r1, r2, r3, r4) = precomp_r5 r in
let aux (i:nat{i < w}) : Lemma ((vec_v (vec_smul_mod (zero w) (u64 5))).[i] == u64 0) = () in
Classical.forall_intro aux;
eq_intro (vec_v (vec_smul_mod (zero w) (u64 5))) (vec_v (zero w));
vecv_extensionality (vec_smul_mod (zero w) (u64 5)) (zero w)
val fadd5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (felem_fits5 (fadd5 f1 f2) (3,3,3,3,3))
[SMTPat (fadd5 f1 f2)]
let fadd5_fits_lemma #w f1 f2 =
let (f10, f11, f12, f13, f14) = f1 in
let (f20, f21, f22, f23, f24) = f2 in
let o = fadd5 f1 f2 in
vec_add_mod_lemma f10 f20;
vec_add_mod_lemma f11 f21;
vec_add_mod_lemma f12 f22;
vec_add_mod_lemma f13 f23;
vec_add_mod_lemma f14 f24
val fadd5_eval_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (2,2,2,2,2)}
-> f2:felem5 w{felem_fits5 f2 (1,1,1,1,1)} ->
Lemma (feval5 (fadd5 f1 f2) == map2 Vec.pfadd (feval5 f1) (feval5 f2))
[SMTPat (fadd5 f1 f2)]
let fadd5_eval_lemma #w f1 f2 =
let o = fadd5 f1 f2 in
FStar.Classical.forall_intro (fadd5_eval_lemma_i f1 f2);
eq_intro (feval5 o) (map2 Vec.pfadd (feval5 f1) (feval5 f2))
val mul_felem5_fits_lemma:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10)} ->
Lemma (felem_wide_fits5 (mul_felem5 #w f1 r r5) (126, 102, 78, 54, 30))
[SMTPat (mul_felem5 #w f1 r r5)]
let mul_felem5_fits_lemma #w f1 r r5 =
let (r0, r1, r2, r3, r4) = r in
let (f10, f11, f12, f13, f14) = f1 in
let (r50, r51, r52, r53, r54) = r5 in
let (a0,a1,a2,a3,a4) = smul_felem5 #w f10 (r0,r1,r2,r3,r4) in
smul_felem5_fits_lemma #w #3 #(2,2,2,2,2) f10 (r0,r1,r2,r3,r4);
let (a10,a11,a12,a13,a14) = smul_add_felem5 #w f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4) in
smul_add_felem5_fits_lemma #w #3 #(10,2,2,2,2) #(6,6,6,6,6) f11 (r54,r0,r1,r2,r3) (a0,a1,a2,a3,a4);
let (a20,a21,a22,a23,a24) = smul_add_felem5 #w f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14) in
smul_add_felem5_fits_lemma #w #3 #(10,10,2,2,2) #(36,12,12,12,12) f12 (r53,r54,r0,r1,r2) (a10,a11,a12,a13,a14);
let (a30,a31,a32,a33,a34) = smul_add_felem5 #w f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,2,2) #(66,42,18,18,18) f13 (r52,r53,r54,r0,r1) (a20,a21,a22,a23,a24);
let (a40,a41,a42,a43,a44) = smul_add_felem5 #w f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34) in
smul_add_felem5_fits_lemma #w #3 #(10,10,10,10,2) #(96,72,48,24,24) f14 (r51,r52,r53,r54,r0) (a30,a31,a32,a33,a34)
val mul_felem5_eval_lemma_i:
#w:lanes
-> f1:felem5 w{felem_fits5 f1 (3, 3, 3, 3, 3)}
-> r:felem5 w{felem_fits5 r (2, 2, 2, 2, 2)}
-> r5:felem5 w{felem_fits5 r5 (10, 10, 10, 10, 10) /\ r5 == precomp_r5 r}
-> i:nat{i < w} ->
Lemma ((feval5 (mul_felem5 #w f1 r r5)).[i] == (feval5 f1).[i] `Vec.pfmul` (feval5 r).[i]) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntVector.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.Poly1305.Vec.fst.checked",
"Hacl.Spec.Poly1305.Field32xN.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas2.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas1.fst.checked",
"Hacl.Poly1305.Field32xN.Lemmas0.fst.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.Poly1305.Field32xN.Lemmas.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.Poly1305.Vec",
"short_module": "Vec"
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas2",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas1",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Poly1305.Field32xN.Lemmas0",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Sequence",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntVector",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.Poly1305.Field32xN",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 0,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
f1:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 f1 (3, 3, 3, 3, 3)} ->
r:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{Hacl.Spec.Poly1305.Field32xN.felem_fits5 r (2, 2, 2, 2, 2)} ->
r5:
Hacl.Spec.Poly1305.Field32xN.felem5 w
{ Hacl.Spec.Poly1305.Field32xN.felem_fits5 r5 (10, 10, 10, 10, 10) /\
r5 == Hacl.Spec.Poly1305.Field32xN.precomp_r5 r } ->
i: Prims.nat{i < w}
-> FStar.Pervasives.Lemma
(ensures
(Hacl.Spec.Poly1305.Field32xN.feval5 (Hacl.Spec.Poly1305.Field32xN.mul_felem5 f1 r r5)).[ i ] ==
Hacl.Spec.Poly1305.Vec.pfmul (Hacl.Spec.Poly1305.Field32xN.feval5 f1).[ i ]
(Hacl.Spec.Poly1305.Field32xN.feval5 r).[ i ]) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Hacl.Spec.Poly1305.Field32xN.lanes",
"Hacl.Spec.Poly1305.Field32xN.felem5",
"Hacl.Spec.Poly1305.Field32xN.felem_fits5",
"FStar.Pervasives.Native.Mktuple5",
"Prims.nat",
"Prims.l_and",
"Prims.eq2",
"Hacl.Spec.Poly1305.Field32xN.precomp_r5",
"Prims.b2t",
"Prims.op_LessThan",
"Hacl.Spec.Poly1305.Field32xN.uint64xN",
"Hacl.Poly1305.Field32xN.Lemmas0.mul_felem5_lemma",
"Hacl.Spec.Poly1305.Field32xN.as_tup64_i",
"Prims.unit",
"Hacl.Poly1305.Field32xN.Lemmas0.mul_felem5_eval_as_tup64",
"Prims._assert",
"Prims.int",
"Lib.Sequence.op_String_Access",
"Hacl.Spec.Poly1305.Field32xN.fas_nat5",
"Prims.op_Addition",
"FStar.Mul.op_Star",
"Hacl.Spec.Poly1305.Field32xN.uint64xN_v",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_add_felem5_fits_lemma",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_add_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.felem_wide5",
"Hacl.Spec.Poly1305.Field32xN.smul_add_felem5",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_felem5_fits_lemma",
"Hacl.Poly1305.Field32xN.Lemmas0.smul_felem5_eval_lemma",
"Hacl.Spec.Poly1305.Field32xN.smul_felem5"
] | [] | false | false | true | false | false | let mul_felem5_eval_lemma_i #w f1 r r5 i =
| let r0, r1, r2, r3, r4 = r in
let f10, f11, f12, f13, f14 = f1 in
let r50, r51, r52, r53, r54 = r5 in
let a0, a1, a2, a3, a4 = smul_felem5 #w f10 (r0, r1, r2, r3, r4) in
smul_felem5_eval_lemma #w #3 #(2, 2, 2, 2, 2) f10 (r0, r1, r2, r3, r4);
smul_felem5_fits_lemma #w #3 #(2, 2, 2, 2, 2) f10 (r0, r1, r2, r3, r4);
assert ((fas_nat5 (a0, a1, a2, a3, a4)).[ i ] ==
(uint64xN_v f10).[ i ] * (fas_nat5 (r0, r1, r2, r3, r4)).[ i ]);
let a10, a11, a12, a13, a14 = smul_add_felem5 #w f11 (r54, r0, r1, r2, r3) (a0, a1, a2, a3, a4) in
smul_add_felem5_eval_lemma #w
#3
#(10, 2, 2, 2, 2)
#(6, 6, 6, 6, 6)
f11
(r54, r0, r1, r2, r3)
(a0, a1, a2, a3, a4);
smul_add_felem5_fits_lemma #w
#3
#(10, 2, 2, 2, 2)
#(6, 6, 6, 6, 6)
f11
(r54, r0, r1, r2, r3)
(a0, a1, a2, a3, a4);
assert ((fas_nat5 (a10, a11, a12, a13, a14)).[ i ] ==
(fas_nat5 (a0, a1, a2, a3, a4)).[ i ] +
(uint64xN_v f11).[ i ] * (fas_nat5 (r54, r0, r1, r2, r3)).[ i ]);
let a20, a21, a22, a23, a24 =
smul_add_felem5 #w f12 (r53, r54, r0, r1, r2) (a10, a11, a12, a13, a14)
in
smul_add_felem5_eval_lemma #w
#3
#(10, 10, 2, 2, 2)
#(36, 12, 12, 12, 12)
f12
(r53, r54, r0, r1, r2)
(a10, a11, a12, a13, a14);
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 2, 2, 2)
#(36, 12, 12, 12, 12)
f12
(r53, r54, r0, r1, r2)
(a10, a11, a12, a13, a14);
