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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Hacl.Impl.Chacha20Poly1305.fst | Hacl.Impl.Chacha20Poly1305.aead_decrypt | val aead_decrypt: #w:field_spec -> aead_decrypt_st w | val aead_decrypt: #w:field_spec -> aead_decrypt_st w | let aead_decrypt #w output input input_len data data_len key nonce tag =
push_frame();
let h0 = ST.get() in
// Create a buffer to store the temporary mac
let computed_tag = create 16ul (u8 0) in
// Compute the expected mac using Poly1305
derive_key_poly1305_do #w key nonce data_len data input_len input computed_tag;
let h1 = ST.get() in
let res =
if lbytes_eq computed_tag tag then (
assert (BSeq.lbytes_eq (as_seq h1 computed_tag) (as_seq h1 tag));
// If the computed mac matches the mac given, decrypt the ciphertext and return 0
chacha20_encrypt #w input_len output input key nonce 1ul;
0ul
) else 1ul // Macs do not agree, do not decrypt
in
pop_frame();
res | {
"file_name": "code/chacha20poly1305/Hacl.Impl.Chacha20Poly1305.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 5,
"end_line": 222,
"start_col": 0,
"start_line": 205
} | module Hacl.Impl.Chacha20Poly1305
open FStar.HyperStack.All
open FStar.HyperStack
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
open Lib.ByteBuffer
open Hacl.Impl.Chacha20Poly1305.PolyCore
open Hacl.Impl.Poly1305.Fields
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BSeq = Lib.ByteSequence
module Spec = Spec.Chacha20Poly1305
module SpecPoly = Spec.Poly1305
module Poly = Hacl.Impl.Poly1305
#reset-options "--z3rlimit 150 --max_fuel 0 --max_ifuel 1 --record_options"
val poly1305_do_:
#w:field_spec
-> k:lbuffer uint8 32ul // key
-> aadlen:size_t
-> aad:lbuffer uint8 aadlen // authenticated additional data
-> mlen:size_t
-> m:lbuffer uint8 mlen // plaintext
-> ctx:Poly.poly1305_ctx w
-> block:lbuffer uint8 16ul ->
Stack unit
(requires fun h ->
live h k /\ live h aad /\ live h m /\ live h ctx /\ live h block /\
disjoint ctx k /\ disjoint ctx aad /\ disjoint ctx m /\ disjoint ctx block /\
disjoint block k /\ disjoint block aad /\ disjoint block m)
(ensures fun h0 _ h1 ->
modifies (loc ctx |+| loc block) h0 h1 /\
(let acc, r = SpecPoly.poly1305_init (as_seq h0 k) in
let acc = if (length aad <> 0) then Spec.poly1305_padded r (as_seq h0 aad) acc else acc in
let acc = if (length m <> 0) then Spec.poly1305_padded r (as_seq h0 m) acc else acc in
let block_s = LSeq.concat (BSeq.uint_to_bytes_le #U64 (u64 (length aad)))
(BSeq.uint_to_bytes_le #U64 (u64 (length m))) in
let acc = SpecPoly.poly1305_update1 r 16 block_s acc in
Poly.as_get_acc h1 ctx == acc /\ as_seq h1 block == block_s /\
Poly.state_inv_t h1 ctx))
[@Meta.Attribute.inline_]
let poly1305_do_ #w k aadlen aad mlen m ctx block =
Poly.poly1305_init ctx k;
if (aadlen <> 0ul) then (
poly1305_padded ctx aadlen aad)
else ();
if (mlen <> 0ul) then (
poly1305_padded ctx mlen m)
else ();
let h0 = ST.get () in
update_sub_f h0 block 0ul 8ul
(fun h -> BSeq.uint_to_bytes_le #U64 (to_u64 aadlen))
(fun _ -> uint_to_bytes_le (sub block 0ul 8ul) (to_u64 aadlen));
let h1 = ST.get () in
//assert (LSeq.sub (as_seq h1 block) 0 8 == BSeq.uint_to_bytes_le #U64 (to_u64 aadlen));
Poly.reveal_ctx_inv ctx h0 h1;
update_sub_f h1 block 8ul 8ul
(fun h -> BSeq.uint_to_bytes_le #U64 (to_u64 mlen))
(fun _ -> uint_to_bytes_le (sub block 8ul 8ul) (to_u64 mlen));
let h2 = ST.get () in
//assert (LSeq.sub (as_seq h2 block) 8 8 == BSeq.uint_to_bytes_le #U64 (to_u64 mlen));
LSeq.eq_intro (LSeq.sub (as_seq h2 block) 0 8) (BSeq.uint_to_bytes_le #U64 (to_u64 aadlen));
LSeq.lemma_concat2 8 (BSeq.uint_to_bytes_le #U64 (to_u64 aadlen)) 8 (BSeq.uint_to_bytes_le #U64 (to_u64 mlen)) (as_seq h2 block);
//assert (as_seq h2 block == LSeq.concat (BSeq.uint_to_bytes_le #U64 (to_u64 aadlen)) (BSeq.uint_to_bytes_le #U64 (to_u64 mlen)));
Poly.reveal_ctx_inv ctx h1 h2;
Poly.poly1305_update1 ctx block
// Implements the actual poly1305_do operation
inline_for_extraction noextract
let poly1305_do_core_st (w:field_spec) =
k:lbuffer uint8 32ul // key
-> aadlen:size_t
-> aad:lbuffer uint8 aadlen // authenticated additional data
-> mlen:size_t
-> m:lbuffer uint8 mlen // plaintext
-> out:lbuffer uint8 16ul -> // output: tag
Stack unit
(requires fun h ->
live h k /\ live h aad /\ live h m /\ live h out /\
disjoint k out)
(ensures fun h0 _ h1 ->
modifies (loc out) h0 h1 /\
as_seq h1 out == Spec.poly1305_do (as_seq h0 k) (as_seq h0 m) (as_seq h0 aad))
noextract
val poly1305_do: #w:field_spec -> poly1305_do_core_st w
[@Meta.Attribute.specialize]
let poly1305_do #w k aadlen aad mlen m out =
push_frame();
let ctx = create (nlimb w +! precomplen w) (limb_zero w) in
let block = create 16ul (u8 0) in
poly1305_do_ #w k aadlen aad mlen m ctx block;
Poly.poly1305_finish out k ctx;
pop_frame()
unfold noextract
let width_chacha20 (s:field_spec) : Hacl.Spec.Chacha20.Vec.lanes =
match s with
| M32 -> 1
| M128 -> 4
| M256 -> 8
[@ Meta.Attribute.specialize ]
assume val chacha20_encrypt: #w:field_spec ->
Hacl.Impl.Chacha20.Vec.chacha20_encrypt_st (width_chacha20 w)
// Derives the key, and then perform poly1305
val derive_key_poly1305_do:
#w:field_spec
-> k:lbuffer uint8 32ul
-> n:lbuffer uint8 12ul
-> aadlen:size_t
-> aad:lbuffer uint8 aadlen
-> mlen:size_t
-> m:lbuffer uint8 mlen
-> out:lbuffer uint8 16ul ->
Stack unit
(requires fun h ->
live h k /\ live h n /\ live h aad /\ live h m /\ live h out)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
(let key:LSeq.lseq uint8 64 = Spec.Chacha20.chacha20_encrypt_bytes (as_seq h0 k) (as_seq h0 n) 0 (LSeq.create 64 (u8 0)) in
as_seq h1 out == Spec.poly1305_do (LSeq.sub key 0 32) (as_seq h0 m) (as_seq h0 aad)))
[@ Meta.Attribute.inline_ ]
let derive_key_poly1305_do #w k n aadlen aad mlen m out =
push_frame ();
// Create a new buffer to derive the key
let tmp = create 64ul (u8 0) in
chacha20_encrypt #w 64ul tmp tmp k n 0ul;
// The derived key should only be the first 32 bytes
let key = sub tmp 0ul 32ul in
poly1305_do #w key aadlen aad mlen m out;
pop_frame()
inline_for_extraction noextract
let aead_encrypt_st (w:field_spec) =
output:buffer uint8
-> tag:lbuffer uint8 16ul
-> input:buffer uint8
-> input_len:size_t { length input = v input_len /\ length output = v input_len }
-> data:buffer uint8
-> data_len:size_t { length data = v data_len }
-> key:lbuffer uint8 32ul
-> nonce:lbuffer uint8 12ul ->
Stack unit
(requires fun h ->
live h key /\ live h nonce /\ live h data /\
live h input /\ live h output /\ live h tag /\
disjoint key output /\ disjoint nonce output /\
disjoint key tag /\ disjoint nonce tag /\
disjoint output tag /\
eq_or_disjoint (input <: lbuffer uint8 input_len) (output <: lbuffer uint8 input_len) /\
disjoint data output)
(ensures fun h0 _ h1 -> modifies2 output tag h0 h1 /\
Seq.append (as_seq h1 (output <: lbuffer uint8 input_len)) (as_seq h1 tag) ==
Spec.aead_encrypt (as_seq h0 key) (as_seq h0 nonce) (as_seq h0 (input <: lbuffer uint8 input_len)) (as_seq h0 (data <: lbuffer uint8 data_len)))
noextract
val aead_encrypt: #w:field_spec -> aead_encrypt_st w
[@ Meta.Attribute.specialize ]
let aead_encrypt #w output tag input input_len data data_len key nonce =
chacha20_encrypt #w input_len output input key nonce 1ul;
derive_key_poly1305_do #w key nonce data_len data input_len output tag
inline_for_extraction noextract
let aead_decrypt_st (w:field_spec) =
output:buffer uint8
-> input:buffer uint8
-> input_len:size_t { length input = v input_len /\ length output = v input_len }
-> data:buffer uint8
-> data_len:size_t { length data = v data_len }
-> key:lbuffer uint8 32ul
-> nonce:lbuffer uint8 12ul
-> tag:lbuffer uint8 16ul ->
Stack UInt32.t
(requires fun h ->
live h key /\ live h nonce /\ live h (data <: lbuffer uint8 data_len) /\
live h input /\ live h output /\ live h tag /\
eq_or_disjoint (input <: lbuffer uint8 input_len) (output <: lbuffer uint8 input_len))
(ensures fun h0 z h1 -> modifies1 output h0 h1 /\
(let plain = Spec.aead_decrypt (as_seq h0 key) (as_seq h0 nonce) (as_seq h0 (input <: lbuffer uint8 input_len)) (as_seq h0 tag) (as_seq h0 (data <: lbuffer uint8 data_len)) in
match z with
| 0ul -> Some? plain /\ as_seq h1 (output <: lbuffer uint8 input_len) == Some?.v plain // decryption succeeded
| 1ul -> None? plain
| _ -> false) // decryption failed
)
noextract
val aead_decrypt: #w:field_spec -> aead_decrypt_st w | {
"checked_file": "/",
"dependencies": [
"Spec.Poly1305.fst.checked",
"Spec.Chacha20Poly1305.fst.checked",
"Spec.Chacha20.fst.checked",
"prims.fst.checked",
"Meta.Attribute.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.ByteSequence.fsti.checked",
"Lib.ByteBuffer.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Spec.Chacha20.Vec.fst.checked",
"Hacl.Impl.Poly1305.Fields.fst.checked",
"Hacl.Impl.Poly1305.fsti.checked",
"Hacl.Impl.Chacha20Poly1305.PolyCore.fst.checked",
"Hacl.Impl.Chacha20.Vec.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.Chacha20Poly1305.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Poly1305",
"short_module": "Poly"
},
{
"abbrev": true,
"full_module": "Spec.Poly1305",
"short_module": "SpecPoly"
},
{
"abbrev": true,
"full_module": "Spec.Chacha20Poly1305",
"short_module": "Spec"
},
{
"abbrev": true,
"full_module": "Lib.ByteSequence",
"short_module": "BSeq"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Poly1305.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Chacha20Poly1305.PolyCore",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.ByteBuffer",
"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",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl",
"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": 150,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Impl.Chacha20Poly1305.aead_decrypt_st w | Prims.Tot | [
"total"
] | [] | [
"Hacl.Impl.Poly1305.Fields.field_spec",
"Lib.Buffer.buffer",
"Lib.IntTypes.uint8",
"Lib.IntTypes.size_t",
"Prims.l_and",
"Prims.b2t",
"Prims.op_Equality",
"Prims.int",
"Prims.l_or",
"Prims.op_GreaterThanOrEqual",
"Lib.IntTypes.range",
"Lib.IntTypes.U32",
"Lib.Buffer.length",
"Lib.Buffer.MUT",
"Lib.IntTypes.v",
"Lib.IntTypes.PUB",
"Lib.Buffer.lbuffer",
"FStar.UInt32.__uint_to_t",
"FStar.UInt32.t",
"Prims.unit",
"FStar.HyperStack.ST.pop_frame",
"Hacl.Impl.Chacha20Poly1305.chacha20_encrypt",
"Prims._assert",
"Lib.ByteSequence.lbytes_eq",
"Lib.Buffer.as_seq",
"Prims.bool",
"Lib.ByteBuffer.lbytes_eq",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"Hacl.Impl.Chacha20Poly1305.derive_key_poly1305_do",
"Lib.Buffer.lbuffer_t",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"FStar.UInt32.uint_to_t",
"Lib.Buffer.create",
"Lib.IntTypes.u8",
"FStar.HyperStack.ST.push_frame"
] | [] | false | false | false | false | false | let aead_decrypt #w output input input_len data data_len key nonce tag =
| push_frame ();
let h0 = ST.get () in
let computed_tag = create 16ul (u8 0) in
derive_key_poly1305_do #w key nonce data_len data input_len input computed_tag;
let h1 = ST.get () in
let res =
if lbytes_eq computed_tag tag
then
(assert (BSeq.lbytes_eq (as_seq h1 computed_tag) (as_seq h1 tag));
chacha20_encrypt #w input_len output input key nonce 1ul;
0ul)
else 1ul
in
pop_frame ();
res | false |
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.point_add_and_double | val point_add_and_double : Hacl.Meta.Curve25519.addanddouble_point_add_and_double_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 102,
"end_line": 14,
"start_col": 0,
"start_line": 13
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.addanddouble_point_add_and_double_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.addanddouble_point_add_and_double_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Impl.Curve25519.Field64.Vale.fmul",
"Hacl.Impl.Curve25519.Field64.Vale.fsqr2",
"Hacl.Impl.Curve25519.Field64.Vale.fmul_scalar",
"Hacl.Impl.Curve25519.Field64.Vale.fmul2",
"Hacl.Impl.Curve25519.Field64.Vale.fsub",
"Hacl.Impl.Curve25519.Field64.Vale.fadd"
] | [] | false | false | false | true | false | let point_add_and_double =
| addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.finv | val finv : Hacl.Meta.Curve25519.finv_finv_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 57,
"end_line": 20,
"start_col": 0,
"start_line": 20
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.finv_finv_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.finv_finv_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Impl.Curve25519.Field64.Vale.fmul",
"Hacl.Curve25519_64.fsquare_times"
] | [] | false | false | false | true | false | let finv =
| finv_finv_higher #M64 C.p C.fmul fsquare_times | false |
|
Hacl.Impl.P256.Qinv.fst | Hacl.Impl.P256.Qinv.qinv_x210_x240 | val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111)) | val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111)) | let qinv_x210_x240 x210 x_11 x_101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x210 == // x215
S.qmul (SI.qsquare_times (qmont_as_nat h0 x210) 5) (qmont_as_nat h0 x_101));
qsquare_times_in_place x210 3ul;
qmul x210 x210 x_11;
let h2 = ST.get () in
assert (qmont_as_nat h2 x210 == // x218
S.qmul (SI.qsquare_times (qmont_as_nat h1 x210) 3) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 10ul;
qmul x210 x210 x_101111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x210 == // x228
S.qmul (SI.qsquare_times (qmont_as_nat h2 x210) 10) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x210 2ul;
qmul x210 x210 x_11;
let h4 = ST.get () in
assert (qmont_as_nat h4 x210 == // x230
S.qmul (SI.qsquare_times (qmont_as_nat h3 x210) 2) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h5 = ST.get () in
assert (qmont_as_nat h5 x210 == // x235
S.qmul (SI.qsquare_times (qmont_as_nat h4 x210) 5) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h6 = ST.get () in
assert (qmont_as_nat h6 x210 == // x240
S.qmul (SI.qsquare_times (qmont_as_nat h5 x210) 5) (qmont_as_nat h0 x_11)) | {
"file_name": "code/ecdsap256/Hacl.Impl.P256.Qinv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 78,
"end_line": 346,
"start_col": 0,
"start_line": 310
} | module Hacl.Impl.P256.Qinv
open FStar.Mul
open FStar.HyperStack.All
open FStar.HyperStack
module ST = FStar.HyperStack.ST
open Lib.IntTypes
open Lib.Buffer
open Hacl.Impl.P256.Bignum
open Hacl.Impl.P256.Scalar
module SE = Spec.Exponentiation
module BE = Hacl.Impl.Exponentiation
module BD = Hacl.Spec.Bignum.Definitions
module LSeq = Lib.Sequence
module S = Spec.P256
module SI = Hacl.Spec.P256.Qinv
module SM = Hacl.Spec.P256.Montgomery
#reset-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let linv (a:LSeq.lseq uint64 4) : Type0 =
BD.bn_v a < S.order
unfold
let refl (a:LSeq.lseq uint64 4{linv a}) : GTot S.qelem =
SM.from_qmont (BD.bn_v a)
inline_for_extraction noextract
let mk_to_p256_order_comm_monoid : BE.to_comm_monoid U64 4ul 0ul = {
BE.a_spec = S.qelem;
BE.comm_monoid = SI.nat_mod_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = linv;
BE.refl = refl;
}
inline_for_extraction noextract
val one_mod : BE.lone_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let one_mod ctx one = make_qone one
inline_for_extraction noextract
val mul_mod : BE.lmul_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let mul_mod ctx x y xy = qmul xy x y
inline_for_extraction noextract
val sqr_mod : BE.lsqr_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let sqr_mod ctx x xx = qsqr xx x
inline_for_extraction noextract
let mk_p256_order_concrete_ops : BE.concrete_ops U64 4ul 0ul = {
BE.to = mk_to_p256_order_comm_monoid;
BE.lone = one_mod;
BE.lmul = mul_mod;
BE.lsqr = sqr_mod;
}
inline_for_extraction noextract
val qsquare_times_in_place (out:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ as_nat h out < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 out) (v b))
let qsquare_times_in_place out b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 out) (v b);
BE.lexp_pow2_in_place 4ul 0ul mk_p256_order_concrete_ops (null uint64) out b
inline_for_extraction noextract
val qsquare_times (out a:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ live h a /\ disjoint out a /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 a) (v b))
let qsquare_times out a b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 a) (v b);
BE.lexp_pow2 4ul 0ul mk_p256_order_concrete_ops (null uint64) a b out
// x6 can be modified
// x_11 cannot be modified
inline_for_extraction noextract
val qinv_x8_x128 (x128 x6 x_11:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x6 /\ live h x_11 /\
disjoint x128 x6 /\ disjoint x128 x_11 /\ disjoint x6 x_11 /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128 |+| loc x6) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x8_x128 (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11))
let qinv_x8_x128 x128 x6 x_11 =
let h0 = ST.get () in
qsquare_times_in_place x6 2ul;
qmul x6 x6 x_11;
let h1 = ST.get () in
assert (qmont_as_nat h1 x6 == // x8
S.qmul (SI.qsquare_times (qmont_as_nat h0 x6) 2) (qmont_as_nat h0 x_11));
qsquare_times x128 x6 8ul;
qmul x128 x128 x6;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x16
S.qmul (SI.qsquare_times (qmont_as_nat h1 x6) 8) (qmont_as_nat h1 x6));
qsquare_times x6 x128 16ul;
qmul x6 x6 x128;
let h3 = ST.get () in
assert (qmont_as_nat h3 x6 == // x32
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 16) (qmont_as_nat h2 x128));
qsquare_times x128 x6 64ul;
qmul x128 x128 x6;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x96
S.qmul (SI.qsquare_times (qmont_as_nat h3 x6) 64) (qmont_as_nat h3 x6));
qsquare_times_in_place x128 32ul;
qmul x128 x128 x6;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x128
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 32) (qmont_as_nat h3 x6))
// x128 can be modified
inline_for_extraction noextract
val qinv_x134_x153 (x128 x_11 x_111 x_1111 x_10101 x_101111:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x_11 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\
disjoint x128 x_11 /\ disjoint x128 x_111 /\ disjoint x128 x_1111 /\
disjoint x128 x_10101 /\ disjoint x128 x_101111 /\
as_nat h x128 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x134_x153
(qmont_as_nat h0 x128) (qmont_as_nat h0 x_11) (qmont_as_nat h0 x_111)
(qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x134_x153 x128 x_11 x_111 x_1111 x_10101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x128 6ul;
qmul x128 x128 x_101111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x128 == // x134
S.qmul (SI.qsquare_times (qmont_as_nat h0 x128) 6) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_111;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x139
S.qmul (SI.qsquare_times (qmont_as_nat h1 x128) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x128 4ul;
qmul x128 x128 x_11;
let h3 = ST.get () in
assert (qmont_as_nat h3 x128 == // x143
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 4) (qmont_as_nat h0 x_11));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x148
S.qmul (SI.qsquare_times (qmont_as_nat h3 x128) 5) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_10101;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x153
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 5) (qmont_as_nat h0 x_10101))
// x153 can be modified
inline_for_extraction noextract
val qinv_x153_x177 (x153 x_101 x_111 x_101111:felem) : Stack unit
(requires fun h ->
live h x153 /\ live h x_101 /\ live h x_111 /\ live h x_101111 /\
disjoint x153 x_101 /\ disjoint x153 x_111 /\ disjoint x153 x_101111 /\
as_nat h x153 < S.order /\ as_nat h x_101 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x153) h0 h1 /\
as_nat h1 x153 < S.order /\
qmont_as_nat h1 x153 = SI.qinv_x153_x177 (qmont_as_nat h0 x153)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_101111))
let qinv_x153_x177 x153 x_101 x_111 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x153 4ul;
qmul x153 x153 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x153 == // x157
S.qmul (SI.qsquare_times (qmont_as_nat h0 x153) 4) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x153 == // x160
S.qmul (SI.qsquare_times (qmont_as_nat h1 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h3 = ST.get () in
assert (qmont_as_nat h3 x153 == // x163
S.qmul (SI.qsquare_times (qmont_as_nat h2 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 5ul;
qmul x153 x153 x_111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x153 == // x168
S.qmul (SI.qsquare_times (qmont_as_nat h3 x153) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x153 9ul;
qmul x153 x153 x_101111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x153 == // x177
S.qmul (SI.qsquare_times (qmont_as_nat h4 x153) 9) (qmont_as_nat h0 x_101111))
// x153 can be modified
inline_for_extraction noextract
val qinv_x177_x210 (x177 x_111 x_1111 a:felem) : Stack unit
(requires fun h ->
live h x177 /\ live h x_111 /\ live h x_1111 /\ live h a /\
disjoint x177 x_111 /\ disjoint x177 x_1111 /\ disjoint x177 a /\
as_nat h x177 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x177) h0 h1 /\
as_nat h1 x177 < S.order /\
qmont_as_nat h1 x177 = SI.qinv_x177_x210 (qmont_as_nat h0 a)
(qmont_as_nat h0 x177) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111))
let qinv_x177_x210 x177 x_111 x_1111 a =
let h0 = ST.get () in
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x177 == // x183
S.qmul (SI.qsquare_times (qmont_as_nat h0 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 2ul;
qmul x177 x177 a;
let h2 = ST.get () in
assert (qmont_as_nat h2 x177 == // x185
S.qmul (SI.qsquare_times (qmont_as_nat h1 x177) 2) (qmont_as_nat h0 a));
qsquare_times_in_place x177 5ul;
qmul x177 x177 a;
let h3 = ST.get () in
assert (qmont_as_nat h3 x177 == // x190
S.qmul (SI.qsquare_times (qmont_as_nat h2 x177) 5) (qmont_as_nat h0 a));
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x177 == // x196
S.qmul (SI.qsquare_times (qmont_as_nat h3 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x177 == // x201
S.qmul (SI.qsquare_times (qmont_as_nat h4 x177) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 4ul;
qmul x177 x177 x_111;
let h6 = ST.get () in
assert (qmont_as_nat h6 x177 == // x205
S.qmul (SI.qsquare_times (qmont_as_nat h5 x177) 4) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h7 = ST.get () in
assert (qmont_as_nat h7 x177 == // x210
S.qmul (SI.qsquare_times (qmont_as_nat h6 x177) 5) (qmont_as_nat h0 x_111))
inline_for_extraction noextract
val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111)) | {
"checked_file": "/",
"dependencies": [
"Spec.P256.fst.checked",
"Spec.Exponentiation.fsti.checked",
"prims.fst.checked",
"LowStar.Monotonic.Buffer.fsti.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Spec.P256.Qinv.fst.checked",
"Hacl.Spec.P256.Montgomery.fsti.checked",
"Hacl.Spec.Bignum.Definitions.fst.checked",
"Hacl.Impl.P256.Scalar.fsti.checked",
"Hacl.Impl.P256.Bignum.fsti.checked",
"Hacl.Impl.Exponentiation.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": true,
"source_file": "Hacl.Impl.P256.Qinv.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Montgomery",
"short_module": "SM"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Qinv",
"short_module": "SI"
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.Bignum.Definitions",
"short_module": "BD"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Spec.Exponentiation",
"short_module": "SE"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"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 |
x210: Hacl.Impl.P256.Bignum.felem ->
x_11: Hacl.Impl.P256.Bignum.felem ->
x_101: Hacl.Impl.P256.Bignum.felem ->
x_101111: Hacl.Impl.P256.Bignum.felem
-> FStar.HyperStack.ST.Stack Prims.unit | FStar.HyperStack.ST.Stack | [] | [] | [
"Hacl.Impl.P256.Bignum.felem",
"Prims._assert",
"Prims.eq2",
"Spec.P256.PointOps.qelem",
"Hacl.Impl.P256.Scalar.qmont_as_nat",
"Spec.P256.PointOps.qmul",
"Hacl.Spec.P256.Qinv.qsquare_times",
"Prims.unit",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"Hacl.Impl.P256.Scalar.qmul",
"Hacl.Impl.P256.Qinv.qsquare_times_in_place",
"FStar.UInt32.__uint_to_t"
] | [] | false | true | false | false | false | let qinv_x210_x240 x210 x_11 x_101 x_101111 =
| let h0 = ST.get () in
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h0 x210) 5) (qmont_as_nat h0 x_101));
qsquare_times_in_place x210 3ul;
qmul x210 x210 x_11;
let h2 = ST.get () in
assert (qmont_as_nat h2 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h1 x210) 3) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 10ul;
qmul x210 x210 x_101111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h2 x210) 10) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x210 2ul;
qmul x210 x210 x_11;
let h4 = ST.get () in
assert (qmont_as_nat h4 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h3 x210) 2) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h5 = ST.get () in
assert (qmont_as_nat h5 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h4 x210) 5) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h6 = ST.get () in
assert (qmont_as_nat h6 x210 ==
S.qmul (SI.qsquare_times (qmont_as_nat h5 x210) 5) (qmont_as_nat h0 x_11)) | false |
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.store_felem | val store_felem : Hacl.Meta.Curve25519.fields_store_felem_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let store_felem = fields_store_felem_higher #M64 C.p C.add_scalar | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 65,
"end_line": 24,
"start_col": 0,
"start_line": 24
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double
let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr
let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times
// Note that here, for implementations of Curve64, we have a generic store_felem
// over an *implementation* of add1. (For Curve51, store_felem does not have | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.fields_store_felem_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.fields_store_felem_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Impl.Curve25519.Field64.Vale.add_scalar"
] | [] | false | false | false | true | false | let store_felem =
| fields_store_felem_higher #M64 C.p C.add_scalar | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.point_double | val point_double : Hacl.Meta.Curve25519.addanddouble_point_double_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 87,
"end_line": 16,
"start_col": 0,
"start_line": 15
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double = | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.addanddouble_point_double_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.addanddouble_point_double_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Impl.Curve25519.Field64.Vale.fmul2",
"Hacl.Impl.Curve25519.Field64.Vale.fmul_scalar",
"Hacl.Impl.Curve25519.Field64.Vale.fsqr2",
"Hacl.Impl.Curve25519.Field64.Vale.fsub",
"Hacl.Impl.Curve25519.Field64.Vale.fadd"
] | [] | false | false | false | true | false | let point_double =
| addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.fsquare_times | val fsquare_times : Hacl.Meta.Curve25519.finv_fsquare_times_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 61,
"end_line": 19,
"start_col": 0,
"start_line": 19
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder = | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.finv_fsquare_times_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.finv_fsquare_times_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Impl.Curve25519.Field64.Vale.fsqr"
] | [] | false | false | false | true | false | let fsquare_times =
| finv_fsquare_times_higher #M64 C.p C.fsqr | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.montgomery_ladder | val montgomery_ladder : Hacl.Meta.Curve25519.generic_montgomery_ladder_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 86,
"end_line": 18,
"start_col": 0,
"start_line": 17
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double = | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.generic_montgomery_ladder_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.generic_montgomery_ladder_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Curve25519_64.point_double",
"Hacl.Impl.Curve25519.Field64.Vale.cswap2",
"Hacl.Curve25519_64.point_add_and_double"
] | [] | false | false | false | true | false | let montgomery_ladder =
| generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.scalarmult | val scalarmult: scalarmult_st M64 p | val scalarmult: scalarmult_st M64 p | let scalarmult = generic_scalarmult_higher #M64 C.p encode_point montgomery_ladder decode_point | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 95,
"end_line": 26,
"start_col": 0,
"start_line": 26
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double
let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr
let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times
// Note that here, for implementations of Curve64, we have a generic store_felem
// over an *implementation* of add1. (For Curve51, store_felem does not have
// that generic aspect.)