assert ((fas_nat5 (a20, a21, a22, a23, a24)).[ i ] ==
(fas_nat5 (a10, a11, a12, a13, a14)).[ i ] +
(uint64xN_v f12).[ i ] * (fas_nat5 (r53, r54, r0, r1, r2)).[ i ]);
let a30, a31, a32, a33, a34 =
smul_add_felem5 #w f13 (r52, r53, r54, r0, r1) (a20, a21, a22, a23, a24)
in
smul_add_felem5_eval_lemma #w
#3
#(10, 10, 10, 2, 2)
#(66, 42, 18, 18, 18)
f13
(r52, r53, r54, r0, r1)
(a20, a21, a22, a23, a24);
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 10, 2, 2)
#(66, 42, 18, 18, 18)
f13
(r52, r53, r54, r0, r1)
(a20, a21, a22, a23, a24);
assert ((fas_nat5 (a30, a31, a32, a33, a34)).[ i ] ==
(fas_nat5 (a20, a21, a22, a23, a24)).[ i ] +
(uint64xN_v f13).[ i ] * (fas_nat5 (r52, r53, r54, r0, r1)).[ i ]);
let a40, a41, a42, a43, a44 =
smul_add_felem5 #w f14 (r51, r52, r53, r54, r0) (a30, a31, a32, a33, a34)
in
smul_add_felem5_eval_lemma #w
#3
#(10, 10, 10, 10, 2)
#(96, 72, 48, 24, 24)
f14
(r51, r52, r53, r54, r0)
(a30, a31, a32, a33, a34);
smul_add_felem5_fits_lemma #w
#3
#(10, 10, 10, 10, 2)
#(96, 72, 48, 24, 24)
f14
(r51, r52, r53, r54, r0)
(a30, a31, a32, a33, a34);
assert ((fas_nat5 (a40, a41, a42, a43, a44)).[ i ] ==
(fas_nat5 (a30, a31, a32, a33, a34)).[ i ] +
(uint64xN_v f14).[ i ] * (fas_nat5 (r51, r52, r53, r54, r0)).[ i ]);
assert ((fas_nat5 (a40, a41, a42, a43, a44)).[ i ] ==
(uint64xN_v f10).[ i ] * (fas_nat5 (r0, r1, r2, r3, r4)).[ i ] +
(uint64xN_v f11).[ i ] * (fas_nat5 (r54, r0, r1, r2, r3)).[ i ] +
(uint64xN_v f12).[ i ] * (fas_nat5 (r53, r54, r0, r1, r2)).[ i ] +
(uint64xN_v f13).[ i ] * (fas_nat5 (r52, r53, r54, r0, r1)).[ i ] +
(uint64xN_v f14).[ i ] * (fas_nat5 (r51, r52, r53, r54, r0)).[ i ]);
mul_felem5_eval_as_tup64 #w f1 r r5 i;
mul_felem5_lemma (as_tup64_i f1 i) (as_tup64_i r i) | false |
LowParse.Low.Sum.fst | LowParse.Low.Sum.gaccessor_clens_sum_payload_injective | val gaccessor_clens_sum_payload_injective
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: (x: sum_key t -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(sl sl': bytes)
: Lemma
(requires
(gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl /\
gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl' /\
injective_precond (parse_sum t p pc) sl sl'))
(ensures
(gaccessor_clens_sum_payload' t p pc k sl == gaccessor_clens_sum_payload' t p pc k sl')) | val gaccessor_clens_sum_payload_injective
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: (x: sum_key t -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(sl sl': bytes)
: Lemma
(requires
(gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl /\
gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl' /\
injective_precond (parse_sum t p pc) sl sl'))
(ensures
(gaccessor_clens_sum_payload' t p pc k sl == gaccessor_clens_sum_payload' t p pc k sl')) | let gaccessor_clens_sum_payload_injective
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(sl sl' : bytes)
: Lemma
(requires (
gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl /\
gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl' /\
injective_precond (parse_sum t p pc) sl sl'
))
(ensures (gaccessor_clens_sum_payload' t p pc k sl == gaccessor_clens_sum_payload' t p pc k sl'))
= parse_sum_eq'' t p pc sl;
parse_sum_eq'' t p pc sl' ;
parse_injective (parse_sum t p pc) sl sl' ;
parse_injective p sl sl' | {
"file_name": "src/lowparse/LowParse.Low.Sum.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 26,
"end_line": 835,
"start_col": 0,
"start_line": 818
} | module LowParse.Low.Sum
include LowParse.Low.Enum
include LowParse.Spec.Sum
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
module B = LowStar.Buffer
module Cast = FStar.Int.Cast
module U64 = FStar.UInt64
inline_for_extraction
let validate_sum_cases_aux
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(vc: ((x: sum_key t) -> Tot (validator (dsnd (pc x)))))
(k: sum_key t)
: Tot (validator (parse_sum_cases t pc k))
= [@inline_let]
let _ = synth_sum_case_injective t k in
validate_synth
(validate_weaken
(weaken_parse_cases_kind t pc)
(vc k)
()
)
(synth_sum_case t k)
()
inline_for_extraction
let validate_sum_cases_t
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot Type
= validator (parse_sum_cases t pc k)
let validate_sum_cases_t_eq
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(x y : validate_sum_cases_t t pc k)
: GTot Type0
= True
inline_for_extraction
let validate_sum_cases_t_if
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot (if_combinator _ (validate_sum_cases_t_eq t pc k))
= fun cond (sv_true: cond_true cond -> Tot (validate_sum_cases_t t pc k)) (sv_false: cond_false cond -> Tot (validate_sum_cases_t t pc k)) #rrel #rel input pos ->
if cond
then sv_true () input pos
else sv_false () input pos
inline_for_extraction
let validate_sum_cases
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(vc: ((x: sum_key t) -> Tot (validator (dsnd (pc x)))))
(destr: dep_enum_destr (sum_enum t) (validate_sum_cases_t t pc))
(k: sum_key t)
: Tot (validator (parse_sum_cases t pc k))
= destr
_
(validate_sum_cases_t_if t pc)
(fun _ _ -> ())
(fun _ _ _ _ -> ())
(validate_sum_cases_aux t pc vc)
k
inline_for_extraction
let validate_sum_aux_payload_t
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot Type
= (#rrel: _) -> (#rel: _) ->
(input: slice rrel rel) ->
(pos: U64.t) ->
HST.Stack U64.t
(requires (fun h -> live_slice h input /\ U64.v pos <= U32.v input.len))
(ensures (fun h res h' ->
B.modifies B.loc_none h h' /\ (
match k with
| Unknown _ -> is_error res
| Known k' ->
if is_success res
then
valid_pos (dsnd (pc k')) h input (uint64_to_uint32 pos) (uint64_to_uint32 res)
else
(~ (valid (dsnd (pc k')) h input (uint64_to_uint32 pos)))
)))
let validate_sum_aux_payload_eq
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot (validate_sum_aux_payload_t t pc k -> validate_sum_aux_payload_t t pc k -> GTot Type0)
= fun _ _ -> True
inline_for_extraction
let validate_sum_aux_payload_if'
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
(cond: bool)
(ift: ((cond_true cond) -> Tot (validate_sum_aux_payload_t t pc k)))
(iff: ((cond_false cond) -> Tot (validate_sum_aux_payload_t t pc k)))
: Tot (validate_sum_aux_payload_t t pc k)
= fun #rrel #rel input pos ->
if cond
then begin
(ift () <: validate_sum_aux_payload_t t pc k) input pos
end else
(iff () <: validate_sum_aux_payload_t t pc k) input pos
inline_for_extraction
let validate_sum_aux_payload_if
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot (if_combinator _ (validate_sum_aux_payload_eq t pc k))
= validate_sum_aux_payload_if' t pc k
#push-options "--z3rlimit 64 --z3cliopt smt.arith.nl=false --using_facts_from '* -FStar.Int.Cast -LowParse.BitFields'"
// --query_stats --smtencoding.elim_box true --smtencoding.l_arith_repr native --z3refresh"
inline_for_extraction
let validate_sum_aux
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(v: validator p)
(p32: leaf_reader p)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(v_payload: ((k: sum_repr_type t)) -> Tot (validate_sum_aux_payload_t t pc (maybe_enum_key_of_repr (sum_enum t) k)))
: Tot (validator (parse_sum t p pc))
= fun #rrel #rel input pos ->
let h = HST.get () in
[@inline_let]
let _ = parse_sum_eq'' t p pc (bytes_of_slice_from h input (uint64_to_uint32 pos)) in
[@inline_let]
let _ = valid_facts (parse_sum t p pc) h input (uint64_to_uint32 pos) in
[@inline_let]
let _ = valid_facts p h input (uint64_to_uint32 pos) in
let len_after_tag = v input pos in
if is_error len_after_tag
then len_after_tag
else begin
let h1 = HST.get () in
let k' = p32 input (uint64_to_uint32 pos) in
[@inline_let]
let _ =
match maybe_enum_key_of_repr (sum_enum t) k' with
| Known k -> valid_facts (dsnd (pc k)) h input (uint64_to_uint32 len_after_tag)
| _ -> ()
in
v_payload k' input len_after_tag
end
#pop-options
inline_for_extraction
let validate_sum_aux_payload'
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (validator (dsnd (pc x)))))
(k: maybe_enum_key (sum_enum t))
: Tot (validate_sum_aux_payload_t t pc k)
= fun #rrel #rel input pos ->
match k with
| Known k ->
[@inline_let]
let _ = synth_sum_case_injective t k in
pc32 k input pos
// validate_synth (pc32 k) (synth_sum_case t k) () input pos
| _ -> validator_error_generic
inline_for_extraction
let validate_sum_aux_payload
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (validator (dsnd (pc x)))))
(destr: dep_maybe_enum_destr_t (sum_enum t) (validate_sum_aux_payload_t t pc))
(k: sum_repr_type t)
: Tot (validate_sum_aux_payload_t t pc (maybe_enum_key_of_repr (sum_enum t) k))
= destr (validate_sum_aux_payload_eq t pc) (validate_sum_aux_payload_if t pc) (fun _ _ -> ()) (fun _ _ _ _ -> ()) (validate_sum_aux_payload' t pc pc32) k
inline_for_extraction
let validate_sum
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(v: validator p)
(p32: leaf_reader p)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (validator (dsnd (pc x)))))
(destr: dep_maybe_enum_destr_t (sum_enum t) (validate_sum_aux_payload_t t pc))
: Tot (validator (parse_sum t p pc))
= validate_sum_aux t v p32 pc (validate_sum_aux_payload t pc pc32 destr)
module HS = FStar.HyperStack
#push-options "--z3rlimit 256 --z3cliopt smt.arith.nl=false --initial_ifuel 8 --max_ifuel 8 --initial_fuel 2 --max_fuel 2"
#restart-solver
let valid_sum_intro
(h: HS.mem)
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(#rrel #rel: _)
(input: slice rrel rel)
(pos: U32.t)
: Lemma
(requires (
valid (parse_enum_key p (sum_enum t)) h input pos /\ (
let k = contents (parse_enum_key p (sum_enum t)) h input pos in
valid (dsnd (pc k)) h input (get_valid_pos (parse_enum_key p (sum_enum t)) h input pos)
)))
(ensures (
let k = contents (parse_enum_key p (sum_enum t)) h input pos in
let pos_payload = get_valid_pos (parse_enum_key p (sum_enum t)) h input pos in
valid_content_pos
(parse_sum t p pc) h input pos
(synth_sum_case t k (contents (dsnd (pc k)) h input pos_payload))
(get_valid_pos (dsnd (pc k)) h input pos_payload)
))
= valid_facts (parse_enum_key p (sum_enum t)) h input pos;
let k = contents (parse_enum_key p (sum_enum t)) h input pos in
let pos_payload = get_valid_pos (parse_enum_key p (sum_enum t)) h input pos in
valid_facts (dsnd (pc k)) h input pos_payload;
valid_facts (parse_sum t p pc) h input pos;
parse_sum_eq t p pc (bytes_of_slice_from h input pos)
#pop-options
inline_for_extraction
let finalize_sum_case
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(s: serializer p)
(w: leaf_writer_strong s)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(destr: enum_repr_of_key'_t (sum_enum t))
(k: sum_key t)
(#rrel #rel: _)
(input: slice rrel rel)
(pos: U32.t)
: HST.Stack unit
(requires (fun h ->
let len_tag = serialized_length (serialize_enum_key _ s (sum_enum t)) k in
U32.v pos + len_tag < 4294967296 /\ (
let pos_payload = pos `U32.add` U32.uint_to_t len_tag in
valid (dsnd (pc k)) h input pos_payload /\
writable input.base (U32.v pos) (U32.v pos_payload) h
)))
(ensures (fun h _ h' ->
let len_tag = serialized_length (serialize_enum_key _ s (sum_enum t)) k in
let pos_payload = pos `U32.add` U32.uint_to_t len_tag in
B.modifies (loc_slice_from_to input pos pos_payload) h h' /\
valid_content_pos (parse_sum t p pc) h' input pos (synth_sum_case t k (contents (dsnd (pc k)) h input pos_payload)) (get_valid_pos (dsnd (pc k)) h input pos_payload)
))
= let pos1 = write_enum_key w (sum_enum t) destr k input pos in
let h = HST.get () in
[@inline_let]
let _ = valid_sum_intro h t p pc input pos in
()
inline_for_extraction
let jump_sum_cases_aux
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(vc: ((x: sum_key t) -> Tot (jumper (dsnd (pc x)))))
(k: sum_key t)
: Tot (jumper (parse_sum_cases t pc k))
= [@inline_let]
let _ = synth_sum_case_injective t k in
jump_synth
(jump_weaken
(weaken_parse_cases_kind t pc)
(vc k)
()
)
(synth_sum_case t k)
()
inline_for_extraction
let jump_sum_cases_t
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot Type
= jumper (parse_sum_cases t pc k)
let jump_sum_cases_t_eq
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(x y : jump_sum_cases_t t pc k)
: GTot Type0
= True
inline_for_extraction
let jump_sum_cases_t_if
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot (if_combinator _ (jump_sum_cases_t_eq t pc k))
= fun cond (sv_true: cond_true cond -> Tot (jump_sum_cases_t t pc k)) (sv_false: cond_false cond -> Tot (jump_sum_cases_t t pc k)) #rrel #rel input pos ->
if cond
then sv_true () input pos
else sv_false () input pos
inline_for_extraction
let jump_sum_cases
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(vc: ((x: sum_key t) -> Tot (jumper (dsnd (pc x)))))
(destr: dep_enum_destr (sum_enum t) (jump_sum_cases_t t pc))
(k: sum_key t)
: Tot (jumper (parse_sum_cases t pc k))
= destr
_
(jump_sum_cases_t_if t pc)
(fun _ _ -> ())
(fun _ _ _ _ -> ())
(jump_sum_cases_aux t pc vc)
k
inline_for_extraction
let jump_sum_aux_payload_t
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot Type
= (#rrel: _) -> (#rel: _) ->
(input: slice rrel rel) ->
(pos: U32.t) ->
HST.Stack U32.t
(requires (fun h -> live_slice h input /\ U32.v pos <= U32.v input.len /\ (
match k with
| Unknown _ -> False
| Known k' -> valid (dsnd (pc k')) h input pos
)))
(ensures (fun h res h' ->
B.modifies B.loc_none h h' /\ (
match k with
| Unknown _ -> False
| Known k' ->
valid_pos (dsnd (pc k')) h input pos res
)))
let jump_sum_aux_payload_eq
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot (jump_sum_aux_payload_t t pc k -> jump_sum_aux_payload_t t pc k -> GTot Type0)
= fun _ _ -> True
inline_for_extraction
let jump_sum_aux_payload_if'
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
(cond: bool)
(ift: ((cond_true cond) -> Tot (jump_sum_aux_payload_t t pc k)))
(iff: ((cond_false cond) -> Tot (jump_sum_aux_payload_t t pc k)))
: Tot (jump_sum_aux_payload_t t pc k)
= fun #rrel #rel input pos ->
if cond