let store_felem = fields_store_felem_higher #M64 C.p C.add_scalar | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Impl.Curve25519.Generic.scalarmult_st Hacl.Impl.Curve25519.Fields.Core.M64 Hacl.Curve25519_64.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.generic_scalarmult_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Curve25519_64.encode_point",
"Hacl.Curve25519_64.montgomery_ladder",
"Hacl.Impl.Curve25519.Generic.decode_point"
] | [] | false | false | false | true | false | let scalarmult =
| generic_scalarmult_higher #M64 C.p encode_point montgomery_ladder decode_point | false |
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.encode_point | val encode_point : Hacl.Meta.Curve25519.generic_encode_point_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | let encode_point = generic_encode_point_higher #M64 C.p store_felem C.fmul finv | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 79,
"end_line": 25,
"start_col": 0,
"start_line": 25
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double
let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr
let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times
// Note that here, for implementations of Curve64, we have a generic store_felem
// over an *implementation* of add1. (For Curve51, store_felem does not have
// that generic aspect.) | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Meta.Curve25519.generic_encode_point_higher_t Hacl.Impl.Curve25519.Field64.Vale.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.generic_encode_point_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Curve25519_64.store_felem",
"Hacl.Impl.Curve25519.Field64.Vale.fmul",
"Hacl.Curve25519_64.finv"
] | [] | false | false | false | true | false | let encode_point =
| generic_encode_point_higher #M64 C.p store_felem C.fmul finv | false |
|
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.ecdh | val ecdh: ecdh_st M64 p | val ecdh: ecdh_st M64 p | let ecdh = generic_ecdh_higher #M64 C.p scalarmult | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 50,
"end_line": 28,
"start_col": 0,
"start_line": 28
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double
let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr
let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times
// Note that here, for implementations of Curve64, we have a generic store_felem
// over an *implementation* of add1. (For Curve51, store_felem does not have
// that generic aspect.)
let store_felem = fields_store_felem_higher #M64 C.p C.add_scalar
let encode_point = generic_encode_point_higher #M64 C.p store_felem C.fmul finv
let scalarmult = generic_scalarmult_higher #M64 C.p encode_point montgomery_ladder decode_point | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Impl.Curve25519.Generic.ecdh_st Hacl.Impl.Curve25519.Fields.Core.M64 Hacl.Curve25519_64.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.generic_ecdh_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Curve25519_64.scalarmult"
] | [] | false | false | false | true | false | let ecdh =
| generic_ecdh_higher #M64 C.p scalarmult | false |
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.secret_to_public | val secret_to_public: secret_to_public_st M64 p | val secret_to_public: secret_to_public_st M64 p | let secret_to_public = generic_secret_to_public_higher #M64 C.p scalarmult g25519 | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 81,
"end_line": 27,
"start_col": 0,
"start_line": 27
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale
let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list
#set-options "--max_fuel 0 --max_ifuel 0 --z3rlimit 100"
let point_add_and_double =
addanddouble_point_add_and_double_higher #M64 C.p C.fmul C.fsqr2 C.fmul_scalar C.fmul2 C.fsub C.fadd
let point_double =
addanddouble_point_double_higher #M64 C.p C.fmul2 C.fmul_scalar C.fsqr2 C.fsub C.fadd
let montgomery_ladder =
generic_montgomery_ladder_higher #M64 C.p point_double C.cswap2 point_add_and_double
let fsquare_times = finv_fsquare_times_higher #M64 C.p C.fsqr
let finv = finv_finv_higher #M64 C.p C.fmul fsquare_times
// Note that here, for implementations of Curve64, we have a generic store_felem
// over an *implementation* of add1. (For Curve51, store_felem does not have
// that generic aspect.)
let store_felem = fields_store_felem_higher #M64 C.p C.add_scalar
let encode_point = generic_encode_point_higher #M64 C.p store_felem C.fmul finv | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Impl.Curve25519.Generic.secret_to_public_st Hacl.Impl.Curve25519.Fields.Core.M64
Hacl.Curve25519_64.p | Prims.Tot | [
"total"
] | [] | [
"Hacl.Meta.Curve25519.generic_secret_to_public_higher",
"Hacl.Impl.Curve25519.Fields.Core.M64",
"Hacl.Impl.Curve25519.Field64.Vale.p",
"Hacl.Curve25519_64.scalarmult",
"Hacl.Curve25519_64.g25519"
] | [] | false | false | false | true | false | let secret_to_public =
| generic_secret_to_public_higher #M64 C.p scalarmult g25519 | false |
Hacl.Impl.P256.Qinv.fst | Hacl.Impl.P256.Qinv.qinv_make_x | val qinv_make_x (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
LowStar.Monotonic.Buffer.all_disjoint
[ loc x6; loc x_11; loc x_101; loc x_111; loc x_1111; loc x_10101; loc x_101111; loc a ] /\
as_nat h a < S.order)
(ensures fun h0 _ h1 ->
modifies (loc x6 |+| loc x_11 |+| loc x_101 |+| loc x_111 |+|
loc x_1111 |+| loc x_10101 |+| loc x_101111) h0 h1 /\
as_nat h1 x6 < S.order /\ as_nat h1 x_11 < S.order /\
as_nat h1 x_101 < S.order /\ as_nat h1 x_111 < S.order /\
as_nat h1 x_1111 < S.order /\ as_nat h1 x_10101 < S.order /\
as_nat h1 x_101111 < S.order /\
(let f = qmont_as_nat h0 a in
let x_10_s = SI.qsquare_times f 1 in // x_10 is used 3x
let x_11_s = S.qmul x_10_s f in
let x_101_s = S.qmul x_10_s x_11_s in
let x_111_s = S.qmul x_10_s x_101_s in
let x_1010_s = SI.qsquare_times x_101_s 1 in // x_1010 is used 2x
let x_1111_s = S.qmul x_101_s x_1010_s in
let x_10101_s = S.qmul (SI.qsquare_times x_1010_s 1) f in
let x_101010_s = SI.qsquare_times x_10101_s 1 in // x_101010 is used 2x
let x_101111_s = S.qmul x_101_s x_101010_s in
let x6_s = S.qmul x_10101_s x_101010_s in
qmont_as_nat h1 x6 = x6_s /\ qmont_as_nat h1 x_11 = x_11_s /\
qmont_as_nat h1 x_101 = x_101_s /\ qmont_as_nat h1 x_111 = x_111_s /\
qmont_as_nat h1 x_1111 = x_1111_s /\ qmont_as_nat h1 x_10101 = x_10101_s /\
qmont_as_nat h1 x_101111 = x_101111_s)) | val qinv_make_x (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
LowStar.Monotonic.Buffer.all_disjoint
[ loc x6; loc x_11; loc x_101; loc x_111; loc x_1111; loc x_10101; loc x_101111; loc a ] /\
as_nat h a < S.order)
(ensures fun h0 _ h1 ->
modifies (loc x6 |+| loc x_11 |+| loc x_101 |+| loc x_111 |+|
loc x_1111 |+| loc x_10101 |+| loc x_101111) h0 h1 /\
as_nat h1 x6 < S.order /\ as_nat h1 x_11 < S.order /\
as_nat h1 x_101 < S.order /\ as_nat h1 x_111 < S.order /\
as_nat h1 x_1111 < S.order /\ as_nat h1 x_10101 < S.order /\
as_nat h1 x_101111 < S.order /\
(let f = qmont_as_nat h0 a in
let x_10_s = SI.qsquare_times f 1 in // x_10 is used 3x
let x_11_s = S.qmul x_10_s f in
let x_101_s = S.qmul x_10_s x_11_s in
let x_111_s = S.qmul x_10_s x_101_s in
let x_1010_s = SI.qsquare_times x_101_s 1 in // x_1010 is used 2x
let x_1111_s = S.qmul x_101_s x_1010_s in
let x_10101_s = S.qmul (SI.qsquare_times x_1010_s 1) f in
let x_101010_s = SI.qsquare_times x_10101_s 1 in // x_101010 is used 2x
let x_101111_s = S.qmul x_101_s x_101010_s in
let x6_s = S.qmul x_10101_s x_101010_s in
qmont_as_nat h1 x6 = x6_s /\ qmont_as_nat h1 x_11 = x_11_s /\
qmont_as_nat h1 x_101 = x_101_s /\ qmont_as_nat h1 x_111 = x_111_s /\
qmont_as_nat h1 x_1111 = x_1111_s /\ qmont_as_nat h1 x_10101 = x_10101_s /\
qmont_as_nat h1 x_101111 = x_101111_s)) | let qinv_make_x x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
qsquare_times x6 a 1ul; // x_10
qmul x_11 x6 a;
qmul x_101 x6 x_11;
qmul x_111 x6 x_101;
qsquare_times x6 x_101 1ul; // x_1010
qmul x_1111 x_101 x6;
qsquare_times_in_place x6 1ul;
qmul x_10101 x6 a;
qsquare_times x6 x_10101 1ul; // x_101010
qmul x_101111 x_101 x6;
qmul x6 x_10101 x6 | {
"file_name": "code/ecdsap256/Hacl.Impl.P256.Qinv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 20,
"end_line": 461,
"start_col": 0,
"start_line": 448
} | module Hacl.Impl.P256.Qinv
open FStar.Mul
open FStar.HyperStack.All
open FStar.HyperStack
module ST = FStar.HyperStack.ST
open Lib.IntTypes
open Lib.Buffer
open Hacl.Impl.P256.Bignum
open Hacl.Impl.P256.Scalar
module SE = Spec.Exponentiation
module BE = Hacl.Impl.Exponentiation
module BD = Hacl.Spec.Bignum.Definitions
module LSeq = Lib.Sequence
module S = Spec.P256
module SI = Hacl.Spec.P256.Qinv
module SM = Hacl.Spec.P256.Montgomery
#reset-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let linv (a:LSeq.lseq uint64 4) : Type0 =
BD.bn_v a < S.order
unfold
let refl (a:LSeq.lseq uint64 4{linv a}) : GTot S.qelem =
SM.from_qmont (BD.bn_v a)
inline_for_extraction noextract
let mk_to_p256_order_comm_monoid : BE.to_comm_monoid U64 4ul 0ul = {
BE.a_spec = S.qelem;
BE.comm_monoid = SI.nat_mod_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = linv;
BE.refl = refl;
}
inline_for_extraction noextract
val one_mod : BE.lone_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let one_mod ctx one = make_qone one
inline_for_extraction noextract
val mul_mod : BE.lmul_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let mul_mod ctx x y xy = qmul xy x y
inline_for_extraction noextract
val sqr_mod : BE.lsqr_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let sqr_mod ctx x xx = qsqr xx x
inline_for_extraction noextract
let mk_p256_order_concrete_ops : BE.concrete_ops U64 4ul 0ul = {
BE.to = mk_to_p256_order_comm_monoid;
BE.lone = one_mod;
BE.lmul = mul_mod;
BE.lsqr = sqr_mod;
}
inline_for_extraction noextract
val qsquare_times_in_place (out:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ as_nat h out < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 out) (v b))
let qsquare_times_in_place out b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 out) (v b);
BE.lexp_pow2_in_place 4ul 0ul mk_p256_order_concrete_ops (null uint64) out b
inline_for_extraction noextract
val qsquare_times (out a:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ live h a /\ disjoint out a /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 a) (v b))
let qsquare_times out a b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 a) (v b);
BE.lexp_pow2 4ul 0ul mk_p256_order_concrete_ops (null uint64) a b out
// x6 can be modified
// x_11 cannot be modified
inline_for_extraction noextract
val qinv_x8_x128 (x128 x6 x_11:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x6 /\ live h x_11 /\
disjoint x128 x6 /\ disjoint x128 x_11 /\ disjoint x6 x_11 /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128 |+| loc x6) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x8_x128 (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11))
let qinv_x8_x128 x128 x6 x_11 =
let h0 = ST.get () in
qsquare_times_in_place x6 2ul;
qmul x6 x6 x_11;
let h1 = ST.get () in
assert (qmont_as_nat h1 x6 == // x8
S.qmul (SI.qsquare_times (qmont_as_nat h0 x6) 2) (qmont_as_nat h0 x_11));
qsquare_times x128 x6 8ul;
qmul x128 x128 x6;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x16
S.qmul (SI.qsquare_times (qmont_as_nat h1 x6) 8) (qmont_as_nat h1 x6));
qsquare_times x6 x128 16ul;
qmul x6 x6 x128;
let h3 = ST.get () in
assert (qmont_as_nat h3 x6 == // x32
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 16) (qmont_as_nat h2 x128));
qsquare_times x128 x6 64ul;
qmul x128 x128 x6;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x96
S.qmul (SI.qsquare_times (qmont_as_nat h3 x6) 64) (qmont_as_nat h3 x6));
qsquare_times_in_place x128 32ul;
qmul x128 x128 x6;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x128
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 32) (qmont_as_nat h3 x6))
// x128 can be modified
inline_for_extraction noextract
val qinv_x134_x153 (x128 x_11 x_111 x_1111 x_10101 x_101111:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x_11 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\
disjoint x128 x_11 /\ disjoint x128 x_111 /\ disjoint x128 x_1111 /\
disjoint x128 x_10101 /\ disjoint x128 x_101111 /\
as_nat h x128 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x134_x153
(qmont_as_nat h0 x128) (qmont_as_nat h0 x_11) (qmont_as_nat h0 x_111)
(qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x134_x153 x128 x_11 x_111 x_1111 x_10101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x128 6ul;
qmul x128 x128 x_101111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x128 == // x134
S.qmul (SI.qsquare_times (qmont_as_nat h0 x128) 6) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_111;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x139
S.qmul (SI.qsquare_times (qmont_as_nat h1 x128) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x128 4ul;
qmul x128 x128 x_11;
let h3 = ST.get () in
assert (qmont_as_nat h3 x128 == // x143
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 4) (qmont_as_nat h0 x_11));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x148
S.qmul (SI.qsquare_times (qmont_as_nat h3 x128) 5) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_10101;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x153
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 5) (qmont_as_nat h0 x_10101))
// x153 can be modified
inline_for_extraction noextract
val qinv_x153_x177 (x153 x_101 x_111 x_101111:felem) : Stack unit
(requires fun h ->
live h x153 /\ live h x_101 /\ live h x_111 /\ live h x_101111 /\
disjoint x153 x_101 /\ disjoint x153 x_111 /\ disjoint x153 x_101111 /\
as_nat h x153 < S.order /\ as_nat h x_101 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x153) h0 h1 /\
as_nat h1 x153 < S.order /\
qmont_as_nat h1 x153 = SI.qinv_x153_x177 (qmont_as_nat h0 x153)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_101111))
let qinv_x153_x177 x153 x_101 x_111 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x153 4ul;
qmul x153 x153 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x153 == // x157
S.qmul (SI.qsquare_times (qmont_as_nat h0 x153) 4) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x153 == // x160
S.qmul (SI.qsquare_times (qmont_as_nat h1 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h3 = ST.get () in
assert (qmont_as_nat h3 x153 == // x163
S.qmul (SI.qsquare_times (qmont_as_nat h2 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 5ul;
qmul x153 x153 x_111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x153 == // x168
S.qmul (SI.qsquare_times (qmont_as_nat h3 x153) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x153 9ul;
qmul x153 x153 x_101111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x153 == // x177
S.qmul (SI.qsquare_times (qmont_as_nat h4 x153) 9) (qmont_as_nat h0 x_101111))
// x153 can be modified
inline_for_extraction noextract
val qinv_x177_x210 (x177 x_111 x_1111 a:felem) : Stack unit
(requires fun h ->
live h x177 /\ live h x_111 /\ live h x_1111 /\ live h a /\
disjoint x177 x_111 /\ disjoint x177 x_1111 /\ disjoint x177 a /\
as_nat h x177 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x177) h0 h1 /\
as_nat h1 x177 < S.order /\
qmont_as_nat h1 x177 = SI.qinv_x177_x210 (qmont_as_nat h0 a)
(qmont_as_nat h0 x177) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111))
let qinv_x177_x210 x177 x_111 x_1111 a =
let h0 = ST.get () in
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x177 == // x183
S.qmul (SI.qsquare_times (qmont_as_nat h0 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 2ul;
qmul x177 x177 a;
let h2 = ST.get () in
assert (qmont_as_nat h2 x177 == // x185
S.qmul (SI.qsquare_times (qmont_as_nat h1 x177) 2) (qmont_as_nat h0 a));
qsquare_times_in_place x177 5ul;
qmul x177 x177 a;
let h3 = ST.get () in
assert (qmont_as_nat h3 x177 == // x190
S.qmul (SI.qsquare_times (qmont_as_nat h2 x177) 5) (qmont_as_nat h0 a));
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x177 == // x196
S.qmul (SI.qsquare_times (qmont_as_nat h3 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x177 == // x201
S.qmul (SI.qsquare_times (qmont_as_nat h4 x177) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 4ul;
qmul x177 x177 x_111;
let h6 = ST.get () in
assert (qmont_as_nat h6 x177 == // x205
S.qmul (SI.qsquare_times (qmont_as_nat h5 x177) 4) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h7 = ST.get () in
assert (qmont_as_nat h7 x177 == // x210
S.qmul (SI.qsquare_times (qmont_as_nat h6 x177) 5) (qmont_as_nat h0 x_111))
inline_for_extraction noextract
val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111))
let qinv_x210_x240 x210 x_11 x_101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x210 == // x215
S.qmul (SI.qsquare_times (qmont_as_nat h0 x210) 5) (qmont_as_nat h0 x_101));
qsquare_times_in_place x210 3ul;
qmul x210 x210 x_11;
let h2 = ST.get () in
assert (qmont_as_nat h2 x210 == // x218
S.qmul (SI.qsquare_times (qmont_as_nat h1 x210) 3) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 10ul;
qmul x210 x210 x_101111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x210 == // x228
S.qmul (SI.qsquare_times (qmont_as_nat h2 x210) 10) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x210 2ul;
qmul x210 x210 x_11;
let h4 = ST.get () in
assert (qmont_as_nat h4 x210 == // x230
S.qmul (SI.qsquare_times (qmont_as_nat h3 x210) 2) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h5 = ST.get () in
assert (qmont_as_nat h5 x210 == // x235
S.qmul (SI.qsquare_times (qmont_as_nat h4 x210) 5) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h6 = ST.get () in
assert (qmont_as_nat h6 x210 == // x240
S.qmul (SI.qsquare_times (qmont_as_nat h5 x210) 5) (qmont_as_nat h0 x_11))
inline_for_extraction noextract
val qinv_x240_x256 (x240 x_1111 x_10101 a:felem) : Stack unit
(requires fun h ->
live h x240 /\ live h x_1111 /\ live h x_10101 /\ live h a /\
disjoint x240 x_1111 /\ disjoint x240 x_10101 /\ disjoint x240 a /\
as_nat h x240 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x240) h0 h1 /\
as_nat h1 x240 < S.order /\
qmont_as_nat h1 x240 = SI.qinv_x240_x256 (qmont_as_nat h0 a)
(qmont_as_nat h0 x240) (qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101))
let qinv_x240_x256 x240 x_1111 x_10101 a =
let h0 = ST.get () in
qsquare_times_in_place x240 3ul;
qmul x240 x240 a;
let h1 = ST.get () in
assert (qmont_as_nat h1 x240 == // x243
S.qmul (SI.qsquare_times (qmont_as_nat h0 x240) 3) (qmont_as_nat h0 a));
qsquare_times_in_place x240 7ul;
qmul x240 x240 x_10101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x240 == // x250
S.qmul (SI.qsquare_times (qmont_as_nat h1 x240) 7) (qmont_as_nat h0 x_10101));
qsquare_times_in_place x240 6ul;
qmul x240 x240 x_1111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x240 == // x256
S.qmul (SI.qsquare_times (qmont_as_nat h2 x240) 6) (qmont_as_nat h0 x_1111))
// x128 can be modified
inline_for_extraction noextract
val qinv_x8_x256 (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
disjoint x6 x_11 /\ disjoint x6 x_101 /\ disjoint x6 x_111 /\ disjoint x6 x_1111 /\
disjoint x6 x_10101 /\ disjoint x6 x_101111 /\ disjoint x6 a /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h x_10101 < S.order /\
as_nat h x_101111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x6) h0 h1 /\
as_nat h1 x6 < S.order /\
qmont_as_nat h1 x6 = SI.qinv_x8_x256
(qmont_as_nat h0 a) (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111)
(qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
push_frame ();
let tmp = create_felem () in
qinv_x8_x128 tmp x6 x_11;
qinv_x134_x153 tmp x_11 x_111 x_1111 x_10101 x_101111;
qinv_x153_x177 tmp x_101 x_111 x_101111;
qinv_x177_x210 tmp x_111 x_1111 a;
qinv_x210_x240 tmp x_11 x_101 x_101111;
qinv_x240_x256 tmp x_1111 x_10101 a;
copy x6 tmp;
pop_frame ()
// x128 can be modified
inline_for_extraction noextract
val qinv_make_x (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
LowStar.Monotonic.Buffer.all_disjoint
[ loc x6; loc x_11; loc x_101; loc x_111; loc x_1111; loc x_10101; loc x_101111; loc a ] /\
as_nat h a < S.order)
(ensures fun h0 _ h1 ->
modifies (loc x6 |+| loc x_11 |+| loc x_101 |+| loc x_111 |+|
loc x_1111 |+| loc x_10101 |+| loc x_101111) h0 h1 /\
as_nat h1 x6 < S.order /\ as_nat h1 x_11 < S.order /\
as_nat h1 x_101 < S.order /\ as_nat h1 x_111 < S.order /\