then begin
(ift () <: jump_sum_aux_payload_t t pc k) input pos
end else
(iff () <: jump_sum_aux_payload_t t pc k) input pos
inline_for_extraction
let jump_sum_aux_payload_if
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: maybe_enum_key (sum_enum t))
: Tot (if_combinator _ (jump_sum_aux_payload_eq t pc k))
= jump_sum_aux_payload_if' t pc k
let parse_sum_eq3
(#kt: parser_kind)
(t: sum)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(input: bytes)
(k' : sum_repr_type t)
(consumed_k: consumed_length input)
: Lemma
(requires (Some? (parse (parse_sum t p pc) input) /\ parse p input == Some (k', consumed_k)))
(ensures (
let input_k = Seq.slice input consumed_k (Seq.length input) in
let k = maybe_enum_key_of_repr (sum_enum t) k' in
begin match k with
| Known k ->
Some? (parse (dsnd (pc k)) input_k)
| _ -> False
end
))
= parse_sum_eq'' t p pc input
let parse_sum_eq4
(#kt: parser_kind)
(t: sum)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(input: bytes)
(k' : sum_repr_type t)
(consumed_k: consumed_length input)
(consumed_payload: nat)
: Lemma
(requires (Some? (parse (parse_sum t p pc) input) /\ parse p input == Some (k', consumed_k) /\ (
let input_k = Seq.slice input consumed_k (Seq.length input) in
let k = maybe_enum_key_of_repr (sum_enum t) k' in
begin match k with
| Known k ->
Some? (parse (dsnd (pc k)) input_k) /\ (
let Some (_, consumed_payload') = parse (dsnd (pc k)) input_k in
consumed_payload' == consumed_payload
)
| _ -> False
end
)))
(ensures (
let Some (_, consumed) = parse (parse_sum t p pc) input in
consumed == consumed_k + consumed_payload
))
= parse_sum_eq'' t p pc input
#push-options "--z3rlimit 16"
let valid_sum_elim
(h: HS.mem)
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(#rrel: _) (#rel: _)
(input: slice rrel rel)
(pos: U32.t)
: Lemma
(requires (
valid (parse_sum t p pc) h input pos
))
(ensures (
valid p h input pos /\ (
let pos_payload = get_valid_pos p h input pos in
let k' = maybe_enum_key_of_repr (sum_enum t) (contents p h input pos) in
match k' with
| Known k ->
k == sum_tag_of_data t (contents (parse_sum t p pc) h input pos) /\
valid (dsnd (pc k)) h input pos_payload /\
valid_pos
(parse_sum t p pc) h input pos
(get_valid_pos (dsnd (pc k)) h input pos_payload)
| _ -> False
)))
= let sinput = bytes_of_slice_from h input pos in
let _ = parse_sum_eq'' t p pc sinput in
[@inline_let]
let _ = valid_facts (parse_sum t p pc) h input pos in
let Some (k', consumed_k) = parse p sinput in
let pos_after_tag = U32.uint_to_t (U32.v pos + consumed_k) in
[@inline_let]
let _ = valid_facts p h input pos in
assert (valid_content_pos p h input pos k' pos_after_tag);
match maybe_enum_key_of_repr (sum_enum t) k' with
| Known k -> valid_facts (dsnd (pc k)) h input pos_after_tag
| _ -> ()
#pop-options
let valid_sum_elim_tag
(h: HS.mem)
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(#rrel #rel: _)
(input: slice rrel rel)
(pos: U32.t)
: Lemma
(requires (
valid (parse_sum t p pc) h input pos
))
(ensures (
valid (parse_enum_key p (sum_enum t)) h input pos /\
contents (parse_enum_key p (sum_enum t)) h input pos == sum_tag_of_data t (contents (parse_sum t p pc) h input pos)
))
= let _ = parse_sum_eq' t p pc (bytes_of_slice_from h input pos) in
let _ = valid_facts (parse_sum t p pc) h input pos in
let _ = valid_facts (parse_enum_key p (sum_enum t)) h input pos in
()
inline_for_extraction
let read_sum_tag
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(p32: leaf_reader p)
(destr: dep_maybe_enum_destr_t (sum_enum t) (read_enum_key_t (sum_enum t)))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(#rrel #rel: _)
(input: slice rrel rel)
(pos: U32.t)
: HST.Stack (sum_key t)
(requires (fun h ->
valid (parse_sum t p pc) h input pos
))
(ensures (fun h res h' ->
B.modifies B.loc_none h h' /\
res == sum_tag_of_data t (contents (parse_sum t p pc) h input pos)
))
= let h = HST.get () in
[@inline_let] let _ = valid_sum_elim_tag h t p pc input pos in
read_enum_key p32 (sum_enum t) destr input pos
inline_for_extraction
let jump_sum_aux
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(v: jumper p)
(p32: leaf_reader p)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(v_payload: ((k: sum_repr_type t)) -> Tot (jump_sum_aux_payload_t t pc (maybe_enum_key_of_repr (sum_enum t) k)))
: Tot (jumper (parse_sum t p pc))
= fun #rrel #rel input pos ->
let h = HST.get () in
[@inline_let]
let _ = valid_sum_elim h t p pc input pos in
let pos_after_tag = v input pos in
let k' = p32 input pos in
v_payload k' input pos_after_tag
inline_for_extraction
let jump_sum_aux_payload'
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (jumper (dsnd (pc x)))))
(k: maybe_enum_key (sum_enum t))
: Tot (jump_sum_aux_payload_t t pc k)
= fun #rrel #rel input pos ->
match k with
| Known k ->
[@inline_let]
let _ = synth_sum_case_injective t k in
pc32 k input pos
| _ -> 0ul // dummy, but we MUST NOT remove this branch, otherwise extraction fails
inline_for_extraction
let jump_sum_aux_payload
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (jumper (dsnd (pc x)))))
(destr: dep_maybe_enum_destr_t (sum_enum t) (jump_sum_aux_payload_t t pc))
(k: sum_repr_type t)
: Tot (jump_sum_aux_payload_t t pc (maybe_enum_key_of_repr (sum_enum t) k))
= destr (jump_sum_aux_payload_eq t pc) (jump_sum_aux_payload_if t pc) (fun _ _ -> ()) (fun _ _ _ _ -> ()) (jump_sum_aux_payload' t pc pc32) k
inline_for_extraction
let jump_sum
(t: sum)
(#kt: parser_kind)
(#p: parser kt (sum_repr_type t))
(v: jumper p)
(p32: leaf_reader p)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (jumper (dsnd (pc x)))))
(destr: dep_maybe_enum_destr_t (sum_enum t) (jump_sum_aux_payload_t t pc))
: Tot (jumper (parse_sum t p pc))
= jump_sum_aux t v p32 pc (jump_sum_aux_payload t pc pc32 destr)
inline_for_extraction
let read_sum_cases'
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (leaf_reader (dsnd (pc x)))))
(k: sum_key t)
: Tot (leaf_reader (parse_sum_cases' t pc k))
= [@inline_let]
let _ = synth_sum_case_injective t k in
read_synth'
(dsnd (pc k))
(synth_sum_case t k)
(pc32 k)
()
inline_for_extraction
let read_sum_cases_t
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot Type
= leaf_reader (parse_sum_cases' t pc k)
let read_sum_cases_t_eq
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(x y : read_sum_cases_t t pc k)
: GTot Type0
= True
inline_for_extraction
let read_sum_cases_t_if
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot (if_combinator _ (read_sum_cases_t_eq t pc k))
= fun cond (sv_true: cond_true cond -> Tot (read_sum_cases_t t pc k)) (sv_false: cond_false cond -> Tot (read_sum_cases_t t pc k)) #_ #_ input pos ->
if cond
then (sv_true () input pos)
else (sv_false () input pos)
inline_for_extraction
let read_sum_cases
(t: sum)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (leaf_reader (dsnd (pc x)))))
(destr: dep_enum_destr (sum_enum t) (read_sum_cases_t t pc))