as_nat h1 x_1111 < S.order /\ as_nat h1 x_10101 < S.order /\
as_nat h1 x_101111 < S.order /\
(let f = qmont_as_nat h0 a in
let x_10_s = SI.qsquare_times f 1 in // x_10 is used 3x
let x_11_s = S.qmul x_10_s f in
let x_101_s = S.qmul x_10_s x_11_s in
let x_111_s = S.qmul x_10_s x_101_s in
let x_1010_s = SI.qsquare_times x_101_s 1 in // x_1010 is used 2x
let x_1111_s = S.qmul x_101_s x_1010_s in
let x_10101_s = S.qmul (SI.qsquare_times x_1010_s 1) f in
let x_101010_s = SI.qsquare_times x_10101_s 1 in // x_101010 is used 2x
let x_101111_s = S.qmul x_101_s x_101010_s in
let x6_s = S.qmul x_10101_s x_101010_s in
qmont_as_nat h1 x6 = x6_s /\ qmont_as_nat h1 x_11 = x_11_s /\
qmont_as_nat h1 x_101 = x_101_s /\ qmont_as_nat h1 x_111 = x_111_s /\
qmont_as_nat h1 x_1111 = x_1111_s /\ qmont_as_nat h1 x_10101 = x_10101_s /\
qmont_as_nat h1 x_101111 = x_101111_s)) | {
"checked_file": "/",
"dependencies": [
"Spec.P256.fst.checked",
"Spec.Exponentiation.fsti.checked",
"prims.fst.checked",
"LowStar.Monotonic.Buffer.fsti.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Spec.P256.Qinv.fst.checked",
"Hacl.Spec.P256.Montgomery.fsti.checked",
"Hacl.Spec.Bignum.Definitions.fst.checked",
"Hacl.Impl.P256.Scalar.fsti.checked",
"Hacl.Impl.P256.Bignum.fsti.checked",
"Hacl.Impl.Exponentiation.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": true,
"source_file": "Hacl.Impl.P256.Qinv.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Montgomery",
"short_module": "SM"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Qinv",
"short_module": "SI"
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.Bignum.Definitions",
"short_module": "BD"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Spec.Exponentiation",
"short_module": "SE"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"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 |
x6: Hacl.Impl.P256.Bignum.felem ->
x_11: Hacl.Impl.P256.Bignum.felem ->
x_101: Hacl.Impl.P256.Bignum.felem ->
x_111: Hacl.Impl.P256.Bignum.felem ->
x_1111: Hacl.Impl.P256.Bignum.felem ->
x_10101: Hacl.Impl.P256.Bignum.felem ->
x_101111: Hacl.Impl.P256.Bignum.felem ->
a: Hacl.Impl.P256.Bignum.felem
-> FStar.HyperStack.ST.Stack Prims.unit | FStar.HyperStack.ST.Stack | [] | [] | [
"Hacl.Impl.P256.Bignum.felem",
"Hacl.Impl.P256.Scalar.qmul",
"Prims.unit",
"Hacl.Impl.P256.Qinv.qsquare_times",
"FStar.UInt32.__uint_to_t",
"Hacl.Impl.P256.Qinv.qsquare_times_in_place"
] | [] | false | true | false | false | false | let qinv_make_x x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
| qsquare_times x6 a 1ul;
qmul x_11 x6 a;
qmul x_101 x6 x_11;
qmul x_111 x6 x_101;
qsquare_times x6 x_101 1ul;
qmul x_1111 x_101 x6;
qsquare_times_in_place x6 1ul;
qmul x_10101 x6 a;
qsquare_times x6 x_10101 1ul;
qmul x_101111 x_101 x6;
qmul x6 x_10101 x6 | false |
Hacl.Impl.P256.Qinv.fst | Hacl.Impl.P256.Qinv.qinv | val qinv: res:felem -> a:felem -> Stack unit
(requires fun h ->
live h a /\ live h res /\ eq_or_disjoint a res /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc res) h0 h1 /\
as_nat h1 res < S.order /\
qmont_as_nat h1 res == S.qinv (qmont_as_nat h0 a)) | val qinv: res:felem -> a:felem -> Stack unit
(requires fun h ->
live h a /\ live h res /\ eq_or_disjoint a res /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc res) h0 h1 /\
as_nat h1 res < S.order /\
qmont_as_nat h1 res == S.qinv (qmont_as_nat h0 a)) | let qinv res r =
let h0 = ST.get () in
push_frame ();
let tmp = create 28ul (u64 0) in
let x6 = sub tmp 0ul 4ul in
let x_11 = sub tmp 4ul 4ul in
let x_101 = sub tmp 8ul 4ul in
let x_111 = sub tmp 12ul 4ul in
let x_1111 = sub tmp 16ul 4ul in
let x_10101 = sub tmp 20ul 4ul in
let x_101111 = sub tmp 24ul 4ul in
qinv_make_x x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 r;
qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 r;
copy res x6;
let h1 = ST.get () in
assert (qmont_as_nat h1 res == SI.qinv (qmont_as_nat h0 r));
SI.qinv_is_qinv_lemma (qmont_as_nat h0 r);
pop_frame () | {
"file_name": "code/ecdsap256/Hacl.Impl.P256.Qinv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 14,
"end_line": 482,
"start_col": 0,
"start_line": 465
} | module Hacl.Impl.P256.Qinv
open FStar.Mul
open FStar.HyperStack.All
open FStar.HyperStack
module ST = FStar.HyperStack.ST
open Lib.IntTypes
open Lib.Buffer
open Hacl.Impl.P256.Bignum
open Hacl.Impl.P256.Scalar
module SE = Spec.Exponentiation
module BE = Hacl.Impl.Exponentiation
module BD = Hacl.Spec.Bignum.Definitions
module LSeq = Lib.Sequence
module S = Spec.P256
module SI = Hacl.Spec.P256.Qinv
module SM = Hacl.Spec.P256.Montgomery
#reset-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let linv (a:LSeq.lseq uint64 4) : Type0 =
BD.bn_v a < S.order
unfold
let refl (a:LSeq.lseq uint64 4{linv a}) : GTot S.qelem =
SM.from_qmont (BD.bn_v a)
inline_for_extraction noextract
let mk_to_p256_order_comm_monoid : BE.to_comm_monoid U64 4ul 0ul = {
BE.a_spec = S.qelem;
BE.comm_monoid = SI.nat_mod_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = linv;
BE.refl = refl;
}
inline_for_extraction noextract
val one_mod : BE.lone_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let one_mod ctx one = make_qone one
inline_for_extraction noextract
val mul_mod : BE.lmul_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let mul_mod ctx x y xy = qmul xy x y
inline_for_extraction noextract
val sqr_mod : BE.lsqr_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let sqr_mod ctx x xx = qsqr xx x
inline_for_extraction noextract
let mk_p256_order_concrete_ops : BE.concrete_ops U64 4ul 0ul = {
BE.to = mk_to_p256_order_comm_monoid;
BE.lone = one_mod;
BE.lmul = mul_mod;
BE.lsqr = sqr_mod;
}
inline_for_extraction noextract
val qsquare_times_in_place (out:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ as_nat h out < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 out) (v b))
let qsquare_times_in_place out b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 out) (v b);
BE.lexp_pow2_in_place 4ul 0ul mk_p256_order_concrete_ops (null uint64) out b
inline_for_extraction noextract
val qsquare_times (out a:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ live h a /\ disjoint out a /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 a) (v b))
let qsquare_times out a b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 a) (v b);
BE.lexp_pow2 4ul 0ul mk_p256_order_concrete_ops (null uint64) a b out
// x6 can be modified
// x_11 cannot be modified
inline_for_extraction noextract
val qinv_x8_x128 (x128 x6 x_11:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x6 /\ live h x_11 /\
disjoint x128 x6 /\ disjoint x128 x_11 /\ disjoint x6 x_11 /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128 |+| loc x6) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x8_x128 (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11))
let qinv_x8_x128 x128 x6 x_11 =
let h0 = ST.get () in
qsquare_times_in_place x6 2ul;
qmul x6 x6 x_11;
let h1 = ST.get () in
assert (qmont_as_nat h1 x6 == // x8
S.qmul (SI.qsquare_times (qmont_as_nat h0 x6) 2) (qmont_as_nat h0 x_11));
qsquare_times x128 x6 8ul;
qmul x128 x128 x6;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x16
S.qmul (SI.qsquare_times (qmont_as_nat h1 x6) 8) (qmont_as_nat h1 x6));
qsquare_times x6 x128 16ul;
qmul x6 x6 x128;
let h3 = ST.get () in
assert (qmont_as_nat h3 x6 == // x32
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 16) (qmont_as_nat h2 x128));
qsquare_times x128 x6 64ul;
qmul x128 x128 x6;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x96
S.qmul (SI.qsquare_times (qmont_as_nat h3 x6) 64) (qmont_as_nat h3 x6));
qsquare_times_in_place x128 32ul;
qmul x128 x128 x6;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x128
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 32) (qmont_as_nat h3 x6))
// x128 can be modified
inline_for_extraction noextract
val qinv_x134_x153 (x128 x_11 x_111 x_1111 x_10101 x_101111:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x_11 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\
disjoint x128 x_11 /\ disjoint x128 x_111 /\ disjoint x128 x_1111 /\
disjoint x128 x_10101 /\ disjoint x128 x_101111 /\
as_nat h x128 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x134_x153
(qmont_as_nat h0 x128) (qmont_as_nat h0 x_11) (qmont_as_nat h0 x_111)
(qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x134_x153 x128 x_11 x_111 x_1111 x_10101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x128 6ul;
qmul x128 x128 x_101111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x128 == // x134
S.qmul (SI.qsquare_times (qmont_as_nat h0 x128) 6) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_111;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x139
S.qmul (SI.qsquare_times (qmont_as_nat h1 x128) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x128 4ul;
qmul x128 x128 x_11;
let h3 = ST.get () in
assert (qmont_as_nat h3 x128 == // x143
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 4) (qmont_as_nat h0 x_11));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x148
S.qmul (SI.qsquare_times (qmont_as_nat h3 x128) 5) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_10101;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x153
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 5) (qmont_as_nat h0 x_10101))
// x153 can be modified
inline_for_extraction noextract
val qinv_x153_x177 (x153 x_101 x_111 x_101111:felem) : Stack unit
(requires fun h ->
live h x153 /\ live h x_101 /\ live h x_111 /\ live h x_101111 /\
disjoint x153 x_101 /\ disjoint x153 x_111 /\ disjoint x153 x_101111 /\
as_nat h x153 < S.order /\ as_nat h x_101 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x153) h0 h1 /\
as_nat h1 x153 < S.order /\
qmont_as_nat h1 x153 = SI.qinv_x153_x177 (qmont_as_nat h0 x153)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_101111))
let qinv_x153_x177 x153 x_101 x_111 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x153 4ul;
qmul x153 x153 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x153 == // x157
S.qmul (SI.qsquare_times (qmont_as_nat h0 x153) 4) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x153 == // x160
S.qmul (SI.qsquare_times (qmont_as_nat h1 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h3 = ST.get () in
assert (qmont_as_nat h3 x153 == // x163
S.qmul (SI.qsquare_times (qmont_as_nat h2 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 5ul;
qmul x153 x153 x_111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x153 == // x168
S.qmul (SI.qsquare_times (qmont_as_nat h3 x153) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x153 9ul;
qmul x153 x153 x_101111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x153 == // x177
S.qmul (SI.qsquare_times (qmont_as_nat h4 x153) 9) (qmont_as_nat h0 x_101111))
// x153 can be modified
inline_for_extraction noextract
val qinv_x177_x210 (x177 x_111 x_1111 a:felem) : Stack unit
(requires fun h ->
live h x177 /\ live h x_111 /\ live h x_1111 /\ live h a /\
disjoint x177 x_111 /\ disjoint x177 x_1111 /\ disjoint x177 a /\
as_nat h x177 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x177) h0 h1 /\
as_nat h1 x177 < S.order /\
qmont_as_nat h1 x177 = SI.qinv_x177_x210 (qmont_as_nat h0 a)
(qmont_as_nat h0 x177) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111))
let qinv_x177_x210 x177 x_111 x_1111 a =
let h0 = ST.get () in
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x177 == // x183
S.qmul (SI.qsquare_times (qmont_as_nat h0 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 2ul;
qmul x177 x177 a;
let h2 = ST.get () in
assert (qmont_as_nat h2 x177 == // x185
S.qmul (SI.qsquare_times (qmont_as_nat h1 x177) 2) (qmont_as_nat h0 a));
qsquare_times_in_place x177 5ul;
qmul x177 x177 a;
let h3 = ST.get () in
assert (qmont_as_nat h3 x177 == // x190
S.qmul (SI.qsquare_times (qmont_as_nat h2 x177) 5) (qmont_as_nat h0 a));
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x177 == // x196
S.qmul (SI.qsquare_times (qmont_as_nat h3 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x177 == // x201
S.qmul (SI.qsquare_times (qmont_as_nat h4 x177) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 4ul;
qmul x177 x177 x_111;
let h6 = ST.get () in
assert (qmont_as_nat h6 x177 == // x205
S.qmul (SI.qsquare_times (qmont_as_nat h5 x177) 4) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h7 = ST.get () in
assert (qmont_as_nat h7 x177 == // x210
S.qmul (SI.qsquare_times (qmont_as_nat h6 x177) 5) (qmont_as_nat h0 x_111))
inline_for_extraction noextract
val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111))
let qinv_x210_x240 x210 x_11 x_101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x210 == // x215
S.qmul (SI.qsquare_times (qmont_as_nat h0 x210) 5) (qmont_as_nat h0 x_101));
qsquare_times_in_place x210 3ul;
qmul x210 x210 x_11;
let h2 = ST.get () in
assert (qmont_as_nat h2 x210 == // x218
S.qmul (SI.qsquare_times (qmont_as_nat h1 x210) 3) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 10ul;
qmul x210 x210 x_101111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x210 == // x228
S.qmul (SI.qsquare_times (qmont_as_nat h2 x210) 10) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x210 2ul;
qmul x210 x210 x_11;
let h4 = ST.get () in
assert (qmont_as_nat h4 x210 == // x230
S.qmul (SI.qsquare_times (qmont_as_nat h3 x210) 2) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h5 = ST.get () in
assert (qmont_as_nat h5 x210 == // x235
S.qmul (SI.qsquare_times (qmont_as_nat h4 x210) 5) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h6 = ST.get () in
assert (qmont_as_nat h6 x210 == // x240
S.qmul (SI.qsquare_times (qmont_as_nat h5 x210) 5) (qmont_as_nat h0 x_11))
inline_for_extraction noextract
val qinv_x240_x256 (x240 x_1111 x_10101 a:felem) : Stack unit
(requires fun h ->
live h x240 /\ live h x_1111 /\ live h x_10101 /\ live h a /\
disjoint x240 x_1111 /\ disjoint x240 x_10101 /\ disjoint x240 a /\
as_nat h x240 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x240) h0 h1 /\
as_nat h1 x240 < S.order /\
qmont_as_nat h1 x240 = SI.qinv_x240_x256 (qmont_as_nat h0 a)
(qmont_as_nat h0 x240) (qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101))
let qinv_x240_x256 x240 x_1111 x_10101 a =
let h0 = ST.get () in
qsquare_times_in_place x240 3ul;
qmul x240 x240 a;
let h1 = ST.get () in
assert (qmont_as_nat h1 x240 == // x243
S.qmul (SI.qsquare_times (qmont_as_nat h0 x240) 3) (qmont_as_nat h0 a));
qsquare_times_in_place x240 7ul;
qmul x240 x240 x_10101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x240 == // x250
S.qmul (SI.qsquare_times (qmont_as_nat h1 x240) 7) (qmont_as_nat h0 x_10101));
qsquare_times_in_place x240 6ul;
qmul x240 x240 x_1111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x240 == // x256
S.qmul (SI.qsquare_times (qmont_as_nat h2 x240) 6) (qmont_as_nat h0 x_1111))
// x128 can be modified
inline_for_extraction noextract
val qinv_x8_x256 (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
disjoint x6 x_11 /\ disjoint x6 x_101 /\ disjoint x6 x_111 /\ disjoint x6 x_1111 /\
disjoint x6 x_10101 /\ disjoint x6 x_101111 /\ disjoint x6 a /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h x_10101 < S.order /\
as_nat h x_101111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x6) h0 h1 /\
as_nat h1 x6 < S.order /\
qmont_as_nat h1 x6 = SI.qinv_x8_x256
(qmont_as_nat h0 a) (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111)
(qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
push_frame ();
let tmp = create_felem () in
qinv_x8_x128 tmp x6 x_11;
qinv_x134_x153 tmp x_11 x_111 x_1111 x_10101 x_101111;
qinv_x153_x177 tmp x_101 x_111 x_101111;
qinv_x177_x210 tmp x_111 x_1111 a;
qinv_x210_x240 tmp x_11 x_101 x_101111;
qinv_x240_x256 tmp x_1111 x_10101 a;
copy x6 tmp;
pop_frame ()
// x128 can be modified
inline_for_extraction noextract
val qinv_make_x (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
LowStar.Monotonic.Buffer.all_disjoint
[ loc x6; loc x_11; loc x_101; loc x_111; loc x_1111; loc x_10101; loc x_101111; loc a ] /\
as_nat h a < S.order)
(ensures fun h0 _ h1 ->
modifies (loc x6 |+| loc x_11 |+| loc x_101 |+| loc x_111 |+|
loc x_1111 |+| loc x_10101 |+| loc x_101111) h0 h1 /\
as_nat h1 x6 < S.order /\ as_nat h1 x_11 < S.order /\
as_nat h1 x_101 < S.order /\ as_nat h1 x_111 < S.order /\
as_nat h1 x_1111 < S.order /\ as_nat h1 x_10101 < S.order /\
as_nat h1 x_101111 < S.order /\
(let f = qmont_as_nat h0 a in
let x_10_s = SI.qsquare_times f 1 in // x_10 is used 3x
let x_11_s = S.qmul x_10_s f in
let x_101_s = S.qmul x_10_s x_11_s in
let x_111_s = S.qmul x_10_s x_101_s in
let x_1010_s = SI.qsquare_times x_101_s 1 in // x_1010 is used 2x
let x_1111_s = S.qmul x_101_s x_1010_s in
let x_10101_s = S.qmul (SI.qsquare_times x_1010_s 1) f in
let x_101010_s = SI.qsquare_times x_10101_s 1 in // x_101010 is used 2x
let x_101111_s = S.qmul x_101_s x_101010_s in
let x6_s = S.qmul x_10101_s x_101010_s in
qmont_as_nat h1 x6 = x6_s /\ qmont_as_nat h1 x_11 = x_11_s /\
qmont_as_nat h1 x_101 = x_101_s /\ qmont_as_nat h1 x_111 = x_111_s /\
qmont_as_nat h1 x_1111 = x_1111_s /\ qmont_as_nat h1 x_10101 = x_10101_s /\
qmont_as_nat h1 x_101111 = x_101111_s))
let qinv_make_x x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
qsquare_times x6 a 1ul; // x_10
qmul x_11 x6 a;
qmul x_101 x6 x_11;
qmul x_111 x6 x_101;
qsquare_times x6 x_101 1ul; // x_1010
qmul x_1111 x_101 x6;
qsquare_times_in_place x6 1ul;
qmul x_10101 x6 a;
qsquare_times x6 x_10101 1ul; // x_101010
qmul x_101111 x_101 x6;
qmul x6 x_10101 x6 | {
"checked_file": "/",
"dependencies": [
"Spec.P256.fst.checked",
"Spec.Exponentiation.fsti.checked",
"prims.fst.checked",
"LowStar.Monotonic.Buffer.fsti.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Spec.P256.Qinv.fst.checked",
"Hacl.Spec.P256.Montgomery.fsti.checked",
"Hacl.Spec.Bignum.Definitions.fst.checked",
"Hacl.Impl.P256.Scalar.fsti.checked",
"Hacl.Impl.P256.Bignum.fsti.checked",
"Hacl.Impl.Exponentiation.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": true,
"source_file": "Hacl.Impl.P256.Qinv.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Montgomery",
"short_module": "SM"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Qinv",
"short_module": "SI"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.Bignum.Definitions",
"short_module": "BD"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Spec.Exponentiation",
"short_module": "SE"
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"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 | res: Hacl.Impl.P256.Bignum.felem -> a: Hacl.Impl.P256.Bignum.felem
-> FStar.HyperStack.ST.Stack Prims.unit | FStar.HyperStack.ST.Stack | [] | [] | [
"Hacl.Impl.P256.Bignum.felem",
"FStar.HyperStack.ST.pop_frame",
"Prims.unit",
"Hacl.Spec.P256.Qinv.qinv_is_qinv_lemma",
"Hacl.Impl.P256.Scalar.qmont_as_nat",
"Prims._assert",
"Prims.eq2",
"Spec.P256.PointOps.qelem",
"Hacl.Spec.P256.Qinv.qinv",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"Lib.Buffer.copy",
"Lib.Buffer.MUT",
"Lib.IntTypes.uint64",
"Lib.IntTypes.size",
"Hacl.Impl.P256.Qinv.qinv_x8_x256",
"Hacl.Impl.P256.Qinv.qinv_make_x",
"Lib.Buffer.lbuffer_t",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.UInt32.uint_to_t",
"FStar.UInt32.t",
"Lib.Buffer.sub",
"FStar.UInt32.__uint_to_t",
"Lib.Buffer.create",
"Lib.IntTypes.u64",
"Lib.Buffer.lbuffer",
"FStar.HyperStack.ST.push_frame"
] | [] | false | true | false | false | false | let qinv res r =
| let h0 = ST.get () in
push_frame ();
let tmp = create 28ul (u64 0) in
let x6 = sub tmp 0ul 4ul in
let x_11 = sub tmp 4ul 4ul in
let x_101 = sub tmp 8ul 4ul in
let x_111 = sub tmp 12ul 4ul in
let x_1111 = sub tmp 16ul 4ul in
let x_10101 = sub tmp 20ul 4ul in
let x_101111 = sub tmp 24ul 4ul in
qinv_make_x x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 r;
qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 r;
copy res x6;
let h1 = ST.get () in
assert (qmont_as_nat h1 res == SI.qinv (qmont_as_nat h0 r));
SI.qinv_is_qinv_lemma (qmont_as_nat h0 r);
pop_frame () | false |
Hacl.Curve25519_64.fst | Hacl.Curve25519_64.g25519 | val g25519:g25519_t | val g25519:g25519_t | let g25519: g25519_t =
Lib.Buffer.createL_global Spec.Curve25519.basepoint_list | {
"file_name": "code/curve25519/Hacl.Curve25519_64.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 58,
"end_line": 10,
"start_col": 0,
"start_line": 9
} | module Hacl.Curve25519_64
friend Hacl.Meta.Curve25519
open Hacl.Meta.Curve25519
// The Vale core.