(k: sum_key t)
: Tot (leaf_reader (parse_sum_cases' t pc k))
= destr
_
(read_sum_cases_t_if t pc)
(fun _ _ -> ())
(fun _ _ _ _ -> ())
(read_sum_cases' t pc pc32)
k
#push-options "--z3rlimit 32"
inline_for_extraction
let read_sum
(#kt: parser_kind)
(t: sum)
(p: parser kt (sum_repr_type t))
(p32: leaf_reader (parse_enum_key p (sum_enum t)))
(j: jumper p)
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(pc32: ((x: sum_key t) -> Tot (leaf_reader (dsnd (pc x)))))
(destr: dep_enum_destr (sum_enum t) (read_sum_cases_t t pc))
: Tot (leaf_reader (parse_sum t p pc))
=
fun #_ #_ input pos ->
let h = HST.get () in
valid_facts (parse_sum t p pc) h input pos;
parse_sum_eq' t p pc (bytes_of_slice_from h input pos);
valid_facts (parse_enum_key p (sum_enum t)) h input pos;
let k = p32 input pos in
let pos' = jump_enum_key j (sum_enum t) input pos in
valid_facts (parse_sum_cases' t pc k) h input pos' ;
read_sum_cases t pc pc32 destr k input pos'
#pop-options
inline_for_extraction
let serialize32_sum_cases_t
(t: sum)
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(k: sum_key t)
: Tot Type
= serializer32 (serialize_sum_cases t pc sc k)
let serialize32_sum_cases_t_eq
(t: sum)
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(k: sum_key t)
(x y: serialize32_sum_cases_t t sc k)
: GTot Type0
= True
inline_for_extraction
let serialize32_sum_cases_t_if
(t: sum)
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(k: sum_key t)
: Tot (if_combinator _ (serialize32_sum_cases_t_eq t sc k))
= fun cond (sv_true: (cond_true cond -> Tot (serialize32_sum_cases_t t sc k))) (sv_false: (cond_false cond -> Tot (serialize32_sum_cases_t t sc k))) x #rrel #rel b pos ->
if cond
then (sv_true () x b pos)
else (sv_false () x b pos)
inline_for_extraction
let serialize32_sum_cases_aux
(t: sum)
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(sc32: ((x: sum_key t) -> Tot (serializer32 (sc x))))
(k: sum_key t)
: Tot (serializer32 (serialize_sum_cases t pc sc k))
= fun x #rrel #rel b pos ->
[@inline_let] let _ =
Classical.forall_intro (parse_sum_cases_eq' t pc k);
synth_sum_case_injective t k;
synth_sum_case_inverse t k
in
serialize32_synth
(sc32 k)
(synth_sum_case t k)
(synth_sum_case_recip t k)
(fun x -> synth_sum_case_recip t k x)
()
x
b
pos
inline_for_extraction
let serialize32_sum_cases
(t: sum)
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(sc32: ((x: sum_key t) -> Tot (serializer32 (sc x))))
(destr: dep_enum_destr (sum_enum t) (serialize32_sum_cases_t t sc))
(k: sum_key t)
: Tot (serializer32 (serialize_sum_cases t pc sc k))
= destr
_
(serialize32_sum_cases_t_if t sc)
(fun _ _ -> ())
(fun _ _ _ _ -> ())
(serialize32_sum_cases_aux t sc sc32)
k
inline_for_extraction
let serialize32_sum
(#kt: parser_kind)
(t: sum)
(#p: parser kt (sum_repr_type t))
(s: serializer p {kt.parser_kind_subkind == Some ParserStrong})
(s32: serializer32 (serialize_enum_key _ s (sum_enum t)))
(#pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(sc: ((x: sum_key t) -> Tot (serializer (dsnd (pc x)))))
(sc32: ((x: sum_key t) -> Tot (serializer32 (sc x))))
(destr: dep_enum_destr (sum_enum t) (serialize32_sum_cases_t t sc))
: Tot (serializer32 (serialize_sum t s sc))
= fun x #rrel #rel b pos ->
serialize_sum_eq t s sc x;
let tg = sum_tag_of_data t x in
serialize32_nondep_then_aux s32 (serialize32_sum_cases t sc sc32 destr tg) tg x b pos
let clens_sum_tag
(s: sum)
: Tot (clens (sum_type s) (sum_key s))
= {
clens_cond = (fun _ -> True);
clens_get = sum_tag_of_data s;
}
let gaccessor_sum_tag
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
: Tot (gaccessor (parse_sum t p pc) (parse_enum_key p (sum_enum t)) (clens_sum_tag t))
= gaccessor_tagged_union_tag
(parse_enum_key p (sum_enum t))
(sum_tag_of_data t)
(parse_sum_cases t pc)
inline_for_extraction
let accessor_sum_tag
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
: Tot (accessor (gaccessor_sum_tag t p pc))
= accessor_tagged_union_tag
(parse_enum_key p (sum_enum t))
(sum_tag_of_data t)
(parse_sum_cases t pc)
let clens_sum_payload
(s: sum)
(k: sum_key s)
: Tot (clens (sum_type s) (sum_type_of_tag s k))
= {
clens_cond = (fun (x: sum_type s) -> sum_tag_of_data s x == k);
clens_get = (fun (x: sum_type s) -> synth_sum_case_recip s k x <: Ghost (sum_type_of_tag s k) (requires (sum_tag_of_data s x == k)) (ensures (fun _ -> True)));
}
#push-options "--z3rlimit 32"
let gaccessor_clens_sum_payload'
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: ((x: sum_key t) -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
: Tot (gaccessor' (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k))
= fun (input: bytes) ->
parse_sum_eq'' t p pc input;
let res =
match parse p input with
| Some (_, consumed) ->
synth_sum_case_inverse t k;
synth_sum_case_injective t k;
synth_injective_synth_inverse_synth_inverse_recip (synth_sum_case t k) (synth_sum_case_recip t k) ();
(consumed)
| _ -> 0 // dummy
in
(res <: (res: _ { gaccessor_post' (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) input res } ))
#push-options "--z3rlimit 64" | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"LowStar.Buffer.fst.checked",
"LowParse.Spec.Sum.fst.checked",
"LowParse.Low.Enum.fst.checked",
"FStar.UInt64.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Int.Cast.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked",
"FStar.Classical.fsti.checked"
],
"interface_file": false,
"source_file": "LowParse.Low.Sum.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack",
"short_module": "HS"
},
{
"abbrev": true,
"full_module": "FStar.UInt64",
"short_module": "U64"
},
{
"abbrev": true,
"full_module": "FStar.Int.Cast",
"short_module": "Cast"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": false,
"full_module": "LowParse.Spec.Sum",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low.Enum",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse.Low",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 64,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
t: LowParse.Spec.Sum.sum ->
p: LowParse.Spec.Base.parser kt (LowParse.Spec.Sum.sum_repr_type t) ->
pc:
(x: LowParse.Spec.Sum.sum_key t
-> Prims.dtuple2 LowParse.Spec.Base.parser_kind
(fun k -> LowParse.Spec.Base.parser k (LowParse.Spec.Sum.sum_type_of_tag t x))) ->
k: LowParse.Spec.Sum.sum_key t ->
sl: LowParse.Bytes.bytes ->
sl': LowParse.Bytes.bytes
-> FStar.Pervasives.Lemma
(requires
LowParse.Low.Base.Spec.gaccessor_pre (LowParse.Spec.Sum.parse_sum t p pc)
(FStar.Pervasives.dsnd (pc k))
(LowParse.Low.Sum.clens_sum_payload t k)
sl /\
LowParse.Low.Base.Spec.gaccessor_pre (LowParse.Spec.Sum.parse_sum t p pc)
(FStar.Pervasives.dsnd (pc k))
(LowParse.Low.Sum.clens_sum_payload t k)
sl' /\ LowParse.Spec.Base.injective_precond (LowParse.Spec.Sum.parse_sum t p pc) sl sl')
(ensures
LowParse.Low.Sum.gaccessor_clens_sum_payload' t p pc k sl ==