module C = Hacl.Impl.Curve25519.Field64.Vale | {
"checked_file": "/",
"dependencies": [
"Spec.Curve25519.fst.checked",
"prims.fst.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Meta.Curve25519.fst.checked",
"Hacl.Impl.Curve25519.Field64.Vale.fsti.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "Hacl.Curve25519_64.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Impl.Curve25519.Field64.Vale",
"short_module": "C"
},
{
"abbrev": false,
"full_module": "Hacl.Meta.Curve25519",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Fields",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.Curve25519.Generic",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl",
"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": false,
"z3cliopt": [],
"z3refresh": false,
"z3rlimit": 5,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | Hacl.Impl.Curve25519.Generic.g25519_t | Prims.Tot | [
"total"
] | [] | [
"Lib.Buffer.createL_global",
"Lib.IntTypes.int_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.PUB",
"Spec.Curve25519.basepoint_list",
"Lib.Buffer.glbuffer",
"Lib.IntTypes.size",
"FStar.Pervasives.normalize_term",
"Lib.IntTypes.size_nat",
"FStar.List.Tot.Base.length"
] | [] | false | false | false | true | false | let g25519:g25519_t =
| Lib.Buffer.createL_global Spec.Curve25519.basepoint_list | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test1_plaintext | val test1_plaintext:lbytes 0 | val test1_plaintext:lbytes 0 | let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 17,
"start_col": 0,
"start_line": 14
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 0 | 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.Nil"
] | [] | false | false | false | false | false | let test1_plaintext:lbytes 0 =
| let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test2_plaintext | val test2_plaintext:lbytes 3 | val test2_plaintext:lbytes 3 | let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 75,
"start_col": 0,
"start_line": 72
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 3 | 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_plaintext:lbytes 3 =
| let l = List.Tot.map u8_from_UInt8 [0x61uy; 0x62uy; 0x63uy] in
assert_norm (List.Tot.length l == 3);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.linv_ctx | val linv_ctx (a: LSeq.lseq uint64 0) : Type0 | val linv_ctx (a: LSeq.lseq uint64 0) : Type0 | let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 50,
"end_line": 23,
"start_col": 0,
"start_line": 23
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0" | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | a: Lib.Sequence.lseq Lib.IntTypes.uint64 0 -> Type0 | Prims.Tot | [
"total"
] | [] | [
"Lib.Sequence.lseq",
"Lib.IntTypes.uint64",
"Prims.l_True"
] | [] | false | false | false | false | true | let linv_ctx (a: LSeq.lseq uint64 0) : Type0 =
| True | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test1_expected_sha3_256 | val test1_expected_sha3_256:lbytes 32 | val test1_expected_sha3_256:lbytes 32 | let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 39,
"start_col": 0,
"start_line": 31
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy; 0x51uy; 0xc1uy; 0x47uy; 0x56uy;
0xa0uy; 0x61uy; 0xd6uy; 0x62uy; 0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test2_expected_sha3_224 | val test2_expected_sha3_224:lbytes 28 | val test2_expected_sha3_224:lbytes 28 | let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 86,
"start_col": 0,
"start_line": 78
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy; 0xd0uy; 0x92uy; 0x34uy; 0xeeuy;
0x7duy; 0x3cuy; 0x76uy; 0x6fuy; 0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.refl | val refl (p: LSeq.lseq uint64 15 {point_inv_lseq p}) : GTot S.aff_point | val refl (p: LSeq.lseq uint64 15 {point_inv_lseq p}) : GTot S.aff_point | let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p) | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 36,
"end_line": 27,
"start_col": 0,
"start_line": 26
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | p: Lib.Sequence.lseq Lib.IntTypes.uint64 15 {Hacl.Impl.K256.Point.point_inv_lseq p}
-> Prims.GTot Spec.K256.PointOps.aff_point | Prims.GTot | [
"sometrivial"
] | [] | [
"Lib.Sequence.lseq",
"Lib.IntTypes.uint64",
"Hacl.Impl.K256.Point.point_inv_lseq",
"Spec.K256.PointOps.to_aff_point",
"Hacl.Impl.K256.Point.point_eval_lseq",
"Spec.K256.PointOps.aff_point"
] | [] | false | false | false | false | false | let refl (p: LSeq.lseq uint64 15 {point_inv_lseq p}) : GTot S.aff_point =
| S.to_aff_point (point_eval_lseq p) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test3_plaintext | val test3_plaintext:lbytes 56 | val test3_plaintext:lbytes 56 | let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 141,
"start_col": 0,
"start_line": 130
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 56 | 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_plaintext:lbytes 56 =
| let l =
List.Tot.map u8_from_UInt8
[
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
]
in
assert_norm (List.Tot.length l == 56);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test2_expected_sha3_256 | val test2_expected_sha3_256:lbytes 32 | val test2_expected_sha3_256:lbytes 32 | let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 97,
"start_col": 0,
"start_line": 89
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy; 0x04uy; 0x5cuy; 0x17uy; 0x2duy;
0x6buy; 0xd3uy; 0x90uy; 0xbduy; 0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test1_expected_sha3_224 | val test1_expected_sha3_224:lbytes 28 | val test1_expected_sha3_224:lbytes 28 | let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 28,
"start_col": 0,
"start_line": 20
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy; 0x3buy; 0x6euy; 0x15uy; 0x45uy;
0x4fuy; 0x0euy; 0xb1uy; 0xabuy; 0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test1_expected_sha3_384 | val test1_expected_sha3_384:lbytes 48 | val test1_expected_sha3_384:lbytes 48 | let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 52,
"start_col": 0,
"start_line": 42
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy; 0x01uy; 0x10uy; 0x7duy; 0x85uy;
0x2euy; 0x4cuy; 0x24uy; 0x85uy; 0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy; 0xc3uy; 0x71uy; 0x38uy; 0x31uy;
0x26uy; 0x4auy; 0xdbuy; 0x47uy; 0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test3_expected_sha3_224 | val test3_expected_sha3_224:lbytes 28 | val test3_expected_sha3_224:lbytes 28 | let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 152,
"start_col": 0,
"start_line": 144
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy; 0xc9uy; 0xfduy; 0x55uy; 0x74uy;
0x49uy; 0x44uy; 0x79uy; 0xbauy; 0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.mk_to_k256_comm_monoid | val mk_to_k256_comm_monoid:BE.to_comm_monoid U64 15ul 0ul | val mk_to_k256_comm_monoid:BE.to_comm_monoid U64 15ul 0ul | let mk_to_k256_comm_monoid : BE.to_comm_monoid U64 15ul 0ul = {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl;
} | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 1,
"end_line": 36,
"start_col": 0,
"start_line": 30
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p) | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | Hacl.Impl.Exponentiation.Definitions.to_comm_monoid Lib.IntTypes.U64
(15ul <: FStar.UInt32.t)
(0ul <: FStar.UInt32.t) | Prims.Tot | [
"total"
] | [] | [
"Hacl.Impl.Exponentiation.Definitions.Mkto_comm_monoid",
"Lib.IntTypes.U64",
"FStar.UInt32.uint_to_t",
"Spec.K256.PointOps.aff_point",
"Spec.K256.mk_k256_comm_monoid",
"Hacl.Impl.K256.Group.linv_ctx",
"Hacl.Impl.K256.Point.point_inv_lseq",
"Hacl.Impl.K256.Group.refl"
] | [] | false | false | false | false | false | let mk_to_k256_comm_monoid:BE.to_comm_monoid U64 15ul 0ul =
| {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl
} | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test1_expected_sha3_512 | val test1_expected_sha3_512:lbytes 64 | val test1_expected_sha3_512:lbytes 64 | let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.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": 55
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy; 0xc8uy; 0xb5uy; 0x67uy; 0xdcuy;
0x18uy; 0x5auy; 0x75uy; 0x6euy; 0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy; 0x15uy; 0xb2uy; 0x12uy; 0x3auy;
0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy; 0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy; 0x01uy; 0x75uy; 0x85uy; 0x86uy;
0x28uy; 0x1duy; 0xcduy; 0x26uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Hacl.Impl.P256.Qinv.fst | Hacl.Impl.P256.Qinv.qinv_x8_x256 | val qinv_x8_x256 (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
disjoint x6 x_11 /\ disjoint x6 x_101 /\ disjoint x6 x_111 /\ disjoint x6 x_1111 /\
disjoint x6 x_10101 /\ disjoint x6 x_101111 /\ disjoint x6 a /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h x_10101 < S.order /\
as_nat h x_101111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x6) h0 h1 /\
as_nat h1 x6 < S.order /\
qmont_as_nat h1 x6 = SI.qinv_x8_x256
(qmont_as_nat h0 a) (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111)
(qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111)) | val qinv_x8_x256 (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
disjoint x6 x_11 /\ disjoint x6 x_101 /\ disjoint x6 x_111 /\ disjoint x6 x_1111 /\
disjoint x6 x_10101 /\ disjoint x6 x_101111 /\ disjoint x6 a /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h x_10101 < S.order /\
as_nat h x_101111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x6) h0 h1 /\
as_nat h1 x6 < S.order /\
qmont_as_nat h1 x6 = SI.qinv_x8_x256
(qmont_as_nat h0 a) (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111)
(qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111)) | let qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
push_frame ();
let tmp = create_felem () in
qinv_x8_x128 tmp x6 x_11;
qinv_x134_x153 tmp x_11 x_111 x_1111 x_10101 x_101111;
qinv_x153_x177 tmp x_101 x_111 x_101111;
qinv_x177_x210 tmp x_111 x_1111 a;
qinv_x210_x240 tmp x_11 x_101 x_101111;
qinv_x240_x256 tmp x_1111 x_10101 a;
copy x6 tmp;
pop_frame () | {
"file_name": "code/ecdsap256/Hacl.Impl.P256.Qinv.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 14,
"end_line": 411,
"start_col": 0,
"start_line": 401
} | module Hacl.Impl.P256.Qinv
open FStar.Mul
open FStar.HyperStack.All
open FStar.HyperStack
module ST = FStar.HyperStack.ST
open Lib.IntTypes
open Lib.Buffer
open Hacl.Impl.P256.Bignum
open Hacl.Impl.P256.Scalar
module SE = Spec.Exponentiation
module BE = Hacl.Impl.Exponentiation
module BD = Hacl.Spec.Bignum.Definitions
module LSeq = Lib.Sequence
module S = Spec.P256
module SI = Hacl.Spec.P256.Qinv
module SM = Hacl.Spec.P256.Montgomery
#reset-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let linv (a:LSeq.lseq uint64 4) : Type0 =
BD.bn_v a < S.order
unfold
let refl (a:LSeq.lseq uint64 4{linv a}) : GTot S.qelem =
SM.from_qmont (BD.bn_v a)
inline_for_extraction noextract
let mk_to_p256_order_comm_monoid : BE.to_comm_monoid U64 4ul 0ul = {
BE.a_spec = S.qelem;
BE.comm_monoid = SI.nat_mod_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = linv;
BE.refl = refl;
}
inline_for_extraction noextract
val one_mod : BE.lone_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let one_mod ctx one = make_qone one
inline_for_extraction noextract
val mul_mod : BE.lmul_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let mul_mod ctx x y xy = qmul xy x y
inline_for_extraction noextract
val sqr_mod : BE.lsqr_st U64 4ul 0ul mk_to_p256_order_comm_monoid
let sqr_mod ctx x xx = qsqr xx x
inline_for_extraction noextract
let mk_p256_order_concrete_ops : BE.concrete_ops U64 4ul 0ul = {
BE.to = mk_to_p256_order_comm_monoid;
BE.lone = one_mod;
BE.lmul = mul_mod;
BE.lsqr = sqr_mod;
}
inline_for_extraction noextract
val qsquare_times_in_place (out:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ as_nat h out < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 out) (v b))
let qsquare_times_in_place out b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 out) (v b);
BE.lexp_pow2_in_place 4ul 0ul mk_p256_order_concrete_ops (null uint64) out b
inline_for_extraction noextract
val qsquare_times (out a:felem) (b:size_t) : Stack unit
(requires fun h ->
live h out /\ live h a /\ disjoint out a /\
as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc out) h0 h1 /\
as_nat h1 out < S.order /\
qmont_as_nat h1 out == SI.qsquare_times (qmont_as_nat h0 a) (v b))
let qsquare_times out a b =
let h0 = ST.get () in
SE.exp_pow2_lemma SI.mk_nat_mod_concrete_ops (qmont_as_nat h0 a) (v b);
BE.lexp_pow2 4ul 0ul mk_p256_order_concrete_ops (null uint64) a b out
// x6 can be modified
// x_11 cannot be modified
inline_for_extraction noextract
val qinv_x8_x128 (x128 x6 x_11:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x6 /\ live h x_11 /\
disjoint x128 x6 /\ disjoint x128 x_11 /\ disjoint x6 x_11 /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128 |+| loc x6) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x8_x128 (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11))
let qinv_x8_x128 x128 x6 x_11 =
let h0 = ST.get () in
qsquare_times_in_place x6 2ul;
qmul x6 x6 x_11;
let h1 = ST.get () in
assert (qmont_as_nat h1 x6 == // x8
S.qmul (SI.qsquare_times (qmont_as_nat h0 x6) 2) (qmont_as_nat h0 x_11));
qsquare_times x128 x6 8ul;
qmul x128 x128 x6;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x16
S.qmul (SI.qsquare_times (qmont_as_nat h1 x6) 8) (qmont_as_nat h1 x6));
qsquare_times x6 x128 16ul;
qmul x6 x6 x128;
let h3 = ST.get () in
assert (qmont_as_nat h3 x6 == // x32
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 16) (qmont_as_nat h2 x128));
qsquare_times x128 x6 64ul;
qmul x128 x128 x6;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x96
S.qmul (SI.qsquare_times (qmont_as_nat h3 x6) 64) (qmont_as_nat h3 x6));
qsquare_times_in_place x128 32ul;
qmul x128 x128 x6;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x128
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 32) (qmont_as_nat h3 x6))
// x128 can be modified
inline_for_extraction noextract
val qinv_x134_x153 (x128 x_11 x_111 x_1111 x_10101 x_101111:felem) : Stack unit
(requires fun h ->
live h x128 /\ live h x_11 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\
disjoint x128 x_11 /\ disjoint x128 x_111 /\ disjoint x128 x_1111 /\
disjoint x128 x_10101 /\ disjoint x128 x_101111 /\
as_nat h x128 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x128) h0 h1 /\
as_nat h1 x128 < S.order /\
qmont_as_nat h1 x128 = SI.qinv_x134_x153
(qmont_as_nat h0 x128) (qmont_as_nat h0 x_11) (qmont_as_nat h0 x_111)
(qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111))
let qinv_x134_x153 x128 x_11 x_111 x_1111 x_10101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x128 6ul;
qmul x128 x128 x_101111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x128 == // x134
S.qmul (SI.qsquare_times (qmont_as_nat h0 x128) 6) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_111;
let h2 = ST.get () in
assert (qmont_as_nat h2 x128 == // x139
S.qmul (SI.qsquare_times (qmont_as_nat h1 x128) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x128 4ul;
qmul x128 x128 x_11;
let h3 = ST.get () in
assert (qmont_as_nat h3 x128 == // x143
S.qmul (SI.qsquare_times (qmont_as_nat h2 x128) 4) (qmont_as_nat h0 x_11));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x128 == // x148
S.qmul (SI.qsquare_times (qmont_as_nat h3 x128) 5) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x128 5ul;
qmul x128 x128 x_10101;
let h5 = ST.get () in
assert (qmont_as_nat h5 x128 == // x153
S.qmul (SI.qsquare_times (qmont_as_nat h4 x128) 5) (qmont_as_nat h0 x_10101))
// x153 can be modified
inline_for_extraction noextract
val qinv_x153_x177 (x153 x_101 x_111 x_101111:felem) : Stack unit
(requires fun h ->
live h x153 /\ live h x_101 /\ live h x_111 /\ live h x_101111 /\
disjoint x153 x_101 /\ disjoint x153 x_111 /\ disjoint x153 x_101111 /\
as_nat h x153 < S.order /\ as_nat h x_101 < S.order /\
as_nat h x_111 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x153) h0 h1 /\
as_nat h1 x153 < S.order /\
qmont_as_nat h1 x153 = SI.qinv_x153_x177 (qmont_as_nat h0 x153)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_101111))
let qinv_x153_x177 x153 x_101 x_111 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x153 4ul;
qmul x153 x153 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x153 == // x157
S.qmul (SI.qsquare_times (qmont_as_nat h0 x153) 4) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x153 == // x160
S.qmul (SI.qsquare_times (qmont_as_nat h1 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 3ul;
qmul x153 x153 x_101;
let h3 = ST.get () in
assert (qmont_as_nat h3 x153 == // x163
S.qmul (SI.qsquare_times (qmont_as_nat h2 x153) 3) (qmont_as_nat h0 x_101));
qsquare_times_in_place x153 5ul;
qmul x153 x153 x_111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x153 == // x168
S.qmul (SI.qsquare_times (qmont_as_nat h3 x153) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x153 9ul;
qmul x153 x153 x_101111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x153 == // x177
S.qmul (SI.qsquare_times (qmont_as_nat h4 x153) 9) (qmont_as_nat h0 x_101111))
// x153 can be modified
inline_for_extraction noextract
val qinv_x177_x210 (x177 x_111 x_1111 a:felem) : Stack unit
(requires fun h ->
live h x177 /\ live h x_111 /\ live h x_1111 /\ live h a /\
disjoint x177 x_111 /\ disjoint x177 x_1111 /\ disjoint x177 a /\
as_nat h x177 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x177) h0 h1 /\
as_nat h1 x177 < S.order /\
qmont_as_nat h1 x177 = SI.qinv_x177_x210 (qmont_as_nat h0 a)
(qmont_as_nat h0 x177) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111))
let qinv_x177_x210 x177 x_111 x_1111 a =
let h0 = ST.get () in
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h1 = ST.get () in
assert (qmont_as_nat h1 x177 == // x183
S.qmul (SI.qsquare_times (qmont_as_nat h0 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 2ul;
qmul x177 x177 a;
let h2 = ST.get () in
assert (qmont_as_nat h2 x177 == // x185
S.qmul (SI.qsquare_times (qmont_as_nat h1 x177) 2) (qmont_as_nat h0 a));
qsquare_times_in_place x177 5ul;
qmul x177 x177 a;
let h3 = ST.get () in
assert (qmont_as_nat h3 x177 == // x190
S.qmul (SI.qsquare_times (qmont_as_nat h2 x177) 5) (qmont_as_nat h0 a));
qsquare_times_in_place x177 6ul;
qmul x177 x177 x_1111;
let h4 = ST.get () in
assert (qmont_as_nat h4 x177 == // x196
S.qmul (SI.qsquare_times (qmont_as_nat h3 x177) 6) (qmont_as_nat h0 x_1111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h5 = ST.get () in
assert (qmont_as_nat h5 x177 == // x201
S.qmul (SI.qsquare_times (qmont_as_nat h4 x177) 5) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 4ul;
qmul x177 x177 x_111;
let h6 = ST.get () in
assert (qmont_as_nat h6 x177 == // x205
S.qmul (SI.qsquare_times (qmont_as_nat h5 x177) 4) (qmont_as_nat h0 x_111));
qsquare_times_in_place x177 5ul;
qmul x177 x177 x_111;
let h7 = ST.get () in
assert (qmont_as_nat h7 x177 == // x210
S.qmul (SI.qsquare_times (qmont_as_nat h6 x177) 5) (qmont_as_nat h0 x_111))
inline_for_extraction noextract
val qinv_x210_x240 (x210 x_11 x_101 x_101111:felem) : Stack unit
(requires fun h ->
live h x210 /\ live h x_11 /\ live h x_101 /\ live h x_101111 /\
disjoint x210 x_11 /\ disjoint x210 x_101 /\ disjoint x210 x_101111 /\
as_nat h x210 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_101111 < S.order)
(ensures fun h0 _ h1 -> modifies (loc x210) h0 h1 /\
as_nat h1 x210 < S.order /\
qmont_as_nat h1 x210 = SI.qinv_x210_x240 (qmont_as_nat h0 x210)
(qmont_as_nat h0 x_11) (qmont_as_nat h0 x_101) (qmont_as_nat h0 x_101111))
let qinv_x210_x240 x210 x_11 x_101 x_101111 =
let h0 = ST.get () in
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_101;
let h1 = ST.get () in
assert (qmont_as_nat h1 x210 == // x215
S.qmul (SI.qsquare_times (qmont_as_nat h0 x210) 5) (qmont_as_nat h0 x_101));
qsquare_times_in_place x210 3ul;
qmul x210 x210 x_11;
let h2 = ST.get () in
assert (qmont_as_nat h2 x210 == // x218
S.qmul (SI.qsquare_times (qmont_as_nat h1 x210) 3) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 10ul;
qmul x210 x210 x_101111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x210 == // x228
S.qmul (SI.qsquare_times (qmont_as_nat h2 x210) 10) (qmont_as_nat h0 x_101111));
qsquare_times_in_place x210 2ul;
qmul x210 x210 x_11;
let h4 = ST.get () in
assert (qmont_as_nat h4 x210 == // x230
S.qmul (SI.qsquare_times (qmont_as_nat h3 x210) 2) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h5 = ST.get () in
assert (qmont_as_nat h5 x210 == // x235
S.qmul (SI.qsquare_times (qmont_as_nat h4 x210) 5) (qmont_as_nat h0 x_11));
qsquare_times_in_place x210 5ul;
qmul x210 x210 x_11;
let h6 = ST.get () in
assert (qmont_as_nat h6 x210 == // x240
S.qmul (SI.qsquare_times (qmont_as_nat h5 x210) 5) (qmont_as_nat h0 x_11))
inline_for_extraction noextract
val qinv_x240_x256 (x240 x_1111 x_10101 a:felem) : Stack unit
(requires fun h ->
live h x240 /\ live h x_1111 /\ live h x_10101 /\ live h a /\
disjoint x240 x_1111 /\ disjoint x240 x_10101 /\ disjoint x240 a /\
as_nat h x240 < S.order /\ as_nat h x_1111 < S.order /\
as_nat h x_10101 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x240) h0 h1 /\
as_nat h1 x240 < S.order /\
qmont_as_nat h1 x240 = SI.qinv_x240_x256 (qmont_as_nat h0 a)
(qmont_as_nat h0 x240) (qmont_as_nat h0 x_1111) (qmont_as_nat h0 x_10101))
let qinv_x240_x256 x240 x_1111 x_10101 a =
let h0 = ST.get () in
qsquare_times_in_place x240 3ul;
qmul x240 x240 a;
let h1 = ST.get () in
assert (qmont_as_nat h1 x240 == // x243
S.qmul (SI.qsquare_times (qmont_as_nat h0 x240) 3) (qmont_as_nat h0 a));
qsquare_times_in_place x240 7ul;
qmul x240 x240 x_10101;
let h2 = ST.get () in
assert (qmont_as_nat h2 x240 == // x250
S.qmul (SI.qsquare_times (qmont_as_nat h1 x240) 7) (qmont_as_nat h0 x_10101));
qsquare_times_in_place x240 6ul;
qmul x240 x240 x_1111;
let h3 = ST.get () in
assert (qmont_as_nat h3 x240 == // x256
S.qmul (SI.qsquare_times (qmont_as_nat h2 x240) 6) (qmont_as_nat h0 x_1111))
// x128 can be modified
inline_for_extraction noextract
val qinv_x8_x256 (x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a:felem) : Stack unit
(requires fun h ->
live h x6 /\ live h x_11 /\ live h x_101 /\ live h x_111 /\
live h x_1111 /\ live h x_10101 /\ live h x_101111 /\ live h a /\
disjoint x6 x_11 /\ disjoint x6 x_101 /\ disjoint x6 x_111 /\ disjoint x6 x_1111 /\
disjoint x6 x_10101 /\ disjoint x6 x_101111 /\ disjoint x6 a /\
as_nat h x6 < S.order /\ as_nat h x_11 < S.order /\
as_nat h x_101 < S.order /\ as_nat h x_111 < S.order /\
as_nat h x_1111 < S.order /\ as_nat h x_10101 < S.order /\
as_nat h x_101111 < S.order /\ as_nat h a < S.order)
(ensures fun h0 _ h1 -> modifies (loc x6) h0 h1 /\
as_nat h1 x6 < S.order /\
qmont_as_nat h1 x6 = SI.qinv_x8_x256
(qmont_as_nat h0 a) (qmont_as_nat h0 x6) (qmont_as_nat h0 x_11)
(qmont_as_nat h0 x_101) (qmont_as_nat h0 x_111) (qmont_as_nat h0 x_1111)
(qmont_as_nat h0 x_10101) (qmont_as_nat h0 x_101111)) | {
"checked_file": "/",
"dependencies": [
"Spec.P256.fst.checked",
"Spec.Exponentiation.fsti.checked",
"prims.fst.checked",
"LowStar.Monotonic.Buffer.fsti.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Spec.P256.Qinv.fst.checked",
"Hacl.Spec.P256.Montgomery.fsti.checked",
"Hacl.Spec.Bignum.Definitions.fst.checked",
"Hacl.Impl.P256.Scalar.fsti.checked",
"Hacl.Impl.P256.Bignum.fsti.checked",
"Hacl.Impl.Exponentiation.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.All.fst.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": true,
"source_file": "Hacl.Impl.P256.Qinv.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Montgomery",
"short_module": "SM"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.P256.Qinv",
"short_module": "SI"
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.Bignum.Definitions",
"short_module": "BD"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Spec.Exponentiation",
"short_module": "SE"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.P256",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Scalar",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256.Bignum",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.Buffer",
"short_module": null
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack.All",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.P256",
"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 |
x6: Hacl.Impl.P256.Bignum.felem ->
x_11: Hacl.Impl.P256.Bignum.felem ->
x_101: Hacl.Impl.P256.Bignum.felem ->
x_111: Hacl.Impl.P256.Bignum.felem ->
x_1111: Hacl.Impl.P256.Bignum.felem ->
x_10101: Hacl.Impl.P256.Bignum.felem ->
x_101111: Hacl.Impl.P256.Bignum.felem ->
a: Hacl.Impl.P256.Bignum.felem
-> FStar.HyperStack.ST.Stack Prims.unit | FStar.HyperStack.ST.Stack | [] | [] | [
"Hacl.Impl.P256.Bignum.felem",
"FStar.HyperStack.ST.pop_frame",
"Prims.unit",
"Lib.Buffer.copy",
"Lib.Buffer.MUT",
"Lib.IntTypes.uint64",
"Lib.IntTypes.size",
"Hacl.Impl.P256.Qinv.qinv_x240_x256",
"Hacl.Impl.P256.Qinv.qinv_x210_x240",
"Hacl.Impl.P256.Qinv.qinv_x177_x210",
"Hacl.Impl.P256.Qinv.qinv_x153_x177",
"Hacl.Impl.P256.Qinv.qinv_x134_x153",
"Hacl.Impl.P256.Qinv.qinv_x8_x128",
"Hacl.Impl.P256.Bignum.create_felem",
"FStar.HyperStack.ST.push_frame"
] | [] | false | true | false | false | false | let qinv_x8_x256 x6 x_11 x_101 x_111 x_1111 x_10101 x_101111 a =
| push_frame ();
let tmp = create_felem () in
qinv_x8_x128 tmp x6 x_11;
qinv_x134_x153 tmp x_11 x_111 x_1111 x_10101 x_101111;
qinv_x153_x177 tmp x_101 x_111 x_101111;
qinv_x177_x210 tmp x_111 x_1111 a;
qinv_x210_x240 tmp x_11 x_101 x_101111;
qinv_x240_x256 tmp x_1111 x_10101 a;
copy x6 tmp;
pop_frame () | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test2_expected_sha3_512 | val test2_expected_sha3_512:lbytes 64 | val test2_expected_sha3_512:lbytes 64 | let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 125,
"start_col": 0,
"start_line": 113
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy; 0x56uy; 0x93uy; 0xcduy; 0x92uy;
0x4buy; 0x6buy; 0x09uy; 0x6euy; 0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy; 0x10uy; 0xe1uy; 0x16uy; 0xe9uy;
0x19uy; 0x2auy; 0xf3uy; 0xc9uy; 0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy; 0x65uy; 0x92uy; 0xf8uy; 0x27uy;
0x4euy; 0xecuy; 0x53uy; 0xf0uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test2_expected_sha3_384 | val test2_expected_sha3_384:lbytes 48 | val test2_expected_sha3_384:lbytes 48 | let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 110,
"start_col": 0,
"start_line": 100
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy; 0x26uy; 0x45uy; 0x9fuy; 0x58uy;
0xe2uy; 0xc6uy; 0xaduy; 0x8duy; 0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy; 0x98uy; 0xd8uy; 0x8cuy; 0xeauy;
0x92uy; 0x7auy; 0xc7uy; 0xf5uy; 0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test3_expected_sha3_256 | val test3_expected_sha3_256:lbytes 32 | val test3_expected_sha3_256:lbytes 32 | let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.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": 155
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy; 0x49uy; 0x10uy; 0x03uy; 0x76uy;
0xa8uy; 0x23uy; 0x5euy; 0x2cuy; 0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test5_plaintext_shake128 | val test5_plaintext_shake128:lbytes 0 | val test5_plaintext_shake128:lbytes 0 | let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 271,
"start_col": 0,
"start_line": 268
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 0 | 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.Nil"
] | [] | false | false | false | false | false | let test5_plaintext_shake128:lbytes 0 =
| let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.mk_k256_concrete_ops | val mk_k256_concrete_ops:BE.concrete_ops U64 15ul 0ul | val mk_k256_concrete_ops:BE.concrete_ops U64 15ul 0ul | let mk_k256_concrete_ops : BE.concrete_ops U64 15ul 0ul = {
BE.to = mk_to_k256_comm_monoid;
BE.lone = point_zero;
BE.lmul = point_add;
BE.lsqr = point_double;
} | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 1,
"end_line": 66,
"start_col": 0,
"start_line": 61
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p)
inline_for_extraction noextract
let mk_to_k256_comm_monoid : BE.to_comm_monoid U64 15ul 0ul = {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl;
}
inline_for_extraction noextract
val point_add : BE.lmul_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_add ctx x y xy =
let h0 = ST.get () in
SL.to_aff_point_add_lemma (point_eval h0 x) (point_eval h0 y);
Hacl.Impl.K256.PointAdd.point_add xy x y
inline_for_extraction noextract
val point_double : BE.lsqr_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_double ctx x xx =
let h0 = ST.get () in
SL.to_aff_point_double_lemma (point_eval h0 x);
Hacl.Impl.K256.PointDouble.point_double xx x
inline_for_extraction noextract
val point_zero : BE.lone_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_zero ctx one = make_point_at_inf one | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | Hacl.Impl.Exponentiation.Definitions.concrete_ops Lib.IntTypes.U64
(15ul <: FStar.UInt32.t)
(0ul <: FStar.UInt32.t) | Prims.Tot | [
"total"
] | [] | [
"Hacl.Impl.Exponentiation.Definitions.Mkconcrete_ops",
"Lib.IntTypes.U64",
"FStar.UInt32.uint_to_t",
"FStar.Ghost.hide",
"Hacl.Impl.Exponentiation.Definitions.to_comm_monoid",
"Hacl.Impl.K256.Group.mk_to_k256_comm_monoid",
"Hacl.Impl.K256.Group.point_zero",
"Hacl.Impl.K256.Group.point_add",
"Hacl.Impl.K256.Group.point_double"
] | [] | false | false | false | false | false | let mk_k256_concrete_ops:BE.concrete_ops U64 15ul 0ul =
| {
BE.to = mk_to_k256_comm_monoid;
BE.lone = point_zero;
BE.lmul = point_add;
BE.lsqr = point_double
} | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test6_plaintext_shake128 | val test6_plaintext_shake128:lbytes 14 | val test6_plaintext_shake128:lbytes 14 | let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 291,
"start_col": 0,
"start_line": 285
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 14 | 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_plaintext_shake128:lbytes 14 =
| let l =
List.Tot.map u8_from_UInt8
[
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy; 0xdfuy; 0xefuy; 0xf7uy; 0xe9uy;
0xe4uy; 0xaduy
]
in
assert_norm (List.Tot.length l == 14);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test5_expected_shake128 | val test5_expected_shake128:lbytes 16 | val test5_expected_shake128:lbytes 16 | let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 280,
"start_col": 0,
"start_line": 274
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_shake128:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy; 0x61uy; 0x60uy; 0x45uy; 0x50uy;
0x76uy; 0x05uy; 0x85uy; 0x3euy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.point_zero | val point_zero : BE.lone_st U64 15ul 0ul mk_to_k256_comm_monoid | val point_zero : BE.lone_st U64 15ul 0ul mk_to_k256_comm_monoid | let point_zero ctx one = make_point_at_inf one | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 46,
"end_line": 57,
"start_col": 0,
"start_line": 57
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p)
inline_for_extraction noextract
let mk_to_k256_comm_monoid : BE.to_comm_monoid U64 15ul 0ul = {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl;
}
inline_for_extraction noextract
val point_add : BE.lmul_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_add ctx x y xy =
let h0 = ST.get () in
SL.to_aff_point_add_lemma (point_eval h0 x) (point_eval h0 y);
Hacl.Impl.K256.PointAdd.point_add xy x y
inline_for_extraction noextract
val point_double : BE.lsqr_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_double ctx x xx =
let h0 = ST.get () in
SL.to_aff_point_double_lemma (point_eval h0 x);
Hacl.Impl.K256.PointDouble.point_double xx x
inline_for_extraction noextract | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | Hacl.Impl.Exponentiation.Definitions.lone_st Lib.IntTypes.U64
15ul
0ul
Hacl.Impl.K256.Group.mk_to_k256_comm_monoid | Prims.Tot | [
"total"
] | [] | [
"Lib.Buffer.lbuffer",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.UInt32.__uint_to_t",
"Hacl.Impl.K256.Point.make_point_at_inf",
"Prims.unit"
] | [] | false | false | false | false | false | let point_zero ctx one =
| make_point_at_inf one | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test4_plaintext | val test4_plaintext:lbytes 112 | val test4_plaintext:lbytes 112 | let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 213,
"start_col": 0,
"start_line": 195
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 112 | 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_plaintext:lbytes 112 =
| let l =
List.Tot.map u8_from_UInt8
[
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x72uy; 0x73uy; 0x74uy; 0x75uy
]
in
assert_norm (List.Tot.length l == 112);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test4_expected_sha3_256 | val test4_expected_sha3_256:lbytes 32 | val test4_expected_sha3_256:lbytes 32 | let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 235,
"start_col": 0,
"start_line": 227
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy; 0xcauy; 0x64uy; 0x69uy; 0xb4uy;
0x39uy; 0x71uy; 0xdfuy; 0xdbuy; 0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test3_expected_sha3_512 | val test3_expected_sha3_512:lbytes 64 | val test3_expected_sha3_512:lbytes 64 | let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 191,
"start_col": 0,
"start_line": 179
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy; 0xb7uy; 0x7cuy; 0xb4uy; 0x86uy;
0x10uy; 0xfcuy; 0xa8uy; 0x18uy; 0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy; 0xeeuy; 0x69uy; 0x1fuy; 0xbeuy;
0x0cuy; 0x98uy; 0x53uy; 0x02uy; 0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy; 0xa2uy; 0x7duy; 0xafuy; 0x11uy;
0x39uy; 0xd6uy; 0xe7uy; 0x5euy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test4_expected_sha3_224 | val test4_expected_sha3_224:lbytes 28 | val test4_expected_sha3_224:lbytes 28 | let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 224,
"start_col": 0,
"start_line": 216
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_224:lbytes 28 =
| let l =
List.Tot.map u8_from_UInt8
[
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy; 0x64uy; 0x36uy; 0x30uy; 0xdfuy;
0x77uy; 0x36uy; 0x7auy; 0xe5uy; 0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
]
in
assert_norm (List.Tot.length l == 28);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test3_expected_sha3_384 | val test3_expected_sha3_384:lbytes 48 | val test3_expected_sha3_384:lbytes 48 | let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 176,
"start_col": 0,
"start_line": 166
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy; 0x6buy; 0xbduy; 0xfbuy; 0x75uy;
0xc7uy; 0x8auy; 0x49uy; 0x2euy; 0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy; 0xa0uy; 0x4auy; 0x1fuy; 0x07uy;
0x6euy; 0x62uy; 0xfeuy; 0xa1uy; 0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test7_expected_shake128 | val test7_expected_shake128:lbytes 16 | val test7_expected_shake128:lbytes 16 | let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 323,
"start_col": 0,
"start_line": 317
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test7_expected_shake128:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy; 0xbeuy; 0x51uy; 0x82uy; 0xbcuy;
0x1fuy; 0x09uy; 0x66uy; 0x48uy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test4_expected_sha3_384 | val test4_expected_sha3_384:lbytes 48 | val test4_expected_sha3_384:lbytes 48 | let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 248,
"start_col": 0,
"start_line": 238
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_384:lbytes 48 =
| let l =
List.Tot.map u8_from_UInt8
[
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy; 0x3euy; 0x30uy; 0xb0uy; 0x98uy;
0x22uy; 0x97uy; 0x47uy; 0x91uy; 0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy; 0x8cuy; 0x70uy; 0x9buy; 0x98uy;
0xb4uy; 0x3buy; 0x38uy; 0x52uy; 0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
]
in
assert_norm (List.Tot.length l == 48);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test6_expected_shake128 | val test6_expected_shake128:lbytes 16 | val test6_expected_shake128:lbytes 16 | let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 300,
"start_col": 0,
"start_line": 294
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test6_expected_shake128:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy; 0x69uy; 0xfcuy; 0xc8uy; 0x58uy;
0x8auy; 0xe5uy; 0xd2uy; 0xccuy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
MerkleTree.New.High.Correct.Path.fst | MerkleTree.New.High.Correct.Path.mt_get_path_acc_inv_ok | val mt_get_path_acc_inv_ok:
#hsz:pos -> #f:MTS.hash_fun_t ->
j:nat ->
fhs:hashess #hsz {S.length fhs = log2c j} ->
rhs:hashes #hsz {S.length rhs = log2c j} ->
k:nat{k <= j} ->
acc:hash -> actd:bool ->
Lemma (requires (j > 0 /\
mt_hashes_lth_inv_log #hsz j fhs /\
mt_hashes_inv_log #_ #f j fhs /\
mt_rhs_inv #_ #f j (hash_seq_spec_full #_ #f (S.head fhs) acc actd) rhs actd))
(ensures (S.equal (path_spec k j actd (mt_get_path_acc #_ #f j fhs rhs k actd))
(MTS.mt_get_path #_ #f #(log2c j)
(hash_seq_spec_full #_ #f (S.head fhs) acc actd) k)))
(decreases j) | val mt_get_path_acc_inv_ok:
#hsz:pos -> #f:MTS.hash_fun_t ->
j:nat ->
fhs:hashess #hsz {S.length fhs = log2c j} ->
rhs:hashes #hsz {S.length rhs = log2c j} ->
k:nat{k <= j} ->
acc:hash -> actd:bool ->
Lemma (requires (j > 0 /\
mt_hashes_lth_inv_log #hsz j fhs /\
mt_hashes_inv_log #_ #f j fhs /\
mt_rhs_inv #_ #f j (hash_seq_spec_full #_ #f (S.head fhs) acc actd) rhs actd))
(ensures (S.equal (path_spec k j actd (mt_get_path_acc #_ #f j fhs rhs k actd))
(MTS.mt_get_path #_ #f #(log2c j)
(hash_seq_spec_full #_ #f (S.head fhs) acc actd) k)))
(decreases j) | let rec mt_get_path_acc_inv_ok #_ #f j fhs rhs k acc actd =
// Below dummy `let` is necessary to provide guidance to the SMT solver.