LowParse.Low.Sum.gaccessor_clens_sum_payload' t p pc k sl') | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"LowParse.Spec.Sum.sum",
"LowParse.Spec.Base.parser_kind",
"LowParse.Spec.Base.parser",
"LowParse.Spec.Sum.sum_repr_type",
"LowParse.Spec.Sum.sum_key",
"Prims.dtuple2",
"LowParse.Spec.Sum.sum_type_of_tag",
"LowParse.Bytes.bytes",
"LowParse.Spec.Base.parse_injective",
"Prims.unit",
"LowParse.Spec.Sum.parse_sum_kind",
"LowParse.Spec.Sum.sum_type",
"LowParse.Spec.Sum.parse_sum",
"LowParse.Spec.Sum.parse_sum_eq''",
"Prims.l_and",
"LowParse.Low.Base.Spec.gaccessor_pre",
"Prims.__proj__Mkdtuple2__item___1",
"FStar.Pervasives.dsnd",
"LowParse.Low.Sum.clens_sum_payload",
"LowParse.Spec.Base.injective_precond",
"Prims.squash",
"Prims.eq2",
"Prims.nat",
"LowParse.Low.Sum.gaccessor_clens_sum_payload'",
"Prims.Nil",
"FStar.Pervasives.pattern"
] | [] | true | false | true | false | false | let gaccessor_clens_sum_payload_injective
(t: sum)
(#kt: parser_kind)
(p: parser kt (sum_repr_type t))
(pc: (x: sum_key t -> Tot (k: parser_kind & parser k (sum_type_of_tag t x))))
(k: sum_key t)
(sl sl': bytes)
: Lemma
(requires
(gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl /\
gaccessor_pre (parse_sum t p pc) (dsnd (pc k)) (clens_sum_payload t k) sl' /\
injective_precond (parse_sum t p pc) sl sl'))
(ensures
(gaccessor_clens_sum_payload' t p pc k sl == gaccessor_clens_sum_payload' t p pc k sl')) =
| parse_sum_eq'' t p pc sl;
parse_sum_eq'' t p pc sl';
parse_injective (parse_sum t p pc) sl sl';
parse_injective p sl sl' | false |
Vale.Poly1305.Equiv.fst | Vale.Poly1305.Equiv.lemma_poly1305_equiv | val lemma_poly1305_equiv (text:bytes) (k:key) : Lemma
(ensures (
let inp = block_fun text in
let pad = pow2 (8 * size_block) in
let len = length text in
let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let key_s:nat128 = nat_from_bytes_le (slice k 16 32) in
let v = V.poly1305_hash key_r key_s inp len in
0 <= v /\ v < pow2 128 /\
nat_to_bytes_le 16 v == S.poly1305_mac text k
)) | val lemma_poly1305_equiv (text:bytes) (k:key) : Lemma
(ensures (
let inp = block_fun text in
let pad = pow2 (8 * size_block) in
let len = length text in
let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let key_s:nat128 = nat_from_bytes_le (slice k 16 32) in
let v = V.poly1305_hash key_r key_s inp len in
0 <= v /\ v < pow2 128 /\
nat_to_bytes_le 16 v == S.poly1305_mac text k
)) | let lemma_poly1305_equiv text k =
let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let key_s:nat128 = nat_from_bytes_le (slice k 16 32) in
let r = S.poly1305_encode_r key_bytes in
lemma_poly1305_equiv_r k;
let acc0 = 0 in
let inp = block_fun text in
let pad = pow2 (8 * size_block) in
assert_norm (pad == pow2_128);
let f = S.poly1305_update1 r size_block in
let len = length text in
let nb = len / size_block in
let acc1 = repeati nb (repeat_blocks_f size_block text f nb) acc0 in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let l = S.poly1305_update_last r in
let repeat_f = repeat_blocks_f size_block text f nb in
let hBlocks = V.poly1305_hash_blocks acc0 pad r inp nb in
if nExtra = 0 then
(
lemma_poly1305_equiv_rec text acc0 r nb;
Lib.Sequence.lemma_repeat_blocks size_block text f l acc0;
calc (==) {
V.poly1305_hash key_r key_s inp len;
== {}
mod2_128 (hBlocks + key_s);
== {assert_norm (mod2_128 (hBlocks + key_s) == (hBlocks + key_s) % pow2 128)}
(hBlocks + key_s) % pow2 128;
};
calc (==) {
hBlocks <: int;
== {lemma_poly1305_equiv_rec text acc0 r nb}
repeati nb repeat_f acc0 <: felem;
};
calc (==) {
repeati nb repeat_f acc0;
== {}
l nExtra last acc1;
== {Lib.Sequence.lemma_repeat_blocks size_block text f l acc0}
repeat_blocks #uint8 #felem size_block text f l acc0;
== {}
S.poly1305_update text acc0 r;
};
calc (==) {
nat_to_bytes_le 16 (V.poly1305_hash key_r key_s inp len);
== {}
nat_to_bytes_le 16 ((S.poly1305_update text acc0 r + key_s) % pow2 128);
== {}
S.poly1305_mac text k;
};
()
)
else
(
lemma_poly1305_equiv_rec text acc0 r nb;
Lib.Sequence.lemma_repeat_blocks size_block text f l acc0;
let padLast = pow2 (nExtra * 8) in
let hLast = modp ((hBlocks + padLast + inp nb % padLast) * r) in
calc (==) {
V.poly1305_hash key_r key_s inp len;
== {}
mod2_128 (hLast + key_s);
== {assert_norm (mod2_128 (hLast + key_s) == (hLast + key_s) % pow2 128)}
(hLast + key_s) % pow2 128;
};
calc (==) {
hBlocks <: int;
== {lemma_poly1305_equiv_rec text acc0 r nb}
repeati nb repeat_f acc0 <: felem;
};
calc (==) {
S.poly1305_update1 r nExtra last (repeati nb repeat_f acc0);
== {}
l nExtra last acc1;
== {Lib.Sequence.lemma_repeat_blocks size_block text f l acc0}
repeat_blocks #uint8 #felem size_block text f l acc0;
== {}
S.poly1305_update text acc0 r;
};
lemma_poly1305_equiv_last text r hBlocks;
calc (==) {
nat_to_bytes_le 16 (V.poly1305_hash key_r key_s inp len);
== {}
nat_to_bytes_le 16 ((S.poly1305_update text acc0 r + key_s) % pow2 128);
== {}
S.poly1305_mac text k;
};
()
) | {
"file_name": "vale/code/crypto/poly1305/Vale.Poly1305.Equiv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 3,
"end_line": 265,
"start_col": 0,
"start_line": 176
} | module Vale.Poly1305.Equiv
open FStar.Mul
module BSeq = Lib.ByteSequence
// REVIEW: S and V use different smtencoding flags,
// so some equalities between S and V definitions aren't as obvious to Z3 as we might want.
unfold let pow2_128 = Vale.Def.Words_s.pow2_128
unfold let nat64 = Vale.Def.Words_s.nat64
unfold let iand #n = Vale.Def.Types_s.iand #n
unfold let size_nat = Lib.IntTypes.size_nat
unfold let uint_v #t #l = Lib.IntTypes.uint_v #t #l
unfold let uint8 = Lib.IntTypes.uint8
unfold let u64 = Lib.IntTypes.u64
unfold let logand #t #l = Lib.IntTypes.logand #t #l
unfold let repeati = Lib.LoopCombinators.repeati
unfold let repeat_blocks = Lib.Sequence.repeat_blocks
unfold let repeat_blocks_f = Lib.Sequence.repeat_blocks_f
unfold let sub #a #len = Lib.Sequence.sub #a #len
unfold let lbytes = Lib.ByteSequence.lbytes
unfold let uint_from_bytes_le #t #l = Lib.ByteSequence.uint_from_bytes_le #t #l
unfold let prime = S.prime
unfold let felem = S.felem
unfold let fadd = S.fadd
unfold let fmul = S.fmul
unfold let to_felem = S.to_felem
unfold let modp = V.modp
unfold let mod2_128 = V.mod2_128
#set-options "--z3rlimit 150 --max_fuel 1 --max_ifuel 1"
let rec lemma_poly1305_equiv_rec (text:bytes) (acc0:felem) (r:felem) (k:nat) : Lemma
(requires k <= length text / size_block)
(ensures (
let f = S.poly1305_update1 r size_block in
let repeat_f = repeat_blocks_f size_block text f (length text / size_block) in
let pad = pow2 (8 * size_block) in
V.poly1305_hash_blocks acc0 pad r (block_fun text) k == repeati k repeat_f acc0
))
(decreases k)
=
let inp = block_fun text in
let f = S.poly1305_update1 r size_block in
let len = length text in
let nb = len / size_block in
let repeat_f = repeat_blocks_f size_block text f nb in
let pad = pow2 (8 * size_block) in
assert_norm (pow2 128 + pow2 128 < prime);
if k = 0 then