let _ = mt_get_path_step_acc j (S.head fhs) (S.head rhs) k actd in
let smt = hash_seq_spec_full #_ #f (S.head fhs) acc actd in
let nacc = (if j % 2 = 0 then acc
else if actd
then f (S.last (S.head fhs)) acc
else S.last (S.head fhs)) in
let nactd = actd || j % 2 = 1 in
if j = 1 then (if k = 0 then () else ())
else begin
mt_hashes_lth_inv_log_next #_ #f j fhs;
hash_seq_spec_full_next #_ #f j (S.head fhs) (S.head (S.tail fhs)) acc actd nacc nactd;
mt_get_path_acc_inv_ok #_ #f (j / 2) (S.tail fhs) (S.tail rhs) (k / 2) nacc nactd;
if k % 2 = 0
then begin
if k = j || (k + 1 = j && not actd)
then assert (S.index smt (k + 1) == MTS.HPad)
else if k + 1 = j
then assert (S.index smt (k + 1) == MTS.HRaw (S.head rhs))
else hash_seq_spec_full_index_raw #_ #f (S.head fhs) acc actd (k + 1)
end
else begin
hash_seq_spec_full_index_raw #_ #f (S.head fhs) acc actd (k - 1)
end
end | {
"file_name": "src/MerkleTree.New.High.Correct.Path.fst",
"git_rev": "7d7bdc20f2033171e279c176b26e84f9069d23c6",
"git_url": "https://github.com/hacl-star/merkle-tree.git",
"project_name": "merkle-tree"
} | {
"end_col": 5,
"end_line": 237,
"start_col": 0,
"start_line": 211
} | module MerkleTree.New.High.Correct.Path
open EverCrypt
open EverCrypt.Helpers
open MerkleTree.New.High.Correct.Base
// Need to use some facts of `mt_get_root`
open MerkleTree.New.High.Correct.Rhs
open FStar.Classical
open FStar.Ghost
open FStar.Seq
module List = FStar.List.Tot
module S = FStar.Seq
module U32 = FStar.UInt32
module U8 = FStar.UInt8
type uint32_t = U32.t
type uint8_t = U8.t
module EHS = EverCrypt.Hash
module MTS = MerkleTree.Spec
open MerkleTree.New.High
#reset-options "--z3rlimit 20"
/// Correctness of path generation
val path_spec:
#hsz:pos ->
k:nat ->
j:nat{k <= j} ->
actd:bool ->
p:path #hsz {S.length p = mt_path_length k j actd} ->
GTot (sp:S.seq (MTS.padded_hash #hsz){S.length sp = log2c j})
(decreases j)
let rec path_spec #hsz k j actd p =
if j = 0 then S.empty
else (if k % 2 = 0
then (if j = k || (j = k + 1 && not actd)
then S.cons MTS.HPad (path_spec (k / 2) (j / 2) (actd || (j % 2 = 1)) p)
else S.cons (MTS.HRaw #hsz (S.head p))
(path_spec (k / 2) (j / 2) (actd || (j % 2 = 1)) (S.tail p)))
else S.cons (MTS.HRaw #hsz (S.head p))
(path_spec (k / 2) (j / 2) (actd || (j % 2 = 1)) (S.tail p)))
val mt_get_path_step_acc:
#hsz:pos ->
j:nat{j > 0} ->
chs:hashes #hsz {S.length chs = j} ->
crh:hash #hsz ->
k:nat{k <= j} ->
actd:bool ->
GTot (option (hash #hsz))
let mt_get_path_step_acc #hsz j chs crh k actd =
if k % 2 = 1
then Some (S.index chs (k - 1))
else (if k = j then None
else if k + 1 = j
then (if actd then Some crh else None)
else Some (S.index chs (k + 1)))
val mt_get_path_acc:
#hsz:pos -> #f:MTS.hash_fun_t #hsz ->
j:nat ->
fhs:hashess #hsz {S.length fhs = log2c j /\ mt_hashes_lth_inv_log #hsz j fhs} ->
rhs:hashes #hsz {S.length rhs = log2c j} ->
k:nat{k <= j} ->
actd:bool ->
GTot (np:path #hsz {S.length np = mt_path_length k j actd})
(decreases j)
let rec mt_get_path_acc #_ #f j fhs rhs k actd =
if j = 0 then S.empty
else
(let sp = mt_get_path_step_acc #_ j (S.head fhs) (S.head rhs) k actd in
let rp = mt_get_path_acc #_ #f (j / 2) (S.tail fhs) (S.tail rhs) (k / 2)
(actd || j % 2 = 1) in
if Some? sp
then (S.cons (Some?.v sp) rp)
else rp)
val mt_get_path_step_acc_consistent:
#hsz:pos -> #f:MTS.hash_fun_t ->
lv:nat{lv <= 32} ->
i:nat ->
j:nat{i <= j /\ j < pow2 (32 - lv)} ->
olds:hashess #hsz {S.length olds = 32 /\ mt_olds_inv #hsz lv i olds} ->
hs:hashess #hsz {S.length hs = 32 /\ hs_wf_elts lv hs i j} ->
rhs:hashes #hsz {S.length rhs = 32} ->
k:nat{i <= k && k <= j} ->
actd:bool ->
Lemma (requires (j <> 0))
(ensures
(log2c_bound j (32 - lv);
mt_olds_hs_lth_inv_ok #_ #f lv i j olds hs;
mt_hashes_lth_inv_log_converted_ #_ #f lv j (merge_hs #_ #f olds hs);
(match mt_get_path_step_acc j
(S.index (merge_hs #_ #f olds hs) lv) (S.index rhs lv)
k actd with
| Some v ->
S.equal (mt_make_path_step lv hs rhs i j k S.empty actd)
(S.cons v S.empty)
| None ->
S.equal (mt_make_path_step lv hs rhs i j k S.empty actd)
S.empty)))
let mt_get_path_step_acc_consistent #_ #_ lv i j olds hs rhs k actd = ()
private val seq_cons_append:
#a:Type -> hd:a -> tl:S.seq a ->
Lemma (S.equal (S.append (S.cons hd S.empty) tl)
(S.cons hd tl))
private let seq_cons_append #a hd tl = ()
val mt_get_path_acc_consistent:
#hsz:pos -> #f:MTS.hash_fun_t ->
lv:nat{lv <= 32} ->
i:nat ->
j:nat{i <= j /\ j < pow2 (32 - lv)} ->
olds:hashess #hsz {S.length olds = 32 /\ mt_olds_inv #hsz lv i olds} ->
hs:hashess #hsz {S.length hs = 32 /\ hs_wf_elts lv hs i j} ->
rhs:hashes #hsz {S.length rhs = 32} ->
k:nat{i <= k && k <= j} ->
actd:bool ->
Lemma (requires True)
(ensures
(log2c_bound j (32 - lv);
mt_olds_hs_lth_inv_ok #_ #f lv i j olds hs;
mt_hashes_lth_inv_log_converted_ #_ #f lv j (merge_hs #_ #f olds hs);
S.equal (mt_get_path_acc #_ #f j
(S.slice (merge_hs #_ #f olds hs) lv (lv + log2c j))
(S.slice rhs lv (lv + log2c j)) k actd)
(mt_get_path_ #_ lv hs rhs i j k S.empty actd)))
(decreases j)
#push-options "--z3rlimit 1000 --max_fuel 1 --max_ifuel 0"
let rec mt_get_path_acc_consistent #hsz #f lv i j olds hs rhs k actd =
log2c_bound j (32 - lv);
mt_olds_hs_lth_inv_ok #_ #f lv i j olds hs;
mt_hashes_lth_inv_log_converted_ #_ #f lv j (merge_hs #_ #f olds hs);
if j = 0 then ()
else begin
let nactd = if j % 2 = 0 then actd else true in
let nactd_ = actd || j % 2 = 1 in
assert (nactd == nactd_);
let pa = mt_get_path_acc #_ #f j
(S.slice (merge_hs #_ #f olds hs) lv (lv + log2c j))
(S.slice rhs lv (lv + log2c j)) k actd in
let p = mt_get_path_ lv hs rhs i j k S.empty actd in
log2c_div j; log2c_bound (j / 2) (32 - (lv + 1));
assert (mt_hashes_lth_inv (lv + 1) (j / 2) (merge_hs #_ #f olds hs));
assert (mt_hashes_lth_inv_log #hsz (j / 2)
(S.slice (merge_hs #_ #f olds hs) (lv + 1) (lv + 1 + log2c (j / 2))));
let npsa = mt_get_path_step_acc j
(S.index (merge_hs #_ #f olds hs) lv) (S.index rhs lv) k actd in
let npa = mt_get_path_acc #_ #f (j / 2)
(S.slice (merge_hs #_ #f olds hs) (lv + 1) (lv + 1 + log2c (j / 2)))
(S.slice rhs (lv + 1) (lv + 1 + log2c (j / 2))) (k / 2) nactd_ in
let nps = mt_make_path_step lv hs rhs i j k S.empty actd in
let np = mt_get_path_ (lv + 1) hs rhs (i / 2) (j / 2) (k / 2) nps nactd in
let npe = mt_get_path_ (lv + 1) hs rhs (i / 2) (j / 2) (k / 2) S.empty nactd in
mt_get_path_pull (lv + 1) hs rhs (i / 2) (j / 2) (k / 2) nps nactd;
assert (S.equal p np);
assert (S.equal np (S.append nps npe));
assert (S.equal p (S.append nps npe));
assert (S.equal pa (if Some? npsa
then S.cons (Some?.v npsa) npa
else npa));
mt_get_path_acc_consistent #_ #f (lv + 1) (i / 2) (j / 2)
olds hs rhs (k / 2) nactd;
assert (S.equal npa npe);
mt_get_path_step_acc_consistent #_ #f lv i j olds hs rhs k actd;
if Some? npsa
then begin
assert (S.equal nps (S.cons (Some?.v npsa) S.empty));
assert (S.equal p (S.append (S.cons (Some?.v npsa) S.empty) npa));
assert (S.equal pa (S.cons (Some?.v npsa) npa));
seq_cons_append (Some?.v npsa) npa;
assert (S.equal pa p)
end
else begin
assert (S.equal nps S.empty);
S.append_empty_l npe;
assert (S.equal p npe);
assert (S.equal pa npa);
assert (S.equal pa p)
end
end
#pop-options
val mt_get_path_acc_inv_ok:
#hsz:pos -> #f:MTS.hash_fun_t ->
j:nat ->
fhs:hashess #hsz {S.length fhs = log2c j} ->
rhs:hashes #hsz {S.length rhs = log2c j} ->
k:nat{k <= j} ->
acc:hash -> actd:bool ->
Lemma (requires (j > 0 /\
mt_hashes_lth_inv_log #hsz j fhs /\
mt_hashes_inv_log #_ #f j fhs /\
mt_rhs_inv #_ #f j (hash_seq_spec_full #_ #f (S.head fhs) acc actd) rhs actd))
(ensures (S.equal (path_spec k j actd (mt_get_path_acc #_ #f j fhs rhs k actd))
(MTS.mt_get_path #_ #f #(log2c j)
(hash_seq_spec_full #_ #f (S.head fhs) acc actd) k)))
(decreases j) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MerkleTree.Spec.fst.checked",
"MerkleTree.New.High.Correct.Rhs.fst.checked",
"MerkleTree.New.High.Correct.Base.fst.checked",
"MerkleTree.New.High.fst.checked",
"FStar.UInt8.fsti.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.fst.checked",
"FStar.Ghost.fsti.checked",
"FStar.Classical.fsti.checked",
"EverCrypt.Helpers.fsti.checked",
"EverCrypt.Hash.fsti.checked"
],
"interface_file": false,
"source_file": "MerkleTree.New.High.Correct.Path.fst"
} | [
{
"abbrev": false,
"full_module": "MerkleTree.New.High",
"short_module": null
},
{
"abbrev": true,
"full_module": "MerkleTree.Spec",
"short_module": "MTS"
},
{
"abbrev": true,
"full_module": "EverCrypt.Hash",
"short_module": "EHS"
},
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "FStar.List.Tot",
"short_module": "List"
},
{
"abbrev": false,
"full_module": "FStar.Seq",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Ghost",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Classical",
"short_module": null
},
{
"abbrev": false,
"full_module": "MerkleTree.New.High.Correct.Rhs",
"short_module": null
},
{
"abbrev": false,
"full_module": "MerkleTree.New.High.Correct.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "EverCrypt.Helpers",
"short_module": null
},
{
"abbrev": false,
"full_module": "EverCrypt",
"short_module": null
},
{
"abbrev": false,
"full_module": "MerkleTree.New.High.Correct",
"short_module": null
},
{
"abbrev": false,
"full_module": "MerkleTree.New.High.Correct",
"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": 1,
"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": 120,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
j: Prims.nat ->
fhs:
MerkleTree.New.High.hashess
{FStar.Seq.Base.length fhs = MerkleTree.New.High.Correct.Base.log2c j} ->
rhs:
MerkleTree.New.High.hashes
{FStar.Seq.Base.length rhs = MerkleTree.New.High.Correct.Base.log2c j} ->
k: Prims.nat{k <= j} ->
acc: MerkleTree.New.High.hash ->
actd: Prims.bool
-> FStar.Pervasives.Lemma
(requires
j > 0 /\ MerkleTree.New.High.Correct.Base.mt_hashes_lth_inv_log j fhs /\
MerkleTree.New.High.Correct.Base.mt_hashes_inv_log j fhs /\
MerkleTree.New.High.Correct.Base.mt_rhs_inv j
(MerkleTree.New.High.Correct.Base.hash_seq_spec_full (FStar.Seq.Properties.head fhs)
acc
actd)
rhs
actd)
(ensures
FStar.Seq.Base.equal (MerkleTree.New.High.Correct.Path.path_spec k
j
actd
(MerkleTree.New.High.Correct.Path.mt_get_path_acc j fhs rhs k actd))
(MerkleTree.Spec.mt_get_path (MerkleTree.New.High.Correct.Base.hash_seq_spec_full (FStar.Seq.Properties.head
fhs)
acc
actd)
k))
(decreases j) | FStar.Pervasives.Lemma | [
"lemma",
""
] | [] | [
"Prims.pos",
"MerkleTree.Spec.hash_fun_t",
"Prims.nat",
"MerkleTree.New.High.hashess",
"Prims.b2t",
"Prims.op_Equality",
"FStar.Seq.Base.length",
"MerkleTree.New.High.hashes",
"MerkleTree.New.High.Correct.Base.log2c",
"MerkleTree.New.High.hash",
"Prims.op_LessThanOrEqual",
"Prims.bool",
"Prims.int",
"Prims.unit",
"Prims.op_Modulus",
"Prims.op_BarBar",
"Prims.op_AmpAmp",
"Prims.op_Addition",
"Prims.op_Negation",
"Prims._assert",
"Prims.eq2",
"MerkleTree.Spec.padded_hash",
"FStar.Seq.Base.index",
"MerkleTree.Spec.HPad",
"MerkleTree.Spec.HRaw",
"FStar.Seq.Properties.head",
"MerkleTree.New.High.Correct.Base.hash_seq_spec_full_index_raw",
"Prims.op_Subtraction",
"MerkleTree.New.High.Correct.Path.mt_get_path_acc_inv_ok",
"Prims.op_Division",
"FStar.Seq.Properties.tail",
"MerkleTree.New.High.Correct.Base.hash_seq_spec_full_next",
"MerkleTree.New.High.Correct.Base.mt_hashes_lth_inv_log_next",
"FStar.Seq.Properties.last",
"MerkleTree.Spec.merkle_tree",
"MerkleTree.New.High.Correct.Base.hash_seq_spec_full",
"FStar.Pervasives.Native.option",
"MerkleTree.New.High.Correct.Path.mt_get_path_step_acc"
] | [
"recursion"
] | false | false | true | false | false | let rec mt_get_path_acc_inv_ok #_ #f j fhs rhs k acc actd =
| let _ = mt_get_path_step_acc j (S.head fhs) (S.head rhs) k actd in
let smt = hash_seq_spec_full #_ #f (S.head fhs) acc actd in
let nacc =
(if j % 2 = 0 then acc else if actd then f (S.last (S.head fhs)) acc else S.last (S.head fhs))
in
let nactd = actd || j % 2 = 1 in
if j = 1
then (if k = 0 then ())
else
(mt_hashes_lth_inv_log_next #_ #f j fhs;
hash_seq_spec_full_next #_ #f j (S.head fhs) (S.head (S.tail fhs)) acc actd nacc nactd;
mt_get_path_acc_inv_ok #_ #f (j / 2) (S.tail fhs) (S.tail rhs) (k / 2) nacc nactd;
if k % 2 = 0
then
if k = j || (k + 1 = j && not actd)
then assert (S.index smt (k + 1) == MTS.HPad)
else
if k + 1 = j
then assert (S.index smt (k + 1) == MTS.HRaw (S.head rhs))
else hash_seq_spec_full_index_raw #_ #f (S.head fhs) acc actd (k + 1)
else hash_seq_spec_full_index_raw #_ #f (S.head fhs) acc actd (k - 1)) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test9_plaintext_shake256 | val test9_plaintext_shake256:lbytes 0 | val test9_plaintext_shake256:lbytes 0 | let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 360,
"start_col": 0,
"start_line": 357
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 0 | 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.Nil"
] | [] | false | false | false | false | false | let test9_plaintext_shake256:lbytes 0 =
| let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test8_expected_shake128 | val test8_expected_shake128:lbytes 16 | val test8_expected_shake128:lbytes 16 | let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 352,
"start_col": 0,
"start_line": 346
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test8_expected_shake128:lbytes 16 =
| let l =
List.Tot.map u8_from_UInt8
[
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy; 0xaduy; 0x94uy; 0xb7uy; 0x97uy;
0xe9uy; 0xd4uy; 0xdduy; 0x30uy
]
in
assert_norm (List.Tot.length l == 16);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test4_expected_sha3_512 | val test4_expected_sha3_512:lbytes 64 | val test4_expected_sha3_512:lbytes 64 | let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 263,
"start_col": 0,
"start_line": 251
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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_expected_sha3_512:lbytes 64 =
| let l =
List.Tot.map u8_from_UInt8
[
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy; 0xc5uy; 0x0cuy; 0xaduy; 0x06uy;
0xd2uy; 0xe5uy; 0x78uy; 0xf9uy; 0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy; 0x73uy; 0xe3uy; 0x26uy; 0x11uy;
0x22uy; 0x94uy; 0x8euy; 0xfcuy; 0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy; 0x27uy; 0x0cuy; 0xb4uy; 0x55uy;
0xf2uy; 0x1duy; 0xd1uy; 0x85uy
]
in
assert_norm (List.Tot.length l == 64);
of_list l | false |
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.point_double | val point_double : BE.lsqr_st U64 15ul 0ul mk_to_k256_comm_monoid | val point_double : BE.lsqr_st U64 15ul 0ul mk_to_k256_comm_monoid | let point_double ctx x xx =
let h0 = ST.get () in
SL.to_aff_point_double_lemma (point_eval h0 x);
Hacl.Impl.K256.PointDouble.point_double xx x | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 46,
"end_line": 52,
"start_col": 0,
"start_line": 49
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p)
inline_for_extraction noextract
let mk_to_k256_comm_monoid : BE.to_comm_monoid U64 15ul 0ul = {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl;
}
inline_for_extraction noextract
val point_add : BE.lmul_st U64 15ul 0ul mk_to_k256_comm_monoid
let point_add ctx x y xy =
let h0 = ST.get () in
SL.to_aff_point_add_lemma (point_eval h0 x) (point_eval h0 y);
Hacl.Impl.K256.PointAdd.point_add xy x y
inline_for_extraction noextract | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | Hacl.Impl.Exponentiation.Definitions.lsqr_st Lib.IntTypes.U64
15ul
0ul
Hacl.Impl.K256.Group.mk_to_k256_comm_monoid | Prims.Tot | [
"total"
] | [] | [
"Lib.Buffer.lbuffer",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.UInt32.__uint_to_t",
"Hacl.Impl.K256.PointDouble.point_double",
"Prims.unit",
"Spec.K256.Lemmas.to_aff_point_double_lemma",
"Hacl.Impl.K256.Point.point_eval",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get"
] | [] | false | false | false | false | false | let point_double ctx x xx =
| let h0 = ST.get () in
SL.to_aff_point_double_lemma (point_eval h0 x);
Hacl.Impl.K256.PointDouble.point_double xx x | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test10_plaintext_shake256 | val test10_plaintext_shake256:lbytes 17 | val test10_plaintext_shake256:lbytes 17 | let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 383,
"start_col": 0,
"start_line": 376
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 17 | 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 test10_plaintext_shake256:lbytes 17 =
| let l =
List.Tot.map u8_from_UInt8
[
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy; 0x45uy; 0x4buy; 0xa6uy; 0x42uy;
0x98uy; 0x82uy; 0xb0uy; 0x54uy; 0x09uy
]
in
assert_norm (List.Tot.length l == 17);
of_list l | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.parse_ret_impl | val parse_ret_impl (#t: Type) (x: t) : Tot (parser_impl (parse_ret x)) | val parse_ret_impl (#t: Type) (x: t) : Tot (parser_impl (parse_ret x)) | let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul) | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 48,
"end_line": 30,
"start_col": 0,
"start_line": 26
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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: t -> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.parse_ret x) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"Prims.eq2",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Mktuple2",
"FStar.UInt32.__uint_to_t",
"FStar.Pervasives.Native.option",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"MiniParse.Impl.Base.parser_impl",
"MiniParse.Spec.Combinators.parse_ret"
] | [] | false | false | false | false | false | let parse_ret_impl (#t: Type) (x: t) : Tot (parser_impl (parse_ret x)) =
| fun _ _ ->
let h = HST.get () in
Some (x, 0ul) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test9_expected_shake256 | val test9_expected_shake256:lbytes 32 | val test9_expected_shake256:lbytes 32 | let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 371,
"start_col": 0,
"start_line": 363
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test9_expected_shake256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy; 0x23uy; 0x3buy; 0x3fuy; 0xebuy;
0x74uy; 0x3euy; 0xebuy; 0x24uy; 0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test7_plaintext_shake128 | val test7_plaintext_shake128:lbytes 34 | val test7_plaintext_shake128:lbytes 34 | let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 314,
"start_col": 0,
"start_line": 305
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 34 | 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_plaintext_shake128:lbytes 34 =
| let l =
List.Tot.map u8_from_UInt8
[
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy; 0x06uy; 0x67uy; 0xa4uy; 0x00uy;
0x20uy; 0xd6uy; 0x5fuy; 0xf5uy; 0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy; 0x00uy; 0x65uy
]
in
assert_norm (List.Tot.length l == 34);
of_list l | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.serialize_empty_impl | val serialize_empty_impl:serializer_impl serialize_empty | val serialize_empty_impl:serializer_impl serialize_empty | let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 45,
"end_line": 35,
"start_col": 0,
"start_line": 33
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 | MiniParse.Impl.Base.serializer_impl MiniParse.Spec.Combinators.serialize_empty | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"Prims.eq2",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"Prims.unit",
"FStar.Pervasives.Native.Some",
"FStar.UInt32.__uint_to_t",
"FStar.Pervasives.Native.option",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get"
] | [] | false | false | false | true | false | let serialize_empty_impl:serializer_impl serialize_empty =
| fun _ _ _ ->
let h = HST.get () in
Some 0ul | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.sha3_length | val sha3_length : a: Spec.SHA3.Test.keccak_alg -> Prims.int | let sha3_length (a:keccak_alg) =
allow_inversion keccak_alg;
match a with
| SHA3_224 -> 28
| SHA3_256 -> 32
| SHA3_384 -> 48
| SHA3_512 -> 64 | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 18,
"end_line": 467,
"start_col": 0,
"start_line": 461
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256
let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l
let test12_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy;
0x34uy; 0x06uy; 0x3buy; 0x5fuy; 0xc9uy; 0x21uy; 0x5fuy; 0xc3uy;
0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
type keccak_alg =
| SHA3_224
| SHA3_256
| SHA3_384
| SHA3_512
type shake_alg =
| SHAKE128
| SHAKE256 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 | a: Spec.SHA3.Test.keccak_alg -> Prims.int | Prims.Tot | [
"total"
] | [] | [
"Spec.SHA3.Test.keccak_alg",
"Prims.int",
"Prims.unit",
"FStar.Pervasives.allow_inversion"
] | [] | false | false | false | true | false | let sha3_length (a: keccak_alg) =
| allow_inversion keccak_alg;
match a with
| SHA3_224 -> 28
| SHA3_256 -> 32
| SHA3_384 -> 48
| SHA3_512 -> 64 | false |
|
Hacl.Impl.K256.Group.fst | Hacl.Impl.K256.Group.point_add | val point_add : BE.lmul_st U64 15ul 0ul mk_to_k256_comm_monoid | val point_add : BE.lmul_st U64 15ul 0ul mk_to_k256_comm_monoid | let point_add ctx x y xy =
let h0 = ST.get () in
SL.to_aff_point_add_lemma (point_eval h0 x) (point_eval h0 y);
Hacl.Impl.K256.PointAdd.point_add xy x y | {
"file_name": "code/k256/Hacl.Impl.K256.Group.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 42,
"end_line": 44,
"start_col": 0,
"start_line": 41
} | module Hacl.Impl.K256.Group
open FStar.HyperStack
open FStar.HyperStack.ST
open FStar.Mul
open Lib.IntTypes
open Lib.Buffer
module ST = FStar.HyperStack.ST
module LSeq = Lib.Sequence
module BE = Hacl.Impl.Exponentiation.Definitions
module S = Spec.K256
module SL = Spec.K256.Lemmas
open Hacl.Impl.K256.Point
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
unfold
let linv_ctx (a:LSeq.lseq uint64 0) : Type0 = True
unfold
let refl (p:LSeq.lseq uint64 15{point_inv_lseq p}) : GTot S.aff_point =
S.to_aff_point (point_eval_lseq p)
inline_for_extraction noextract
let mk_to_k256_comm_monoid : BE.to_comm_monoid U64 15ul 0ul = {
BE.a_spec = S.aff_point;
BE.comm_monoid = S.mk_k256_comm_monoid;
BE.linv_ctx = linv_ctx;
BE.linv = point_inv_lseq;
BE.refl = refl;
}
inline_for_extraction noextract | {
"checked_file": "/",
"dependencies": [
"Spec.K256.Lemmas.fsti.checked",
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.Sequence.fsti.checked",
"Lib.IntTypes.fsti.checked",
"Lib.Buffer.fsti.checked",
"Hacl.Impl.K256.PointDouble.fst.checked",
"Hacl.Impl.K256.PointAdd.fst.checked",
"Hacl.Impl.K256.Point.fsti.checked",
"Hacl.Impl.Exponentiation.Definitions.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.HyperStack.ST.fsti.checked",
"FStar.HyperStack.fst.checked"
],
"interface_file": false,
"source_file": "Hacl.Impl.K256.Group.fst"
} | [
{
"abbrev": false,
"full_module": "Hacl.Impl.K256.Point",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256.Lemmas",
"short_module": "SL"
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": true,
"full_module": "Hacl.Impl.Exponentiation.Definitions",
"short_module": "BE"
},
{
"abbrev": true,
"full_module": "Lib.Sequence",
"short_module": "LSeq"
},
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "ST"
},
{
"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.ST",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.HyperStack",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Impl.K256",
"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 | Hacl.Impl.Exponentiation.Definitions.lmul_st Lib.IntTypes.U64
15ul
0ul
Hacl.Impl.K256.Group.mk_to_k256_comm_monoid | Prims.Tot | [
"total"
] | [] | [
"Lib.Buffer.lbuffer",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U64",
"Lib.IntTypes.SEC",
"FStar.UInt32.__uint_to_t",
"Hacl.Impl.K256.PointAdd.point_add",
"Prims.unit",
"Spec.K256.Lemmas.to_aff_point_add_lemma",
"Hacl.Impl.K256.Point.point_eval",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get"
] | [] | false | false | false | false | false | let point_add ctx x y xy =
| let h0 = ST.get () in
SL.to_aff_point_add_lemma (point_eval h0 x) (point_eval h0 y);
Hacl.Impl.K256.PointAdd.point_add xy x y | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.seq_append_slice | val seq_append_slice (#t: Type) (s: Seq.seq t) (i1 i2: nat)
: Lemma (requires (i1 + i2 <= Seq.length s))
(ensures (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2))
) | val seq_append_slice (#t: Type) (s: Seq.seq t) (i1 i2: nat)
: Lemma (requires (i1 + i2 <= Seq.length s))
(ensures (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2))
) | let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2)) | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 103,
"end_line": 80,
"start_col": 0,
"start_line": 71
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y))) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 | s: FStar.Seq.Base.seq t -> i1: Prims.nat -> i2: Prims.nat
-> FStar.Pervasives.Lemma (requires i1 + i2 <= FStar.Seq.Base.length s)
(ensures
FStar.Seq.Base.append (FStar.Seq.Base.slice s 0 i1) (FStar.Seq.Base.slice s i1 (i1 + i2)) ==
FStar.Seq.Base.slice s 0 (i1 + i2)) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"FStar.Seq.Base.seq",
"Prims.nat",
"Prims._assert",
"FStar.Seq.Base.equal",
"FStar.Seq.Base.append",
"FStar.Seq.Base.slice",
"Prims.op_Addition",
"Prims.unit",
"Prims.b2t",
"Prims.op_LessThanOrEqual",
"FStar.Seq.Base.length",
"Prims.squash",
"Prims.eq2",
"Prims.Nil",
"FStar.Pervasives.pattern"
] | [] | true | false | true | false | false | let seq_append_slice (#t: Type) (s: Seq.seq t) (i1 i2: nat)
: Lemma (requires (i1 + i2 <= Seq.length s))
(ensures (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2))
) =
| assert ((Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)))
`Seq.equal`
(Seq.slice s 0 (i1 + i2))) | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.parse_nondep_then_impl | val parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2': parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2)) | val parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2': parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2)) | let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y))) | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 103,
"end_line": 69,
"start_col": 0,
"start_line": 61
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16" | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 | p1': MiniParse.Impl.Base.parser_impl p1 -> p2': MiniParse.Impl.Base.parser_impl p2
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.nondep_then p1 p2) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Impl.Base.parser_impl",
"MiniParse.Impl.Combinators.parse_and_then_impl",
"FStar.Pervasives.Native.tuple2",
"MiniParse.Spec.Combinators.and_then",
"MiniParse.Spec.Combinators.parse_ret",
"FStar.Pervasives.Native.Mktuple2",
"MiniParse.Impl.Combinators.parse_ret_impl",
"MiniParse.Spec.Combinators.nondep_then"
] | [] | false | false | false | false | false | let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2': parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2)) =
| parse_and_then_impl p1'
_
()
(fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y))) | false |
LowParse.Bytes.fst | LowParse.Bytes.bytes_equal_elim | val bytes_equal_elim (b1 b2: bytes) : Lemma
(requires (b1 `bytes_equal` b2))
(ensures (b1 == b2))
[SMTPat (b1 `bytes_equal` b2)] | val bytes_equal_elim (b1 b2: bytes) : Lemma
(requires (b1 `bytes_equal` b2))
(ensures (b1 == b2))
[SMTPat (b1 `bytes_equal` b2)] | let bytes_equal_elim (b1 b2: bytes) : Lemma
(requires (b1 `bytes_equal` b2))
(ensures (b1 == b2))
[SMTPat (b1 `bytes_equal` b2)]
= assert (b1 `Seq.equal` b2) | {
"file_name": "src/lowparse/LowParse.Bytes.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 28,
"end_line": 29,
"start_col": 0,
"start_line": 25
} | module LowParse.Bytes
module Seq = FStar.Seq
module U8 = FStar.UInt8
let bytes_equal (b1 b2: bytes) : GTot Type0 =
Seq.length b1 == Seq.length b2 /\
(forall (i: nat { i < Seq.length b1 } ) . {:pattern (Seq.index b1 i); (Seq.index b2 i) } U8.v (Seq.index b1 i) == U8.v (Seq.index b2 i))
let bytes_equal_intro (b1 b2: bytes) : Lemma
(requires (
Seq.length b1 == Seq.length b2 /\
(forall (i: nat { i < Seq.length b1 } ) . U8.v (Seq.index b1 i) == U8.v (Seq.index b2 i))
))
(ensures (bytes_equal b1 b2))
[SMTPat (bytes_equal b1 b2)]
= ()
let bytes_equal_refl (b1 b2: bytes) : Lemma
(requires (b1 == b2))
(ensures (b1 `bytes_equal` b2))
[SMTPat (bytes_equal b1 b2)]
= () | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Bytes.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse",
"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 | b1: LowParse.Bytes.bytes -> b2: LowParse.Bytes.bytes
-> FStar.Pervasives.Lemma (requires LowParse.Bytes.bytes_equal b1 b2)
(ensures b1 == b2)
[SMTPat (LowParse.Bytes.bytes_equal b1 b2)] | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"LowParse.Bytes.bytes",
"Prims._assert",
"FStar.Seq.Base.equal",
"LowParse.Bytes.byte",
"Prims.unit",
"LowParse.Bytes.bytes_equal",
"Prims.squash",
"Prims.eq2",
"Prims.Cons",
"FStar.Pervasives.pattern",
"FStar.Pervasives.smt_pat",
"Prims.Nil"
] | [] | true | false | true | false | false | let bytes_equal_elim (b1 b2: bytes)
: Lemma (requires (b1 `bytes_equal` b2)) (ensures (b1 == b2)) [SMTPat (b1 `bytes_equal` b2)] =
| assert (b1 `Seq.equal` b2) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test_one | val test_one : v: Spec.SHA3.Test.vec -> FStar.All.ALL Prims.bool | let test_one (v:vec) =
let computed, expected =
match v with
| Vec SHA3_224 plain tag -> Spec.SHA3.sha3_224 (length plain) plain, tag
| Vec SHA3_256 plain tag -> Spec.SHA3.sha3_256 (length plain) plain, tag
| Vec SHA3_384 plain tag -> Spec.SHA3.sha3_384 (length plain) plain, tag
| Vec SHA3_512 plain tag -> Spec.SHA3.sha3_512 (length plain) plain, tag
| Vec1 SHAKE128 plain tag -> Spec.SHA3.shake128 (length plain) plain (length tag), tag
| Vec1 SHAKE256 plain tag -> Spec.SHA3.shake256 (length plain) plain (length tag), tag in
assert (length expected = length computed);
PS.print_compare true (length expected) expected computed | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 59,
"end_line": 526,
"start_col": 0,
"start_line": 516
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256
let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l
let test12_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy;
0x34uy; 0x06uy; 0x3buy; 0x5fuy; 0xc9uy; 0x21uy; 0x5fuy; 0xc3uy;
0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
type keccak_alg =
| SHA3_224
| SHA3_256
| SHA3_384
| SHA3_512
type shake_alg =
| SHAKE128
| SHAKE256
let sha3_length (a:keccak_alg) =
allow_inversion keccak_alg;
match a with
| SHA3_224 -> 28
| SHA3_256 -> 32
| SHA3_384 -> 48
| SHA3_512 -> 64
noeq type vec =
| Vec :
a:keccak_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash = sha3_length a} -> vec
| Vec1 :
a:shake_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash <= max_size_t} -> vec
let test_vectors : list vec = [
Vec SHA3_224 test1_plaintext test1_expected_sha3_224;
Vec SHA3_256 test1_plaintext test1_expected_sha3_256;
Vec SHA3_384 test1_plaintext test1_expected_sha3_384;
Vec SHA3_512 test1_plaintext test1_expected_sha3_512;
Vec SHA3_224 test2_plaintext test2_expected_sha3_224;
Vec SHA3_256 test2_plaintext test2_expected_sha3_256;
Vec SHA3_384 test2_plaintext test2_expected_sha3_384;
Vec SHA3_512 test2_plaintext test2_expected_sha3_512;
Vec SHA3_224 test3_plaintext test3_expected_sha3_224;
Vec SHA3_256 test3_plaintext test3_expected_sha3_256;
Vec SHA3_384 test3_plaintext test3_expected_sha3_384;
Vec SHA3_512 test3_plaintext test3_expected_sha3_512;
Vec SHA3_224 test4_plaintext test4_expected_sha3_224;
Vec SHA3_256 test4_plaintext test4_expected_sha3_256;
Vec SHA3_384 test4_plaintext test4_expected_sha3_384;
Vec SHA3_512 test4_plaintext test4_expected_sha3_512;
Vec1 SHAKE128 test5_plaintext_shake128 test5_expected_shake128;
Vec1 SHAKE128 test6_plaintext_shake128 test6_expected_shake128;
Vec1 SHAKE128 test7_plaintext_shake128 test7_expected_shake128;
Vec1 SHAKE128 test8_plaintext_shake128 test8_expected_shake128;
Vec1 SHAKE256 test9_plaintext_shake256 test9_expected_shake256;
Vec1 SHAKE256 test10_plaintext_shake256 test10_expected_shake256;
Vec1 SHAKE256 test11_plaintext_shake256 test11_expected_shake256;
Vec1 SHAKE256 test12_plaintext_shake256 test12_expected_shake256
]
#set-options "--ifuel 1" | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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": 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": 50,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false | v: Spec.SHA3.Test.vec -> FStar.All.ALL Prims.bool | FStar.All.ALL | [] | [] | [
"Spec.SHA3.Test.vec",
"Lib.Sequence.seq",
"Lib.IntTypes.uint_t",
"Lib.IntTypes.U8",
"Lib.IntTypes.SEC",
"Lib.PrintSequence.print_compare",
"Lib.Sequence.length",
"Prims.bool",
"Prims.unit",
"Prims._assert",
"Prims.b2t",
"Prims.op_Equality",
"Prims.nat",
"FStar.Pervasives.Native.tuple2",
"Lib.IntTypes.int_t",
"Lib.ByteSequence.bytes",
"Prims.op_LessThanOrEqual",
"Lib.IntTypes.max_size_t",
"Prims.int",
"Spec.SHA3.Test.sha3_length",
"Spec.SHA3.Test.SHA3_224",
"FStar.Pervasives.Native.Mktuple2",
"Spec.SHA3.sha3_224",
"Spec.SHA3.Test.SHA3_256",
"Spec.SHA3.sha3_256",
"Spec.SHA3.Test.SHA3_384",
"Spec.SHA3.sha3_384",
"Spec.SHA3.Test.SHA3_512",
"Spec.SHA3.sha3_512",
"Spec.SHA3.shake128",
"Spec.SHA3.shake256"
] | [] | false | true | false | false | false | let test_one (v: vec) =
| let computed, expected =
match v with
| Vec SHA3_224 plain tag -> Spec.SHA3.sha3_224 (length plain) plain, tag
| Vec SHA3_256 plain tag -> Spec.SHA3.sha3_256 (length plain) plain, tag
| Vec SHA3_384 plain tag -> Spec.SHA3.sha3_384 (length plain) plain, tag
| Vec SHA3_512 plain tag -> Spec.SHA3.sha3_512 (length plain) plain, tag
| Vec1 SHAKE128 plain tag -> Spec.SHA3.shake128 (length plain) plain (length tag), tag
| Vec1 SHAKE256 plain tag -> Spec.SHA3.shake256 (length plain) plain (length tag), tag
in
assert (length expected = length computed);
PS.print_compare true (length expected) expected computed | false |
|
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.parse_synth_impl | val parse_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(f2: (t1 -> GTot t2))
(f2': (x: t1 -> Tot (y: t2{y == f2 x})))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse g1 f2))
: Tot (parser_impl (parse_synth p1 f2 g1)) | val parse_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(f2: (t1 -> GTot t2))
(f2': (x: t1 -> Tot (y: t2{y == f2 x})))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse g1 f2))
: Tot (parser_impl (parse_synth p1 f2 g1)) | let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 15,
"end_line": 128,
"start_col": 0,
"start_line": 113
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
p1': MiniParse.Impl.Base.parser_impl p1 ->
f2: (_: t1 -> Prims.GTot t2) ->
f2': (x: t1 -> y: t2{y == f2 x}) ->
g1: (_: t2 -> Prims.GTot t1) ->
u81: Prims.squash (MiniParse.Spec.Combinators.synth_inverse g1 f2)
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.parse_synth p1 f2 g1) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Impl.Base.parser_impl",
"Prims.eq2",
"Prims.squash",
"MiniParse.Spec.Combinators.synth_inverse",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Pervasives.Native.option",
"FStar.Pervasives.Native.None",
"MiniParse.Spec.Combinators.parse_synth"
] | [] | false | false | false | false | false | let parse_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(p1': parser_impl p1)
(f2: (t1 -> GTot t2))
(f2': (x: t1 -> Tot (y: t2{y == f2 x})))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse g1 f2))
: Tot (parser_impl (parse_synth p1 f2 g1)) =
| fun (input: buffer8) (len: U32.t{len == B.len input}) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None | false |
LowParse.Bytes.fst | LowParse.Bytes.bytes_equal | val bytes_equal (b1 b2: bytes) : GTot Type0 | val bytes_equal (b1 b2: bytes) : GTot Type0 | let bytes_equal (b1 b2: bytes) : GTot Type0 =
Seq.length b1 == Seq.length b2 /\
(forall (i: nat { i < Seq.length b1 } ) . {:pattern (Seq.index b1 i); (Seq.index b2 i) } U8.v (Seq.index b1 i) == U8.v (Seq.index b2 i)) | {
"file_name": "src/lowparse/LowParse.Bytes.fst",
"git_rev": "00217c4a89f5ba56002ba9aa5b4a9d5903bfe9fa",
"git_url": "https://github.com/project-everest/everparse.git",
"project_name": "everparse"
} | {
"end_col": 138,
"end_line": 8,
"start_col": 0,
"start_line": 6
} | module LowParse.Bytes
module Seq = FStar.Seq
module U8 = FStar.UInt8 | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.UInt8.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": true,
"source_file": "LowParse.Bytes.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.UInt8",
"short_module": "U8"
},
{
"abbrev": true,
"full_module": "FStar.Seq",
"short_module": "Seq"
},
{
"abbrev": false,
"full_module": "LowParse",
"short_module": null
},
{
"abbrev": false,
"full_module": "LowParse",
"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 | b1: LowParse.Bytes.bytes -> b2: LowParse.Bytes.bytes -> Prims.GTot Type0 | Prims.GTot | [
"sometrivial"
] | [] | [
"LowParse.Bytes.bytes",
"Prims.l_and",
"Prims.eq2",
"Prims.nat",
"FStar.Seq.Base.length",
"LowParse.Bytes.byte",
"Prims.l_Forall",
"Prims.b2t",
"Prims.op_LessThan",
"FStar.UInt.uint_t",
"FStar.UInt8.n",
"FStar.UInt8.v",
"FStar.Seq.Base.index"
] | [] | false | false | false | false | true | let bytes_equal (b1 b2: bytes) : GTot Type0 =
| Seq.length b1 == Seq.length b2 /\
(forall (i: nat{i < Seq.length b1}). {:pattern (Seq.index b1 i); (Seq.index b2 i)}
U8.v (Seq.index b1 i) == U8.v (Seq.index b2 i)) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test10_expected_shake256 | val test10_expected_shake256:lbytes 32 | val test10_expected_shake256:lbytes 32 | let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 394,
"start_col": 0,
"start_line": 386
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test10_expected_shake256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy; 0xe1uy; 0x9euy; 0x2cuy; 0x84uy;
0x20uy; 0xa7uy; 0xeauy; 0x85uy; 0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.serialize_synth_impl' | val serialize_synth_impl'
(#t1 #t2: Type0)
(g1': (x: t2 -> Tot t1))
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
(v: squash ((forall (x: t2). g1' x == g1 x)))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) | val serialize_synth_impl'
(#t1 #t2: Type0)
(g1': (x: t2 -> Tot t1))
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
(v: squash ((forall (x: t2). g1' x == g1 x)))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) | let serialize_synth_impl'
(#t1: Type0)
(#t2: Type0)
(g1': (x: t2) -> Tot t1)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
(v: squash (
(forall (x: t2) . g1' x == g1 x)
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= serialize_synth_impl s1' f2 g1 (fun x -> g1' x) () | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 52,
"end_line": 167,
"start_col": 0,
"start_line": 150
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None
inline_for_extraction
let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
g1': (x: t2 -> t1) ->
s1': MiniParse.Impl.Base.serializer_impl s1 ->
f2: (_: t1 -> Prims.GTot t2) ->
g1: (_: t2 -> Prims.GTot t1) ->
u121:
Prims.squash (MiniParse.Spec.Combinators.synth_inverse f2 g1 /\
MiniParse.Spec.Combinators.synth_inverse g1 f2) ->
v: Prims.squash (forall (x: t2). g1' x == g1 x)
-> MiniParse.Impl.Base.serializer_impl (MiniParse.Spec.Combinators.serialize_synth s1 f2 g1 u121) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Spec.Base.serializer_spec",
"MiniParse.Impl.Base.serializer_impl",
"Prims.squash",
"Prims.l_and",
"MiniParse.Spec.Combinators.synth_inverse",
"Prims.l_Forall",
"Prims.eq2",
"MiniParse.Impl.Combinators.serialize_synth_impl",
"MiniParse.Spec.Combinators.parse_synth",
"MiniParse.Spec.Combinators.serialize_synth"
] | [] | false | false | false | false | false | let serialize_synth_impl'
(#t1 #t2: Type0)
(g1': (x: t2 -> Tot t1))
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
(v: squash ((forall (x: t2). g1' x == g1 x)))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) =
| serialize_synth_impl s1' f2 g1 (fun x -> g1' x) () | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.serialize_synth_impl | val serialize_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(g1': (x: t2 -> Tot (y: t1{y == g1 x})))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) | val serialize_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(g1': (x: t2 -> Tot (y: t1{y == g1 x})))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) | let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 20,
"end_line": 147,
"start_col": 0,
"start_line": 131
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
s1': MiniParse.Impl.Base.serializer_impl s1 ->
f2: (_: t1 -> Prims.GTot t2) ->
g1: (_: t2 -> Prims.GTot t1) ->
g1': (x: t2 -> y: t1{y == g1 x}) ->
u100:
Prims.squash (MiniParse.Spec.Combinators.synth_inverse f2 g1 /\
MiniParse.Spec.Combinators.synth_inverse g1 f2)
-> MiniParse.Impl.Base.serializer_impl (MiniParse.Spec.Combinators.serialize_synth s1 f2 g1 u100) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Spec.Base.serializer_spec",
"MiniParse.Impl.Base.serializer_impl",
"Prims.eq2",
"Prims.squash",
"Prims.l_and",
"MiniParse.Spec.Combinators.synth_inverse",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.option",
"MiniParse.Spec.Combinators.parse_synth",
"MiniParse.Spec.Combinators.serialize_synth"
] | [] | false | false | false | false | false | let serialize_synth_impl
(#t1 #t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(f2: (t1 -> GTot t2))
(g1: (t2 -> GTot t1))
(g1': (x: t2 -> Tot (y: t1{y == g1 x})))
(u: squash (synth_inverse f2 g1 /\ synth_inverse g1 f2))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u)) =
| fun (output: buffer8) (len: U32.t{len == B.len output}) (input: t2) ->
let x = g1' input in
s1' output len x | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test11_plaintext_shake256 | val test11_plaintext_shake256:lbytes 32 | val test11_plaintext_shake256:lbytes 32 | let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 407,
"start_col": 0,
"start_line": 399
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test11_plaintext_shake256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy; 0x91uy; 0x78uy; 0xa1uy; 0xbbuy;
0x1cuy; 0x99uy; 0x39uy; 0x46uy; 0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.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\nSHA3 : Success!\n"; true end
else begin IO.print_string "\n\nSHA3: Failure :(\n"; false end | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 64,
"end_line": 532,
"start_col": 0,
"start_line": 529
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256
let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l
let test12_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy;
0x34uy; 0x06uy; 0x3buy; 0x5fuy; 0xc9uy; 0x21uy; 0x5fuy; 0xc3uy;
0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
type keccak_alg =
| SHA3_224
| SHA3_256
| SHA3_384
| SHA3_512
type shake_alg =
| SHAKE128
| SHAKE256
let sha3_length (a:keccak_alg) =
allow_inversion keccak_alg;
match a with
| SHA3_224 -> 28
| SHA3_256 -> 32
| SHA3_384 -> 48
| SHA3_512 -> 64
noeq type vec =
| Vec :
a:keccak_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash = sha3_length a} -> vec
| Vec1 :
a:shake_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash <= max_size_t} -> vec
let test_vectors : list vec = [
Vec SHA3_224 test1_plaintext test1_expected_sha3_224;
Vec SHA3_256 test1_plaintext test1_expected_sha3_256;
Vec SHA3_384 test1_plaintext test1_expected_sha3_384;
Vec SHA3_512 test1_plaintext test1_expected_sha3_512;
Vec SHA3_224 test2_plaintext test2_expected_sha3_224;
Vec SHA3_256 test2_plaintext test2_expected_sha3_256;
Vec SHA3_384 test2_plaintext test2_expected_sha3_384;
Vec SHA3_512 test2_plaintext test2_expected_sha3_512;
Vec SHA3_224 test3_plaintext test3_expected_sha3_224;
Vec SHA3_256 test3_plaintext test3_expected_sha3_256;
Vec SHA3_384 test3_plaintext test3_expected_sha3_384;
Vec SHA3_512 test3_plaintext test3_expected_sha3_512;
Vec SHA3_224 test4_plaintext test4_expected_sha3_224;
Vec SHA3_256 test4_plaintext test4_expected_sha3_256;
Vec SHA3_384 test4_plaintext test4_expected_sha3_384;
Vec SHA3_512 test4_plaintext test4_expected_sha3_512;
Vec1 SHAKE128 test5_plaintext_shake128 test5_expected_shake128;
Vec1 SHAKE128 test6_plaintext_shake128 test6_expected_shake128;
Vec1 SHAKE128 test7_plaintext_shake128 test7_expected_shake128;
Vec1 SHAKE128 test8_plaintext_shake128 test8_expected_shake128;
Vec1 SHAKE256 test9_plaintext_shake256 test9_expected_shake256;
Vec1 SHAKE256 test10_plaintext_shake256 test10_expected_shake256;
Vec1 SHAKE256 test11_plaintext_shake256 test11_expected_shake256;
Vec1 SHAKE256 test12_plaintext_shake256 test12_expected_shake256
]
#set-options "--ifuel 1"
let test_one (v:vec) =
let computed, expected =
match v with
| Vec SHA3_224 plain tag -> Spec.SHA3.sha3_224 (length plain) plain, tag
| Vec SHA3_256 plain tag -> Spec.SHA3.sha3_256 (length plain) plain, tag
| Vec SHA3_384 plain tag -> Spec.SHA3.sha3_384 (length plain) plain, tag
| Vec SHA3_512 plain tag -> Spec.SHA3.sha3_512 (length plain) plain, tag
| Vec1 SHAKE128 plain tag -> Spec.SHA3.shake128 (length plain) plain (length tag), tag
| Vec1 SHAKE256 plain tag -> Spec.SHA3.shake256 (length plain) plain (length tag), tag in
assert (length expected = length computed);
PS.print_compare true (length expected) expected computed | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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": 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": 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.SHA3.Test.vec",
"Spec.SHA3.Test.test_one",
"Spec.SHA3.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\nSHA3 : Success!\n";