Lib.LoopCombinators.eq_repeati0 nb repeat_f acc0
else
(
let kk = k - 1 in
let hh = V.poly1305_hash_blocks acc0 pad r inp kk in
let r0:felem = repeati kk repeat_f acc0 in
let block = Seq.slice text (kk * size_block) (kk * size_block + size_block) in
calc (==) {
V.poly1305_hash_blocks acc0 pad r inp k;
== {}
modp ((hh + pad + inp kk) * r);
== {assert_norm (modp ((hh + pad + inp kk) * r) == (hh + pad + inp kk) * r % prime)}
(hh + pad + inp kk) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (hh + pad + inp kk) r prime}
((hh + pad + inp kk) % prime) * r % prime;
== {lemma_poly1305_equiv_rec text acc0 r kk}
((pad + inp kk + r0) % prime) * r % prime;
== {assert_norm (fmul (fadd (pad + inp kk) r0) r == ((pad + inp kk + r0) % prime) * r % prime)}
fmul (fadd (pad + inp kk) r0) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (pad + inp kk) r0 prime }
fmul (fadd (fadd pad (inp kk)) r0) r;
== {}
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
};
calc (==) {
S.poly1305_update1 r size_block block (repeati kk repeat_f acc0);
== {}
f block (repeati kk repeat_f acc0);
== {}
repeat_f kk (repeati kk repeat_f acc0);
== {Lib.LoopCombinators.unfold_repeati nb repeat_f acc0 kk}
repeati k repeat_f acc0;
}
)
let lemma_poly1305_equiv_last (text:bytes) (r:felem) (hBlocks:felem) : Lemma
(ensures (
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
modp ((hBlocks + padLast + inp nb % padLast) * r) == S.poly1305_update1 r nExtra last hBlocks
))
=
let inp = block_fun text in
let len = length text in
let nb = len / size_block in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let padLast = pow2 (nExtra * 8) in
let x = nat_from_bytes_le last in
Math.Lemmas.pow2_le_compat 128 (8 * nExtra);
FStar.Math.Lemmas.modulo_lemma x padLast;
assert_norm (x + padLast < prime);
calc (==) {
modp ((hBlocks + padLast + inp nb % padLast) * r);
== {}
modp ((x + padLast + hBlocks) * r);
== {assert_norm (modp ((x + padLast + hBlocks) * r) == (x + padLast + hBlocks) * r % prime)}
(x + padLast + hBlocks) * r % prime;
== {FStar.Math.Lemmas.lemma_mod_mul_distr_l (x + padLast + hBlocks) r prime}
((x + padLast + hBlocks) % prime) * r % prime;
== {assert_norm (((x + padLast + hBlocks) % prime) * r % prime == fmul (fadd (x + padLast) hBlocks) r)}
fmul (fadd (x + padLast) hBlocks) r;
== { FStar.Math.Lemmas.lemma_mod_plus_distr_l (x + padLast) hBlocks prime }
fmul (fadd (fadd x padLast) hBlocks) r;
== {}
S.poly1305_update1 r nExtra last hBlocks;
}
let lemma_poly1305_equiv_r (k:key) : Lemma
(ensures (
let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
iand key_r 0x0ffffffc0ffffffc0ffffffc0fffffff == S.poly1305_encode_r key_bytes
))
=
let key_bytes:S.block = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let mask = 0x0ffffffc0ffffffc0ffffffc0fffffff in
let rv = iand key_r mask in
let lo = uint_from_bytes_le (sub key_bytes 0 8) in
let hi = uint_from_bytes_le (sub key_bytes 8 8) in
let mask0 = u64 0x0ffffffc0fffffff in
let mask1 = u64 0x0ffffffc0ffffffc in
let mlo = logand lo mask0 in
let mhi = logand hi mask1 in
assert_norm (pow2 128 < prime);
let rs:felem = to_felem (uint_v mhi * pow2 64 + uint_v mlo) in
assert_norm (rs == S.poly1305_encode_r key_bytes);
let v_mask0:nat64 = 0x0ffffffc0fffffff in
let v_mask1:nat64 = 0x0ffffffc0ffffffc in
let v_lo:nat64 = uint_v lo in
let v_hi:nat64 = uint_v hi in
let lowerUpper128 = Vale.Poly1305.Math.lowerUpper128 in
let v_lo_hi:nat128 = lowerUpper128 v_lo v_hi in
let v_mask_0_1:nat128 = lowerUpper128 v_mask0 v_mask1 in
let z0 = iand v_lo v_mask0 in
let z1 = iand v_hi v_mask1 in
let z = lowerUpper128 z0 z1 in
let and64 = UInt.logand #64 in
calc (==) {
rv;
== {}
iand key_r mask;
== {Hacl.Impl.Poly1305.Lemmas.uint_from_bytes_le_lemma key_bytes}
iand (pow2 64 * v_hi + v_lo) mask;
== {Vale.Poly1305.Math.lowerUpper128_reveal ()}
iand v_lo_hi v_mask_0_1;
== {Vale.Poly1305.Math.lemma_lowerUpper128_and v_lo_hi v_lo v_hi v_mask_0_1 v_mask0 v_mask1 z z0 z1}
z;
== {Vale.Poly1305.Math.lowerUpper128_reveal ()}
z1 * pow2 64 + z0;
== {Vale.Arch.TypesNative.reveal_iand_all 64}
and64 v_hi v_mask1 * pow2 64 + and64 v_lo v_mask0;
== {Lib.IntTypes.logand_spec hi mask1; Lib.IntTypes.logand_spec lo mask0}
uint_v mhi * pow2 64 + uint_v mlo;
== {}
rs;
} | {
"checked_file": "/",
"dependencies": [
"Vale.Poly1305.Math.fsti.checked",
"Vale.Def.Words_s.fsti.checked",
"Vale.Def.Types_s.fst.checked",
"Vale.Arch.TypesNative.fsti.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.LoopCombinators.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Hacl.Impl.Poly1305.Lemmas.fst.checked",
"FStar.UInt.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Vale.Poly1305.Equiv.fst"
} | [
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": true,
"full_module": "Vale.Poly1305.Spec_s",
"short_module": "V"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "FStar.Seq.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "Vale.Poly1305",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 0,
"max_fuel": 1,
"max_ifuel": 1,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": true,
"smtencoding_l_arith_repr": "native",
"smtencoding_nl_arith_repr": "wrapped",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": false,
"z3cliopt": [
"smt.arith.nl=false",
"smt.QI.EAGER_THRESHOLD=100",
"smt.CASE_SPLIT=3"
],
"z3refresh": false,
"z3rlimit": 150,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | text: Vale.Poly1305.Equiv.bytes -> k: Vale.Poly1305.Equiv.key
-> FStar.Pervasives.Lemma
(ensures
(let inp = Vale.Poly1305.Equiv.block_fun text in
let pad = Prims.pow2 (8 * Vale.Poly1305.Equiv.size_block) in
let len = FStar.Seq.Base.length text in
let key_bytes = FStar.Seq.Base.slice k 0 16 in
let key_r = Vale.Poly1305.Equiv.nat_from_bytes_le key_bytes in
let key_s = Vale.Poly1305.Equiv.nat_from_bytes_le (FStar.Seq.Base.slice k 16 32) in
let v = Vale.Poly1305.Spec_s.poly1305_hash key_r key_s inp len in
0 <= v /\ v < Prims.pow2 128 /\
Vale.Poly1305.Equiv.nat_to_bytes_le 16 v == Spec.Poly1305.poly1305_mac text k)) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Vale.Poly1305.Equiv.bytes",
"Vale.Poly1305.Equiv.key",
"Prims.op_Equality",
"Prims.int",
"Prims.unit",
"FStar.Calc.calc_finish",
"Lib.Sequence.seq",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Prims.l_and",
"Prims.eq2",
"Prims.nat",
"Lib.Sequence.length",
"Prims.l_or",
"Prims.b2t",
"Prims.op_LessThan",
"Prims.pow2",
"Prims.op_Multiply",
"Vale.Poly1305.Spec_s.poly1305_hash",
"Lib.ByteSequence.nat_from_intseq_le",
"Vale.Poly1305.Equiv.nat_to_bytes_le",
"Spec.Poly1305.poly1305_mac",
"Prims.Cons",
"FStar.Preorder.relation",
"Prims.Nil",
"FStar.Calc.calc_step",
"Prims.op_Modulus",
"Prims.op_Addition",
"Spec.Poly1305.poly1305_update",
"FStar.Calc.calc_init",
"FStar.Calc.calc_pack",
"Prims.squash",
"Spec.Poly1305.felem",
"Vale.Poly1305.Equiv.repeati",
"Vale.Poly1305.Equiv.repeat_blocks",
"Vale.Poly1305.Equiv.uint8",
"Vale.Poly1305.Equiv.felem",