true)
else
(IO.print_string "\n\nSHA3: Failure :(\n";
false) | false |
|
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.parse_and_then_impl | val parse_and_then_impl
(#t: Type)
(#p: parser_spec t)
(p32: parser_impl p)
(#t': Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32': (x: t -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p')) | val parse_and_then_impl
(#t: Type)
(#p: parser_spec t)
(p32: parser_impl p)
(#t': Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32': (x: t -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p')) | let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 13,
"end_line": 56,
"start_col": 0,
"start_line": 38
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
p32: MiniParse.Impl.Base.parser_impl p ->
p': (_: t -> MiniParse.Spec.Base.parser_spec t') ->
u23: Prims.squash (MiniParse.Spec.Combinators.and_then_cases_injective p') ->
p32': (x: t -> MiniParse.Impl.Base.parser_impl (p' x))
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.and_then p p') | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Impl.Base.parser_impl",
"Prims.squash",
"MiniParse.Spec.Combinators.and_then_cases_injective",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"Prims.eq2",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Mktuple2",
"FStar.UInt32.add",
"FStar.Pervasives.Native.option",
"FStar.Pervasives.Native.None",
"FStar.UInt32.sub",
"LowStar.Monotonic.Buffer.mbuffer",
"LowStar.Buffer.offset",
"MiniParse.Spec.Combinators.and_then"
] | [] | false | false | false | false | false | let parse_and_then_impl
(#t: Type)
(#p: parser_spec t)
(p32: parser_impl p)
(#t': Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32': (x: t -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p')) =
| fun (input: buffer8) (len: U32.t{len == B.len input}) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
(match p32' v input' (len `U32.sub` l) with
| Some (v', l') -> Some (v', U32.add l l')
| _ -> None)
| _ -> None | false |
Hacl.Spec.K256.Field52.Lemmas4.fst | Hacl.Spec.K256.Field52.Lemmas4.lemma_fmul_ab | val lemma_fmul_ab (a0 a1 a2 a3 a4 b0 b1 b2 b3 b4:nat) :
Lemma
(let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let r = 0x1000003D10 in
(a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208) *
(b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208) % S.prime =
(sum0 + sum5 * r + (sum1 + sum6 * r) * pow2 52 + (sum2 + r * sum7) * pow2 104
+ (sum3 + r * sum8) * pow2 156 + sum4 * pow2 208) % S.prime) | val lemma_fmul_ab (a0 a1 a2 a3 a4 b0 b1 b2 b3 b4:nat) :
Lemma
(let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let r = 0x1000003D10 in
(a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208) *
(b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208) % S.prime =
(sum0 + sum5 * r + (sum1 + sum6 * r) * pow2 52 + (sum2 + r * sum7) * pow2 104
+ (sum3 + r * sum8) * pow2 156 + sum4 * pow2 208) % S.prime) | let lemma_fmul_ab a0 a1 a2 a3 a4 b0 b1 b2 b3 b4 =
let r = 0x1000003D10 in
let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let a_sum = a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208 in
let b_sum = b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208 in
let tmp0 = sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208 in
let tmp1 = sum5 + sum6 * pow2 52 + sum7 * pow2 104 + sum8 * pow2 156 in
calc (==) {
a_sum * b_sum % S.prime;
(==) { lemma_mul_ab a0 a1 a2 a3 a4 b0 b1 b2 b3 b4 }
(tmp0 + pow2 260 * tmp1) % S.prime;
(==) { Math.Lemmas.pow2_plus 256 4; Math.Lemmas.paren_mul_right (pow2 256) (pow2 4) tmp1 }
(tmp0 + pow2 256 * (pow2 4 * tmp1)) % S.prime;
(==) { LD.lemma_a_plus_b_mul_pow256 tmp0 (pow2 4 * tmp1) }
(tmp0 + 0x1000003D1 * (pow2 4 * tmp1)) % S.prime;
(==) { Math.Lemmas.paren_mul_right 0x1000003D1 (pow2 4) tmp1; assert_norm (0x1000003D1 * pow2 4 = r) }
(tmp0 + r * tmp1) % S.prime;
(==) { ML.lemma_distr5_pow52 r sum5 sum6 sum7 sum8 0 }
(sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ r * sum5 + r * sum6 * pow2 52 + r * sum7 * pow2 104 + r * sum8 * pow2 156) % S.prime;
(==) { Math.Lemmas.distributivity_add_left sum1 (r * sum6) (pow2 52) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ r * sum7 * pow2 104 + r * sum8 * pow2 156) % S.prime;
(==) { Math.Lemmas.distributivity_add_left sum2 (r * sum7) (pow2 104) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + (sum2 + r * sum7) * pow2 104
+ sum3 * pow2 156 + sum4 * pow2 208 + r * sum8 * pow2 156) % S.prime;
(==) { Math.Lemmas.distributivity_add_left sum3 (r * sum8) (pow2 156) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + (sum2 + r * sum7) * pow2 104
+ (sum3 + r * sum8) * pow2 156 + sum4 * pow2 208) % S.prime;
} | {
"file_name": "code/k256/Hacl.Spec.K256.Field52.Lemmas4.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 5,
"end_line": 353,
"start_col": 0,
"start_line": 314
} | module Hacl.Spec.K256.Field52.Lemmas4
open FStar.Mul
open Lib.IntTypes
module S = Spec.K256
include Hacl.Spec.K256.Field52.Definitions
include Hacl.Spec.K256.Field52
module ML = Hacl.Spec.K256.MathLemmas
module LD = Hacl.Spec.K256.Field52.Definitions.Lemmas
#set-options "--z3rlimit 100 --fuel 0 --ifuel 0"
val lemma_nat_r432 (r2 r3 r4 c9 c11 d4 d11 t3 r:nat) : Lemma
(requires
r2 = c9 % pow2 52 /\ c11 = c9 / pow2 52 + r * pow2 12 * d11 + t3 /\
r3 = c11 % pow2 52 /\ r4 = c11 / pow2 52 + (d4 % pow2 52) % pow2 48)
(ensures
(r4 * pow2 52 + r3) * pow2 52 + r2 =
c9 + r * d11 * pow2 64 + t3 * pow2 52 + (d4 % pow2 48) * pow2 104)
let lemma_nat_r432 r2 r3 r4 c9 c11 d4 d11 t3 r =
let k = d4 % pow2 48 in
calc (==) {
(r4 * pow2 52 + r3) * pow2 52 + r2;
(==) { Math.Lemmas.pow2_modulo_modulo_lemma_1 d4 48 52 }
((c11 / pow2 52 + k) * pow2 52 + c11 % pow2 52) * pow2 52 + r2;
(==) { ML.lemma_distr_eucl c11 k }
(c9 / pow2 52 + r * pow2 12 * d11 + t3 + k * pow2 52) * pow2 52 + c9 % pow2 52;
(==) { ML.lemma_distr_eucl c9 (r * pow2 12 * d11 + t3 + k * pow2 52) }
c9 + (r * pow2 12 * d11 + t3 + k * pow2 52) * pow2 52;
(==) { ML.lemma_distr_pow (r * pow2 12 * d11 + t3) k 52 52 }
c9 + (r * pow2 12 * d11 + t3) * pow2 52 + k * pow2 104;
(==) { ML.lemma_swap_mul3 r (pow2 12) d11 }
c9 + (r * d11 * pow2 12 + t3) * pow2 52 + k * pow2 104;
(==) { ML.lemma_distr_pow t3 (r * d11) 12 52 }
c9 + r * d11 * pow2 64 + t3 * pow2 52 + k * pow2 104;
}
val lemma_nat_r4321 (r1 r2 r3 r4 c6 c9 c11 d4 d10 d11 t3 r sum2:nat) : Lemma
(requires
d11 = d10 / pow2 64 /\
r1 = c6 % pow2 52 /\ c9 = c6 / pow2 52 + sum2 + r * (d10 % pow2 64) /\
r2 = c9 % pow2 52 /\ c11 = c9 / pow2 52 + r * pow2 12 * d11 + t3 /\
r3 = c11 % pow2 52 /\ r4 = c11 / pow2 52 + (d4 % pow2 52) % pow2 48)
(ensures
((r4 * pow2 52 + r3) * pow2 52 + r2) * pow2 52 + r1 =
c6 + sum2 * pow2 52 + r * d10 * pow2 52 + t3 * pow2 104 + (d4 % pow2 48) * pow2 156)
let lemma_nat_r4321 r1 r2 r3 r4 c6 c9 c11 d4 d10 d11 t3 r sum2 =
let k = d4 % pow2 48 in
let tmp1 = t3 * pow2 52 + k * pow2 104 in
calc (==) {
((r4 * pow2 52 + r3) * pow2 52 + r2) * pow2 52 + r1;
(==) { lemma_nat_r432 r2 r3 r4 c9 c11 d4 d11 t3 r }
(c9 + r * d11 * pow2 64 + tmp1) * pow2 52 + r1;
(==) { }
(c6 / pow2 52 + sum2 + r * (d10 % pow2 64) + r * d11 * pow2 64 + tmp1) * pow2 52 + c6 % pow2 52;
(==) { ML.lemma_distr_eucl_mul r d10 (pow2 64) }
(c6 / pow2 52 + sum2 + r * d10 + tmp1) * pow2 52 + c6 % pow2 52;
(==) { ML.lemma_distr_eucl c6 (sum2 + r * d10 + tmp1) }
c6 + (sum2 + r * d10 + tmp1) * pow2 52;
(==) { Math.Lemmas.distributivity_add_left (sum2 + r * d10) tmp1 (pow2 52) }
c6 + (sum2 + r * d10) * pow2 52 + tmp1 * pow2 52;
(==) { Math.Lemmas.distributivity_add_left sum2 (r * d10) (pow2 52) }
c6 + sum2 * pow2 52 + r * d10 * pow2 52 + tmp1 * pow2 52;
(==) { ML.lemma_distr_pow_pow t3 52 k 104 52 }
c6 + sum2 * pow2 52 + r * d10 * pow2 52 + t3 * pow2 104 + k * pow2 156;
}
val lemma_nat_r43210 (r0 r1 r2 r3 r4 c3 c6 c9 c11 d4 d8 d10 d11 t3 r sum1 sum2 sum7:nat) : Lemma
(requires
d10 == d8 / pow2 52 + sum7 /\
r0 = c3 % pow2 52 /\ c6 = c3 / pow2 52 + sum1 + d8 % pow2 52 * r /\
d11 = d10 / pow2 64 /\
r1 = c6 % pow2 52 /\ c9 = c6 / pow2 52 + sum2 + r * (d10 % pow2 64) /\
r2 = c9 % pow2 52 /\ c11 = c9 / pow2 52 + r * pow2 12 * d11 + t3 /\
r3 = c11 % pow2 52 /\ r4 = c11 / pow2 52 + (d4 % pow2 52) % pow2 48)
(ensures
r0 + r1 * pow52 + r2 * pow104 + r3 * pow156 + r4 * pow208 =
c3 + (sum1 + r * d8) * pow2 52 + (sum2 + r * sum7) * pow2 104 + t3 * pow2 156 + (d4 % pow2 48) * pow2 208)
let lemma_nat_r43210 r0 r1 r2 r3 r4 c3 c6 c9 c11 d4 d8 d10 d11 t3 r sum1 sum2 sum7 =
let k = d4 % pow2 48 in
let tmp1 = sum2 * pow2 52 + t3 * pow2 104 + k * pow2 156 in
calc (==) { // tmp1 * pow2 52
(sum2 * pow2 52 + t3 * pow2 104 + k * pow2 156) * pow2 52;
(==) { ML.lemma_distr_pow (sum2 * pow2 52 + t3 * pow2 104) k 156 52 }
(sum2 * pow2 52 + t3 * pow2 104) * pow2 52 + k * pow2 208;
(==) { ML.lemma_distr_pow_pow sum2 52 t3 104 52 }
sum2 * pow2 104 + t3 * pow2 156 + k * pow2 208;
};
calc (==) {
r0 + r1 * pow52 + r2 * pow104 + r3 * pow156 + r4 * pow208;
(==) { ML.lemma_as_nat_horner r0 r1 r2 r3 r4 }
(((r4 * pow2 52 + r3) * pow2 52 + r2) * pow2 52 + r1) * pow2 52 + r0;
(==) { lemma_nat_r4321 r1 r2 r3 r4 c6 c9 c11 d4 d10 d11 t3 r sum2 }
(c3 / pow2 52 + sum1 + d8 % pow2 52 * r + r * (d8 / pow2 52 + sum7) * pow2 52 + tmp1) * pow2 52 + c3 % pow2 52;
(==) { ML.lemma_distr_eucl_mul_add r d8 sum7 (pow2 52) }
(c3 / pow2 52 + sum1 + r * d8 + r * sum7 * pow2 52 + tmp1) * pow2 52 + c3 % pow2 52;
(==) { ML.lemma_distr_eucl c3 (sum1 + r * d8 + r * sum7 * pow2 52 + tmp1) }
c3 + (sum1 + r * d8 + r * sum7 * pow2 52 + tmp1) * pow2 52;
(==) { ML.lemma_distr_pow (sum1 + r * d8 + tmp1) (r * sum7) 52 52 }
c3 + (sum1 + r * d8 + tmp1) * pow2 52 + r * sum7 * pow2 104;
(==) { Math.Lemmas.distributivity_add_left (sum1 + r * d8) tmp1 (pow2 52) }
c3 + (sum1 + r * d8) * pow2 52 + sum2 * pow2 104 + t3 * pow2 156 + k * pow2 208 + r * sum7 * pow2 104;
(==) { Math.Lemmas.distributivity_add_left sum2 (r * sum7) (pow2 104) }
c3 + (sum1 + r * d8) * pow2 52 + (sum2 + r * sum7) * pow2 104 + t3 * pow2 156 + k * pow2 208;
}
val simplify_c3 (d4 r sum5:nat) : Lemma
(requires r % pow2 4 = 0)
(ensures (let k = (d4 / pow2 52 + sum5) % pow2 52 in
((d4 % pow2 52) / pow2 48 + k * pow2 4) * (r / pow2 4) ==
(d4 / pow2 48) * (r / pow2 4) + (k - (d4 / pow2 52)) * r))
let simplify_c3 d4 r sum5 =
let k = (d4 / pow2 52 + sum5) % pow2 52 in
calc (==) { //simplify c3
((d4 % pow2 52) / pow2 48 + k * pow2 4) * (r / pow2 4);
(==) { Math.Lemmas.pow2_modulo_division_lemma_1 d4 48 52 }
((d4 / pow2 48) % pow2 4 + k * pow2 4) * (r / pow2 4);
(==) { Math.Lemmas.euclidean_division_definition (d4 / pow2 48) (pow2 4) }
(d4 / pow2 48 - (d4 / pow2 48 / pow2 4) * pow2 4 + k * pow2 4) * (r / pow2 4);
(==) { Math.Lemmas.division_multiplication_lemma d4 (pow2 48) (pow2 4); Math.Lemmas.pow2_plus 48 4 }
(d4 / pow2 48 - (d4 / pow2 52) * pow2 4 + k * pow2 4) * (r / pow2 4);
(==) { Math.Lemmas.distributivity_sub_left k (d4 / pow2 52) (pow2 4) }
(d4 / pow2 48 + (k - d4 / pow2 52) * pow2 4) * (r / pow2 4);
(==) { Math.Lemmas.distributivity_add_left (d4 / pow2 48) ((k - d4 / pow2 52) * pow2 4) (r / pow2 4) }
(d4 / pow2 48) * (r / pow2 4) + (k - d4 / pow2 52) * pow2 4 * (r / pow2 4);
(==) { Math.Lemmas.paren_mul_right (k - d4 / pow2 52) (pow2 4) (r / pow2 4); Math.Lemmas.div_exact_r r (pow2 4) }
(d4 / pow2 48) * (r / pow2 4) + (k - d4 / pow2 52) * r;
}
val lemma_nat_r43210_mod_prime (c3 d4 d8 t3 r sum0 sum1 sum2 sum3 sum4 sum5 sum6 sum7 sum8: nat) : Lemma
(requires
r = 0x1000003D10 /\
d4 = (sum3 + r * (sum8 % pow2 64)) / pow2 52 + sum4 + r * pow2 12 * (sum8 / pow2 64) /\
t3 = (sum3 + r * (sum8 % pow2 64)) % pow2 52 /\
d8 = (d4 / pow2 52 + sum5) / pow2 52 + sum6 /\
c3 = sum0 + ((d4 % pow2 52) / pow2 48 + ((d4 / pow2 52 + sum5) % pow2 52) * pow2 4) * (r / pow2 4))
(ensures
(c3 + (sum1 + r * d8) * pow2 52 + (sum2 + r * sum7) * pow2 104 +
t3 * pow2 156 + (d4 % pow2 48) * pow2 208) % S.prime ==
(sum0 + sum5 * r + (sum1 + sum6 * r) * pow2 52 + (sum2 + r * sum7) * pow2 104 +
(sum3 + r * sum8) * pow2 156 + sum4 * pow2 208) % S.prime)
let lemma_nat_r43210_mod_prime c3 d4 d8 t3 r sum0 sum1 sum2 sum3 sum4 sum5 sum6 sum7 sum8 =
let tmp2 = sum3 + r * (sum8 % pow2 64) in
let tmp1 = d4 / pow2 52 + sum5 in
let tmp0 = sum0 + (tmp1 % pow2 52 - d4 / pow2 52) * r in
let d4mod = (d4 % pow2 48) * pow2 208 + (d4 / pow2 48) * 0x1000003D1 in
calc (==) {
c3 + (d4 % pow2 48) * pow2 208 + (sum1 + r * d8) * pow2 52;
(==) { simplify_c3 d4 r sum5; assert_norm (0x1000003D10 / pow2 4 = 0x1000003D1) }
d4mod + tmp0 + (sum1 + r * d8) * pow2 52;
(==) { Math.Lemmas.distributivity_add_left sum1 (r * d8) (pow2 52) }
d4mod + sum0 + (tmp1 % pow2 52 - d4 / pow2 52) * r + sum1 * pow2 52 + r * (tmp1 / pow2 52 + sum6) * pow2 52;
(==) { Math.Lemmas.distributivity_sub_left (tmp1 % pow2 52) (d4 / pow2 52) r }
d4mod + sum0 + (tmp1 % pow2 52) * r - d4 / pow2 52 * r + sum1 * pow2 52 + r * (tmp1 / pow2 52 + sum6) * pow2 52;
(==) { ML.lemma_distr_eucl_mul_add r tmp1 sum6 (pow2 52) }
d4mod + sum0 + r * (d4 / pow2 52 + sum5) - d4 / pow2 52 * r + sum1 * pow2 52 + r * sum6 * pow2 52;
(==) { Math.Lemmas.distributivity_add_right r (d4 / pow2 52) sum5 }
d4mod + sum0 + r * sum5 + sum1 * pow2 52 + r * sum6 * pow2 52;
(==) { Math.Lemmas.distributivity_add_left sum1 (r * sum6) (pow2 52) }
d4mod + sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52;
};
calc (==) { //t3 * pow2 156 + d4 * pow2 208;
(tmp2 % pow2 52) * pow2 156 + (tmp2 / pow2 52 + sum4 + r * pow2 12 * (sum8 / pow2 64)) * pow2 208;
(==) { ML.lemma_distr_pow (tmp2 % pow2 52) (tmp2 / pow2 52 + sum4 + r * pow2 12 * (sum8 / pow2 64)) 52 156 }
(tmp2 % pow2 52 + (tmp2 / pow2 52 + sum4 + r * pow2 12 * (sum8 / pow2 64)) * pow2 52) * pow2 156;
(==) { ML.lemma_distr_eucl_mul_add 1 tmp2 (sum4 + r * pow2 12 * (sum8 / pow2 64)) (pow2 52) }
(tmp2 + (sum4 + r * pow2 12 * (sum8 / pow2 64)) * pow2 52) * pow2 156;
(==) { ML.lemma_swap_mul3 r (pow2 12) (sum8 / pow2 64) }
(tmp2 + (sum4 + r * (sum8 / pow2 64) * pow2 12) * pow2 52) * pow2 156;
(==) { ML.lemma_distr_pow sum4 (r * (sum8 / pow2 64)) 12 52 }
(sum3 + r * (sum8 % pow2 64) + sum4 * pow2 52 + r * (sum8 / pow2 64) * pow2 64) * pow2 156;
(==) { ML.lemma_distr_eucl_mul r sum8 (pow2 64) }
(sum3 + r * sum8 + sum4 * pow2 52) * pow2 156;
(==) { ML.lemma_distr_pow (sum3 + r * sum8) sum4 52 156 }
(sum3 + r * sum8) * pow2 156 + sum4 * pow2 208;
};
LD.as_nat_mod_prime (sum0 + r * sum5) (sum1 + r * sum6) (sum2 + r * sum7) t3 d4
val lemma_mul_ab (a0 a1 a2 a3 a4 b0 b1 b2 b3 b4:nat) :
Lemma
(let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
(a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208) *
(b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208) =
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208 +
pow2 260 * (sum5 + sum6 * pow2 52 + sum7 * pow2 104 + sum8 * pow2 156))
let lemma_mul_ab a0 a1 a2 a3 a4 b0 b1 b2 b3 b4 =
let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let b_sum = b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208 in
calc (==) {
(a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208) * b_sum;
(==) { ML.lemma_distr5 a0 (a1 * pow52) (a2 * pow104) (a3 * pow156) (a4 * pow208) b_sum }
a0 * b_sum + a1 * pow52 * b_sum + a2 * pow104 * b_sum + a3 * pow156 * b_sum + a4 * pow208 * b_sum;
(==) { ML.lemma_distr5_pow52 a0 b0 b1 b2 b3 b4 }
sum0 + a0 * b1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * pow52 * b_sum + a2 * pow104 * b_sum + a3 * pow156 * b_sum + a4 * pow208 * b_sum;
(==) { ML.lemma_distr5_pow52_mul_pow a1 b0 b1 b2 b3 b4 52 }
sum0 + a0 * b1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b0 * pow2 52 + a1 * b1 * pow2 104 + a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * pow104 * b_sum + a3 * pow156 * b_sum + a4 * pow208 * b_sum;
(==) { ML.lemma_distr5_pow52_mul_pow a2 b0 b1 b2 b3 b4 104 }
sum0 + a0 * b1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b0 * pow2 52 + a1 * b1 * pow2 104 + a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b0 * pow2 104 + a2 * b1 * pow2 156 + a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * pow156 * b_sum + a4 * pow208 * b_sum;
(==) { ML.lemma_distr5_pow52_mul_pow a3 b0 b1 b2 b3 b4 156 }
sum0 + a0 * b1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b0 * pow2 52 + a1 * b1 * pow2 104 + a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b0 * pow2 104 + a2 * b1 * pow2 156 + a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b0 * pow2 156 + a3 * b1 * pow2 208 + a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * pow208 * b_sum;
(==) { ML.lemma_distr5_pow52_mul_pow a4 b0 b1 b2 b3 b4 208 }
sum0 + a0 * b1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b0 * pow2 52 + a1 * b1 * pow2 104 + a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b0 * pow2 104 + a2 * b1 * pow2 156 + a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b0 * pow2 156 + a3 * b1 * pow2 208 + a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b0 * pow2 208 + a4 * b1 * pow2 260 + a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { Math.Lemmas.distributivity_add_left (a0 * b1) (a1 * b0) (pow2 52) }
sum0 + sum1 * pow2 52 + a0 * b2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b1 * pow2 104 + a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b0 * pow2 104 + a2 * b1 * pow2 156 + a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b0 * pow2 156 + a3 * b1 * pow2 208 + a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b0 * pow2 208 + a4 * b1 * pow2 260 + a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { ML.lemma_distr5 (a0 * b2) (a1 * b1) (a2 * b0) 0 0 (pow2 104) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + a0 * b3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b2 * pow2 156 + a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b1 * pow2 156 + a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b0 * pow2 156 + a3 * b1 * pow2 208 + a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b0 * pow2 208 + a4 * b1 * pow2 260 + a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { ML.lemma_distr5 (a0 * b3) (a1 * b2) (a2 * b1) (a3 * b0) 0 (pow2 156) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + a0 * b4 * pow2 208
+ a1 * b3 * pow2 208 + a1 * b4 * pow2 260
+ a2 * b2 * pow2 208 + a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b1 * pow2 208 + a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b0 * pow2 208 + a4 * b1 * pow2 260 + a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { ML.lemma_distr5 (a0 * b4) (a1 * b3) (a2 * b2) (a3 * b1) (a4 * b0) (pow2 208) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ a1 * b4 * pow2 260
+ a2 * b3 * pow2 260 + a2 * b4 * pow2 312
+ a3 * b2 * pow2 260 + a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b1 * pow2 260 + a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { ML.lemma_distr5 (a1 * b4) (a2 * b3) (a3 * b2) (a4 * b1) 0 (pow2 260) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ sum5 * pow2 260
+ a2 * b4 * pow2 312
+ a3 * b3 * pow2 312 + a3 * b4 * pow2 364
+ a4 * b2 * pow2 312 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { ML.lemma_distr5 (a2 * b4) (a3 * b3) (a4 * b2) 0 0 (pow2 312) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ sum5 * pow2 260 + sum6 * pow2 312 + a3 * b4 * pow2 364 + a4 * b3 * pow2 364 + a4 * b4 * pow2 416;
(==) { Math.Lemmas.distributivity_add_left (a3 * b4) (a4 * b3) (pow2 364) }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ sum5 * pow2 260 + sum6 * pow2 312 + sum7 * pow2 364 + sum8 * pow2 416;
(==) { ML.lemma_distr5_pow52_mul_pow 1 sum5 sum6 sum7 sum8 0 260 }
sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208
+ pow2 260 * (sum5 + sum6 * pow2 52 + sum7 * pow2 104 + sum8 * pow2 156);
}
val lemma_fmul_ab (a0 a1 a2 a3 a4 b0 b1 b2 b3 b4:nat) :
Lemma
(let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let r = 0x1000003D10 in
(a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208) *
(b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208) % S.prime =
(sum0 + sum5 * r + (sum1 + sum6 * r) * pow2 52 + (sum2 + r * sum7) * pow2 104
+ (sum3 + r * sum8) * pow2 156 + sum4 * pow2 208) % S.prime) | {
"checked_file": "/",
"dependencies": [
"Spec.K256.fst.checked",
"prims.fst.checked",
"Lib.IntTypes.fsti.checked",
"Hacl.Spec.K256.MathLemmas.fst.checked",
"Hacl.Spec.K256.Field52.Definitions.Lemmas.fst.checked",
"Hacl.Spec.K256.Field52.Definitions.fst.checked",
"Hacl.Spec.K256.Field52.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.Math.Lemmas.fst.checked",
"FStar.Calc.fsti.checked"
],
"interface_file": false,
"source_file": "Hacl.Spec.K256.Field52.Lemmas4.fst"
} | [
{
"abbrev": true,
"full_module": "Hacl.Spec.K256.Field52.Definitions.Lemmas",
"short_module": "LD"
},
{
"abbrev": true,
"full_module": "Hacl.Spec.K256.MathLemmas",
"short_module": "ML"
},
{
"abbrev": false,
"full_module": "Hacl.Spec.K256.Field52",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.K256.Field52.Definitions",
"short_module": null
},
{
"abbrev": true,
"full_module": "Spec.K256",
"short_module": "S"
},
{
"abbrev": false,
"full_module": "Lib.IntTypes",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Mul",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.K256.Field52",
"short_module": null
},
{
"abbrev": false,
"full_module": "Hacl.Spec.K256.Field52",
"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": 100,
"z3rlimit_factor": 1,
"z3seed": 0,
"z3smtopt": [],
"z3version": "4.8.5"
} | false |
a0: Prims.nat ->
a1: Prims.nat ->
a2: Prims.nat ->
a3: Prims.nat ->
a4: Prims.nat ->
b0: Prims.nat ->
b1: Prims.nat ->
b2: Prims.nat ->
b3: Prims.nat ->
b4: Prims.nat
-> FStar.Pervasives.Lemma
(ensures
(let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let r = 0x1000003D10 in
(a0 + a1 * Hacl.Spec.K256.Field52.Definitions.pow52 +
a2 * Hacl.Spec.K256.Field52.Definitions.pow104 +
a3 * Hacl.Spec.K256.Field52.Definitions.pow156 +
a4 * Hacl.Spec.K256.Field52.Definitions.pow208) *
(b0 + b1 * Hacl.Spec.K256.Field52.Definitions.pow52 +
b2 * Hacl.Spec.K256.Field52.Definitions.pow104 +
b3 * Hacl.Spec.K256.Field52.Definitions.pow156 +
b4 * Hacl.Spec.K256.Field52.Definitions.pow208) %
Spec.K256.PointOps.prime =
(sum0 + sum5 * r + (sum1 + sum6 * r) * Prims.pow2 52 + (sum2 + r * sum7) * Prims.pow2 104 +
(sum3 + r * sum8) * Prims.pow2 156 +
sum4 * Prims.pow2 208) %
Spec.K256.PointOps.prime)) | FStar.Pervasives.Lemma | [
"lemma"
] | [] | [
"Prims.nat",
"FStar.Calc.calc_finish",
"Prims.int",
"Prims.eq2",
"Prims.op_Modulus",
"FStar.Mul.op_Star",
"Spec.K256.PointOps.prime",
"Prims.op_Addition",
"Prims.pow2",
"Prims.Cons",
"FStar.Preorder.relation",
"Prims.Nil",
"Prims.unit",
"FStar.Calc.calc_step",
"FStar.Calc.calc_init",
"FStar.Calc.calc_pack",
"Hacl.Spec.K256.Field52.Lemmas4.lemma_mul_ab",
"Prims.squash",
"FStar.Math.Lemmas.paren_mul_right",
"FStar.Math.Lemmas.pow2_plus",
"Hacl.Spec.K256.Field52.Definitions.Lemmas.lemma_a_plus_b_mul_pow256",
"FStar.Pervasives.assert_norm",
"Prims.b2t",
"Prims.op_Equality",
"Hacl.Spec.K256.MathLemmas.lemma_distr5_pow52",
"FStar.Math.Lemmas.distributivity_add_left",
"Hacl.Spec.K256.Field52.Definitions.pow52",