"Vale.Poly1305.Equiv.size_block",
"Lib.Sequence.lemma_repeat_blocks",
"Lib.IntTypes.uint_t",
"Vale.Poly1305.Equiv.lemma_poly1305_equiv_rec",
"Vale.Poly1305.Equiv.mod2_128",
"FStar.Pervasives.assert_norm",
"Prims.bool",
"Vale.Poly1305.Equiv.lemma_poly1305_equiv_last",
"Spec.Poly1305.poly1305_update1",
"Vale.Poly1305.Equiv.modp",
"FStar.Mul.op_Star",
"Prims.pos",
"Vale.Poly1305.Spec_s.poly1305_hash_blocks",
"Vale.Poly1305.Equiv.repeat_blocks_f",
"Prims.op_LessThanOrEqual",
"Prims.op_Subtraction",
"Lib.Sequence.lseq",
"Spec.Poly1305.poly1305_update_last",
"FStar.Seq.Base.seq",
"FStar.Seq.Base.slice",
"Prims.op_Division",
"FStar.Seq.Base.length",
"Spec.Poly1305.size_block",
"Vale.Poly1305.Equiv.pow2_128",
"Vale.Def.Words_s.nat128",
"Vale.Poly1305.Equiv.block_fun",
"Vale.Poly1305.Equiv.lemma_poly1305_equiv_r",
"Spec.Poly1305.poly1305_encode_r",
"Vale.Poly1305.Equiv.nat_from_bytes_le"
] | [] | false | false | true | false | false | let lemma_poly1305_equiv text k =
| let key_bytes = slice k 0 16 in
let key_r:nat128 = nat_from_bytes_le key_bytes in
let key_s:nat128 = nat_from_bytes_le (slice k 16 32) in
let r = S.poly1305_encode_r key_bytes in
lemma_poly1305_equiv_r k;
let acc0 = 0 in
let inp = block_fun text in
let pad = pow2 (8 * size_block) in
assert_norm (pad == pow2_128);
let f = S.poly1305_update1 r size_block in
let len = length text in
let nb = len / size_block in
let acc1 = repeati nb (repeat_blocks_f size_block text f nb) acc0 in
let last = Seq.slice text (nb * size_block) len in
let nExtra = len % size_block in
let l = S.poly1305_update_last r in
let repeat_f = repeat_blocks_f size_block text f nb in
let hBlocks = V.poly1305_hash_blocks acc0 pad r inp nb in
if nExtra = 0
then
(lemma_poly1305_equiv_rec text acc0 r nb;
Lib.Sequence.lemma_repeat_blocks size_block text f l acc0;
calc ( == ) {
V.poly1305_hash key_r key_s inp len;
( == ) { () }
mod2_128 (hBlocks + key_s);
( == ) { assert_norm (mod2_128 (hBlocks + key_s) == (hBlocks + key_s) % pow2 128) }
(hBlocks + key_s) % pow2 128;
};
calc ( == ) {
hBlocks <: int;
( == ) { lemma_poly1305_equiv_rec text acc0 r nb }
repeati nb repeat_f acc0 <: felem;
};
calc ( == ) {
repeati nb repeat_f acc0;
( == ) { () }
l nExtra last acc1;
( == ) { Lib.Sequence.lemma_repeat_blocks size_block text f l acc0 }
repeat_blocks #uint8 #felem size_block text f l acc0;
( == ) { () }
S.poly1305_update text acc0 r;
};
calc ( == ) {
nat_to_bytes_le 16 (V.poly1305_hash key_r key_s inp len);
( == ) { () }
nat_to_bytes_le 16 ((S.poly1305_update text acc0 r + key_s) % pow2 128);
( == ) { () }
S.poly1305_mac text k;
};
())
else
(lemma_poly1305_equiv_rec text acc0 r nb;
Lib.Sequence.lemma_repeat_blocks size_block text f l acc0;
let padLast = pow2 (nExtra * 8) in
let hLast = modp ((hBlocks + padLast + inp nb % padLast) * r) in
calc ( == ) {
V.poly1305_hash key_r key_s inp len;
( == ) { () }
mod2_128 (hLast + key_s);
( == ) { assert_norm (mod2_128 (hLast + key_s) == (hLast + key_s) % pow2 128) }
(hLast + key_s) % pow2 128;
};
calc ( == ) {
hBlocks <: int;
( == ) { lemma_poly1305_equiv_rec text acc0 r nb }
repeati nb repeat_f acc0 <: felem;
};
calc ( == ) {
S.poly1305_update1 r nExtra last (repeati nb repeat_f acc0);
( == ) { () }
l nExtra last acc1;
( == ) { Lib.Sequence.lemma_repeat_blocks size_block text f l acc0 }
repeat_blocks #uint8 #felem size_block text f l acc0;
( == ) { () }
S.poly1305_update text acc0 r;
};
lemma_poly1305_equiv_last text r hBlocks;
calc ( == ) {
nat_to_bytes_le 16 (V.poly1305_hash key_r key_s inp len);
( == ) { () }
nat_to_bytes_le 16 ((S.poly1305_update text acc0 r + key_s) % pow2 128);
( == ) { () }
S.poly1305_mac text k;
};
()) | false |
Steel.Memory.fst | Steel.Memory.core_mem | val core_mem (m:mem u#a) : mem u#a | val core_mem (m:mem u#a) : mem u#a | let core_mem (m:mem) : mem = mem_of_heap (heap_of_mem m) | {
"file_name": "lib/steel/Steel.Memory.fst",
"git_rev": "f984200f79bdc452374ae994a5ca837496476c41",
"git_url": "https://github.com/FStarLang/steel.git",
"project_name": "steel"
} | {
"end_col": 56,
"end_line": 50,
"start_col": 0,
"start_line": 50
} | (*
Copyright 2020 Microsoft Research
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*)
module Steel.Memory
module F = FStar.FunctionalExtensionality
open FStar.FunctionalExtensionality
open FStar.PCM
module H = Steel.Heap
noeq
type lock_state : Type u#(a + 1) =
| Invariant : inv:H.slprop u#a -> lock_state
let lock_store : Type u#(a+1) = list (lock_state u#a)
noeq
type mem : Type u#(a + 1) =
{
ctr: nat;
heap: H.heap u#a;
locks: lock_store u#a;
}
let heap_of_mem (x:mem) : H.heap = x.heap
let mem_of_heap (h:H.heap) : mem = {
ctr = 0;
heap = h;
locks = []
}
let mem_set_heap (m:mem) (h:H.heap) : mem = {
ctr = m.ctr;
heap = h;
locks = m.locks;
} | {
"checked_file": "/",
"dependencies": [
"Steel.Preorder.fst.checked",
"Steel.Heap.fsti.checked",
"prims.fst.checked",
"FStar.Witnessed.Core.fsti.checked",
"FStar.Set.fsti.checked",
"FStar.Preorder.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.PCM.fst.checked",
"FStar.NMSTTotal.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.IndefiniteDescription.fsti.checked",
"FStar.Ghost.fsti.checked",
"FStar.FunctionalExtensionality.fsti.checked",
"FStar.Classical.Sugar.fsti.checked",
"FStar.Classical.fsti.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": true,
"source_file": "Steel.Memory.fst"
} | [
{
"abbrev": true,
"full_module": "Steel.Heap",
"short_module": "H"
},
{
"abbrev": false,
"full_module": "FStar.FunctionalExtensionality",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.FunctionalExtensionality",
"short_module": "F"
},
{
"abbrev": false,
"full_module": "FStar.PCM",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Ghost",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "Steel",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Pervasives",
"short_module": null
},
{
"abbrev": false,
"full_module": "Prims",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar",
"short_module": null
}
] | {
"detail_errors": false,
"detail_hint_replay": false,
"initial_fuel": 2,
"initial_ifuel": 1,
"max_fuel": 8,
"max_ifuel": 2,
"no_plugins": false,
"no_smt": false,
"no_tactics": false,
"quake_hi": 1,
"quake_keep": false,
"quake_lo": 1,
"retry": false,
"reuse_hint_for": null,
"smtencoding_elim_box": false,
"smtencoding_l_arith_repr": "boxwrap",
"smtencoding_nl_arith_repr": "boxwrap",
"smtencoding_valid_elim": false,
"smtencoding_valid_intro": true,
"tcnorm": true,
"trivial_pre_for_unannotated_effectful_fns": true,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | m: Steel.Memory.mem -> Steel.Memory.mem | Prims.Tot | [
"total"
] | [] | [
"Steel.Memory.mem",
"Steel.Memory.mem_of_heap",
"Steel.Memory.heap_of_mem"
] | [] | false | false | false | true | false | let core_mem (m: mem) : mem =
| mem_of_heap (heap_of_mem m) | false |
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