"Hacl.Spec.K256.Field52.Definitions.pow104",
"Hacl.Spec.K256.Field52.Definitions.pow156",
"Hacl.Spec.K256.Field52.Definitions.pow208"
] | [] | false | false | true | false | false | let lemma_fmul_ab a0 a1 a2 a3 a4 b0 b1 b2 b3 b4 =
| let r = 0x1000003D10 in
let sum0 = a0 * b0 in
let sum1 = a0 * b1 + a1 * b0 in
let sum2 = a0 * b2 + a1 * b1 + a2 * b0 in
let sum3 = a0 * b3 + a1 * b2 + a2 * b1 + a3 * b0 in
let sum4 = a0 * b4 + a1 * b3 + a2 * b2 + a3 * b1 + a4 * b0 in
let sum5 = a1 * b4 + a2 * b3 + a3 * b2 + a4 * b1 in
let sum6 = a2 * b4 + a3 * b3 + a4 * b2 in
let sum7 = a3 * b4 + a4 * b3 in
let sum8 = a4 * b4 in
let a_sum = a0 + a1 * pow52 + a2 * pow104 + a3 * pow156 + a4 * pow208 in
let b_sum = b0 + b1 * pow52 + b2 * pow104 + b3 * pow156 + b4 * pow208 in
let tmp0 = sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208 in
let tmp1 = sum5 + sum6 * pow2 52 + sum7 * pow2 104 + sum8 * pow2 156 in
calc ( == ) {
a_sum * b_sum % S.prime;
( == ) { lemma_mul_ab a0 a1 a2 a3 a4 b0 b1 b2 b3 b4 }
(tmp0 + pow2 260 * tmp1) % S.prime;
( == ) { (Math.Lemmas.pow2_plus 256 4;
Math.Lemmas.paren_mul_right (pow2 256) (pow2 4) tmp1) }
(tmp0 + pow2 256 * (pow2 4 * tmp1)) % S.prime;
( == ) { LD.lemma_a_plus_b_mul_pow256 tmp0 (pow2 4 * tmp1) }
(tmp0 + 0x1000003D1 * (pow2 4 * tmp1)) % S.prime;
( == ) { (Math.Lemmas.paren_mul_right 0x1000003D1 (pow2 4) tmp1;
assert_norm (0x1000003D1 * pow2 4 = r)) }
(tmp0 + r * tmp1) % S.prime;
( == ) { ML.lemma_distr5_pow52 r sum5 sum6 sum7 sum8 0 }
(sum0 + sum1 * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 + sum4 * pow2 208 + r * sum5 +
(r * sum6) * pow2 52 +
(r * sum7) * pow2 104 +
(r * sum8) * pow2 156) %
S.prime;
( == ) { Math.Lemmas.distributivity_add_left sum1 (r * sum6) (pow2 52) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + sum2 * pow2 104 + sum3 * pow2 156 +
sum4 * pow2 208 +
(r * sum7) * pow2 104 +
(r * sum8) * pow2 156) %
S.prime;
( == ) { Math.Lemmas.distributivity_add_left sum2 (r * sum7) (pow2 104) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + (sum2 + r * sum7) * pow2 104 + sum3 * pow2 156 +
sum4 * pow2 208 +
(r * sum8) * pow2 156) %
S.prime;
( == ) { Math.Lemmas.distributivity_add_left sum3 (r * sum8) (pow2 156) }
(sum0 + r * sum5 + (sum1 + r * sum6) * pow2 52 + (sum2 + r * sum7) * pow2 104 +
(sum3 + r * sum8) * pow2 156 +
sum4 * pow2 208) %
S.prime;
} | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test11_expected_shake256 | val test11_expected_shake256:lbytes 32 | val test11_expected_shake256:lbytes 32 | let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 418,
"start_col": 0,
"start_line": 410
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test11_expected_shake256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy; 0xbauy; 0xbeuy; 0x98uy; 0xf8uy;
0xf1uy; 0x69uy; 0xcbuy; 0x62uy; 0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test8_plaintext_shake128 | val test8_plaintext_shake128:lbytes 83 | val test8_plaintext_shake128:lbytes 83 | let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 343,
"start_col": 0,
"start_line": 328
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 83 | 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 test8_plaintext_shake128:lbytes 83 =
| let l =
List.Tot.map u8_from_UInt8
[
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy; 0x30uy; 0xa9uy; 0x7euy; 0xf1uy;
0xb3uy; 0x46uy; 0x73uy; 0xecuy; 0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy; 0x37uy; 0x80uy; 0xbauy; 0x7buy;
0xdfuy; 0xeduy; 0x86uy; 0x20uy; 0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy; 0x2cuy; 0xa0uy; 0xe0uy; 0xfauy;
0x0duy; 0xdfuy; 0xbbuy; 0xdfuy; 0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy; 0x2duy; 0x2duy; 0x01uy
]
in
assert_norm (List.Tot.length l == 83);
of_list l | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.parse_filter_impl | val parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: (x: t -> Tot (b: bool{b == f x})))
: Tot (parser_impl (parse_filter p f)) | val parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: (x: t -> Tot (b: bool{b == f x})))
: Tot (parser_impl (parse_filter p f)) | let parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: ((x: t) -> Tot (b: bool { b == f x } )))
: Tot (parser_impl (parse_filter p f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, consumed) ->
if g v
then
[@@inline_let]
let (v' : t { f v' == true } ) = v in
Some (v', consumed)
else
None
| _ -> None | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 15,
"end_line": 187,
"start_col": 0,
"start_line": 170
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None
inline_for_extraction
let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x
inline_for_extraction
let serialize_synth_impl'
(#t1: Type0)
(#t2: Type0)
(g1': (x: t2) -> Tot t1)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
(v: squash (
(forall (x: t2) . g1' x == g1 x)
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= serialize_synth_impl s1' f2 g1 (fun x -> g1' x) () | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
p32: MiniParse.Impl.Base.parser_impl p ->
f: (_: t -> Prims.GTot Prims.bool) ->
g: (x: t -> b: Prims.bool{b == f x})
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.parse_filter p f) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Impl.Base.parser_impl",
"Prims.bool",
"Prims.eq2",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Pervasives.Native.None",
"FStar.Pervasives.Native.option",
"MiniParse.Spec.Combinators.parse_filter"
] | [] | false | false | false | false | false | let parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: (x: t -> Tot (b: bool{b == f x})))
: Tot (parser_impl (parse_filter p f)) =
| fun (input: buffer8) (len: U32.t{len == B.len input}) ->
match p32 input len with
| Some (v, consumed) ->
if g v
then
[@@ inline_let ]let v':v': t{f v' == true} = v in
Some (v', consumed)
else None
| _ -> None | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.serialize_filter_impl | val serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f)) | val serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f)) | let serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t { f input == true } ) -> s32 output len input | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 117,
"end_line": 197,
"start_col": 0,
"start_line": 190
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None
inline_for_extraction
let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x
inline_for_extraction
let serialize_synth_impl'
(#t1: Type0)
(#t2: Type0)
(g1': (x: t2) -> Tot t1)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
(v: squash (
(forall (x: t2) . g1' x == g1 x)
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= serialize_synth_impl s1' f2 g1 (fun x -> g1' x) ()
inline_for_extraction
let parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: ((x: t) -> Tot (b: bool { b == f x } )))
: Tot (parser_impl (parse_filter p f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, consumed) ->
if g v
then
[@@inline_let]
let (v' : t { f v' == true } ) = v in
Some (v', consumed)
else
None
| _ -> None | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 | s32: MiniParse.Impl.Base.serializer_impl s -> f: (_: t -> Prims.GTot Prims.bool)
-> MiniParse.Impl.Base.serializer_impl (MiniParse.Spec.Combinators.serialize_filter s f) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Spec.Base.serializer_spec",
"MiniParse.Impl.Base.serializer_impl",
"Prims.bool",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"Prims.eq2",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.option",
"MiniParse.Spec.Combinators.parse_filter",
"MiniParse.Spec.Combinators.serialize_filter"
] | [] | false | false | false | false | false | let serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f)) =
| fun (output: buffer8) (len: U32.t{len == B.len output}) (input: t{f input == true}) ->
s32 output len input | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test12_plaintext_shake256 | val test12_plaintext_shake256:lbytes 78 | val test12_plaintext_shake256:lbytes 78 | let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.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": 423
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256 | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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) 78 | 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 test12_plaintext_shake256:lbytes 78 =
| let l =
List.Tot.map u8_from_UInt8
[
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy; 0xdauy; 0xccuy; 0x96uy; 0x87uy;
0x3auy; 0x3cuy; 0xd5uy; 0x58uy; 0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy; 0x0buy; 0x25uy; 0x48uy; 0xb6uy;
0x5buy; 0x52uy; 0xa9uy; 0x22uy; 0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy; 0xf2uy; 0x4duy; 0xb3uy; 0x4euy;
0x82uy; 0x8buy; 0x74uy; 0xdbuy; 0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
]
in
assert_norm (List.Tot.length l == 78);
of_list l | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test12_expected_shake256 | val test12_expected_shake256:lbytes 32 | val test12_expected_shake256:lbytes 32 | let test12_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy;
0x34uy; 0x06uy; 0x3buy; 0x5fuy; 0xc9uy; 0x21uy; 0x5fuy; 0xc3uy;
0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 11,
"end_line": 448,
"start_col": 0,
"start_line": 440
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256
let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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 test12_expected_shake256:lbytes 32 =
| let l =
List.Tot.map u8_from_UInt8
[
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy; 0x34uy; 0x06uy; 0x3buy; 0x5fuy;
0xc9uy; 0x21uy; 0x5fuy; 0xc3uy; 0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
]
in
assert_norm (List.Tot.length l == 32);
of_list l | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.serialize_nondep_then_impl | val serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2': serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2)) | val serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2': serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2)) | let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 7,
"end_line": 110,
"start_col": 0,
"start_line": 83
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 | s1': MiniParse.Impl.Base.serializer_impl s1 -> s2': MiniParse.Impl.Base.serializer_impl s2
-> MiniParse.Impl.Base.serializer_impl (MiniParse.Spec.Combinators.serialize_nondep_then s1 s2) | Prims.Tot | [
"total"
] | [] | [
"MiniParse.Spec.Base.parser_spec",
"MiniParse.Spec.Base.serializer_spec",
"MiniParse.Impl.Base.serializer_impl",
"MiniParse.Impl.Base.buffer8",
"FStar.UInt32.t",
"Prims.eq2",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Some",
"FStar.UInt32.add",
"Prims.unit",
"Prims._assert",
"FStar.Seq.Base.equal",
"FStar.Seq.Base.append",
"LowStar.Monotonic.Buffer.as_seq",
"LowStar.Buffer.gsub",
"FStar.UInt32.__uint_to_t",
"MiniParse.Impl.Combinators.seq_append_slice",
"FStar.UInt32.v",
"FStar.Seq.Base.seq",
"FStar.Pervasives.Native.option",
"FStar.Monotonic.HyperStack.mem",
"FStar.HyperStack.ST.get",
"FStar.Pervasives.Native.None",
"FStar.UInt32.sub",
"LowStar.Monotonic.Buffer.mbuffer",
"LowStar.Buffer.offset",
"MiniParse.Spec.Combinators.nondep_then",
"MiniParse.Spec.Combinators.serialize_nondep_then"
] | [] | false | false | false | false | false | let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1': serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2': serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2)) =
| fun (output: buffer8) (l: U32.t{l == B.len output}) (input: t1 * t2) ->
match input with
| fs, sn ->
match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
(match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert ((Seq.append (B.as_seq h2 (B.gsub output 0ul l1))
(B.as_seq h2 (B.gsub output' 0ul l2)))
`Seq.equal`
(B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2))));
Some (l1 `U32.add` l2)
| _ -> None)
| _ -> None | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.make_total_constant_size_parser_impl | val make_total_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (t)))
(u: squash (make_total_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack t
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_total_constant_size_parser sz t f)) | val make_total_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (t)))
(u: squash (make_total_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack t
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_total_constant_size_parser sz t f)) | let make_total_constant_size_parser_impl
(sz: nat)
(sz' : U32.t { U32.v sz' == sz } )
(#t: Type0)
(f: ((s: bytes {Seq.length s == sz}) -> GTot (t)))
(u: squash (
make_total_constant_size_parser_precond sz t f
))
(f' : (
(s: buffer8 { B.length s == sz } ) ->
HST.Stack t
(requires (fun h -> B.live h s))
(ensures (fun h y h' ->
M.modifies M.loc_none h h' /\
y == f (B.as_seq h s)
))))
: Tot (parser_impl (make_total_constant_size_parser sz t f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
if U32.lt len sz'
then None
else
let s' = B.sub input 0ul sz' in
Some (f' s', (sz' <: U32.t)) | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 34,
"end_line": 250,
"start_col": 0,
"start_line": 228
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None
inline_for_extraction
let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x
inline_for_extraction
let serialize_synth_impl'
(#t1: Type0)
(#t2: Type0)
(g1': (x: t2) -> Tot t1)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
(v: squash (
(forall (x: t2) . g1' x == g1 x)
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= serialize_synth_impl s1' f2 g1 (fun x -> g1' x) ()
inline_for_extraction
let parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: ((x: t) -> Tot (b: bool { b == f x } )))
: Tot (parser_impl (parse_filter p f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, consumed) ->
if g v
then
[@@inline_let]
let (v' : t { f v' == true } ) = v in
Some (v', consumed)
else
None
| _ -> None
inline_for_extraction
let serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t { f input == true } ) -> s32 output len input
inline_for_extraction
let make_constant_size_parser_impl
(sz: nat)
(sz' : U32.t { U32.v sz' == sz } )
(#t: Type0)
(f: ((s: bytes {Seq.length s == sz}) -> GTot (option t)))
(u: squash (
make_constant_size_parser_precond sz t f
))
(f' : (
(s: buffer8 { B.length s == sz } ) ->
HST.Stack (option t)
(requires (fun h -> B.live h s))
(ensures (fun h y h' ->
M.modifies M.loc_none h h' /\
y == f (B.as_seq h s)
))))
: Tot (parser_impl (make_constant_size_parser sz t f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
if U32.lt len sz'
then None
else begin
let s' = B.sub input 0ul sz' in
match f' s' with
| None -> None
| Some v -> Some (v, (sz' <: U32.t))
end | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
sz: Prims.nat ->
sz': FStar.UInt32.t{FStar.UInt32.v sz' == sz} ->
f: (s: MiniParse.Spec.Base.bytes{FStar.Seq.Base.length s == sz} -> Prims.GTot t) ->
u161: Prims.squash (MiniParse.Spec.Combinators.make_total_constant_size_parser_precond sz t f) ->
f':
(s: MiniParse.Impl.Base.buffer8{LowStar.Monotonic.Buffer.length s == sz}
-> FStar.HyperStack.ST.Stack t)
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.make_total_constant_size_parser sz
t
f) | Prims.Tot | [
"total"
] | [] | [
"Prims.nat",
"FStar.UInt32.t",
"Prims.eq2",
"Prims.int",
"Prims.l_or",
"FStar.UInt.size",
"FStar.UInt32.n",
"Prims.b2t",
"Prims.op_GreaterThanOrEqual",
"FStar.UInt32.v",
"MiniParse.Spec.Base.bytes",
"FStar.Seq.Base.length",
"MiniParse.Spec.Base.byte",
"Prims.squash",
"MiniParse.Spec.Combinators.make_total_constant_size_parser_precond",
"MiniParse.Impl.Base.buffer8",
"LowStar.Monotonic.Buffer.length",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Monotonic.HyperStack.mem",
"LowStar.Monotonic.Buffer.live",
"Prims.l_and",
"LowStar.Monotonic.Buffer.modifies",
"LowStar.Monotonic.Buffer.loc_none",
"LowStar.Monotonic.Buffer.as_seq",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt32.lt",
"FStar.Pervasives.Native.None",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.option",
"Prims.bool",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.Mktuple2",
"LowStar.Monotonic.Buffer.mbuffer",
"LowStar.Buffer.sub",
"FStar.UInt32.__uint_to_t",
"FStar.Ghost.hide",
"MiniParse.Impl.Base.parser_impl",
"MiniParse.Spec.Combinators.make_total_constant_size_parser"
] | [] | false | false | false | false | false | let make_total_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (t)))
(u: squash (make_total_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack t
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_total_constant_size_parser sz t f)) =
| fun (input: buffer8) (len: U32.t{len == B.len input}) ->
if U32.lt len sz'
then None
else
let s' = B.sub input 0ul sz' in
Some (f' s', (sz' <: U32.t)) | false |
MiniParse.Impl.Combinators.fst | MiniParse.Impl.Combinators.make_constant_size_parser_impl | val make_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (option t)))
(u: squash (make_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack (option t)
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_constant_size_parser sz t f)) | val make_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (option t)))
(u: squash (make_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack (option t)
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_constant_size_parser sz t f)) | let make_constant_size_parser_impl
(sz: nat)
(sz' : U32.t { U32.v sz' == sz } )
(#t: Type0)
(f: ((s: bytes {Seq.length s == sz}) -> GTot (option t)))
(u: squash (
make_constant_size_parser_precond sz t f
))
(f' : (
(s: buffer8 { B.length s == sz } ) ->
HST.Stack (option t)
(requires (fun h -> B.live h s))
(ensures (fun h y h' ->
M.modifies M.loc_none h h' /\
y == f (B.as_seq h s)
))))
: Tot (parser_impl (make_constant_size_parser sz t f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
if U32.lt len sz'
then None
else begin
let s' = B.sub input 0ul sz' in
match f' s' with
| None -> None
| Some v -> Some (v, (sz' <: U32.t))
end | {
"file_name": "examples/miniparse/MiniParse.Impl.Combinators.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 7,
"end_line": 225,
"start_col": 0,
"start_line": 200
} | (*
Copyright 2008-2018 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 MiniParse.Impl.Combinators
include MiniParse.Impl.Base
include MiniParse.Spec.Combinators
module B = LowStar.Buffer
module M = LowStar.ModifiesPat
module U32 = FStar.UInt32
module HST = FStar.HyperStack.ST
inline_for_extraction
let parse_ret_impl
(#t: Type)
(x: t)
: Tot (parser_impl (parse_ret x))
= fun _ _ -> let h = HST.get () in Some (x, 0ul)
inline_for_extraction
let serialize_empty_impl
: serializer_impl serialize_empty
= fun _ _ _ -> let h = HST.get () in Some 0ul
inline_for_extraction
let parse_and_then_impl
(#t:Type)
(#p:parser_spec t)
(p32: parser_impl p)
(#t':Type)
(p': (t -> Tot (parser_spec t')))
(u: squash (and_then_cases_injective p'))
(p32' : ((x: t) -> Tot (parser_impl (p' x))))
: Tot (parser_impl (p `and_then` p'))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, l) ->
let input' = B.offset input l in
begin match p32' v input' (len `U32.sub` l) with
| Some (v', l') ->
Some (v', U32.add l l')
| _ -> None
end
| _ -> None
#set-options "--z3rlimit 16"
inline_for_extraction
let parse_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(#t2: Type0)
(#p2: parser_spec t2)
(p2' : parser_impl p2)
: Tot (parser_impl (nondep_then p1 p2))
= parse_and_then_impl p1' _ () (fun x -> parse_and_then_impl p2' _ () (fun y -> parse_ret_impl (x, y)))
let seq_append_slice
(#t: Type)
(s: Seq.seq t)
(i1 i2: nat)
: Lemma
(requires (i1 + i2 <= Seq.length s))
(ensures (
Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) == Seq.slice s 0 (i1 + i2)
))
= assert (Seq.append (Seq.slice s 0 i1) (Seq.slice s i1 (i1 + i2)) `Seq.equal` Seq.slice s 0 (i1 + i2))
inline_for_extraction
let serialize_nondep_then_impl
(#t1: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(#t2: Type0)
(#p2: parser_spec t2)
(#s2: serializer_spec p2)
(s2' : serializer_impl s2)
: Tot (serializer_impl (serialize_nondep_then s1 s2))
= fun (output: buffer8) (l: U32.t { l == B.len output } ) (input: t1 * t2) ->
match input with
| (fs, sn) ->
begin match s1' output l fs with
| Some l1 ->
let h1 = HST.get () in
let output' = B.offset output l1 in
begin match s2' output' (l `U32.sub` l1) sn with
| Some l2 ->
let h2 = HST.get () in
assert (B.as_seq h1 (B.gsub output 0ul l1) == B.as_seq h2 (B.gsub output 0ul l1));
seq_append_slice (B.as_seq h2 output) (U32.v l1) (U32.v l2);
assert (Seq.append (B.as_seq h2 (B.gsub output 0ul l1)) (B.as_seq h2 (B.gsub output' 0ul l2)) `Seq.equal` B.as_seq h2 (B.gsub output 0ul (l1 `U32.add` l2)));
Some (l1 `U32.add` l2)
| _ -> None
end
| _ -> None
end
inline_for_extraction
let parse_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(p1' : parser_impl p1)
(f2: t1 -> GTot t2)
(f2': (x: t1) -> Tot (y: t2 { y == f2 x } ))
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse g1 f2
))
: Tot (parser_impl (parse_synth p1 f2 g1))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p1' input len with
| Some (v1, consumed) -> Some ((f2' v1 <: t2), consumed)
| _ -> None
inline_for_extraction
let serialize_synth_impl
(#t1: Type0)
(#t2: Type0)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(g1': (x: t2) -> Tot (y: t1 { y == g1 x } ) )
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t2) ->
let x = g1' input in
s1' output len x
inline_for_extraction
let serialize_synth_impl'
(#t1: Type0)
(#t2: Type0)
(g1': (x: t2) -> Tot t1)
(#p1: parser_spec t1)
(#s1: serializer_spec p1)
(s1' : serializer_impl s1)
(f2: t1 -> GTot t2)
(g1: t2 -> GTot t1)
(u: squash (
synth_inverse f2 g1 /\
synth_inverse g1 f2
))
(v: squash (
(forall (x: t2) . g1' x == g1 x)
))
: Tot (serializer_impl (serialize_synth s1 f2 g1 u))
= serialize_synth_impl s1' f2 g1 (fun x -> g1' x) ()
inline_for_extraction
let parse_filter_impl
(#t: Type0)
(#p: parser_spec t)
(p32: parser_impl p)
(f: (t -> GTot bool))
(g: ((x: t) -> Tot (b: bool { b == f x } )))
: Tot (parser_impl (parse_filter p f))
= fun (input: buffer8) (len: U32.t { len == B.len input } ) ->
match p32 input len with
| Some (v, consumed) ->
if g v
then
[@@inline_let]
let (v' : t { f v' == true } ) = v in
Some (v', consumed)
else
None
| _ -> None
inline_for_extraction
let serialize_filter_impl
(#t: Type0)
(#p: parser_spec t)
(#s: serializer_spec p)
(s32: serializer_impl s)
(f: (t -> GTot bool))
: Tot (serializer_impl (serialize_filter s f))
= fun (output: buffer8) (len: U32.t { len == B.len output } ) (input: t { f input == true } ) -> s32 output len input | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"MiniParse.Spec.Combinators.fst.checked",
"MiniParse.Impl.Base.fst.checked",
"LowStar.ModifiesPat.fst.checked",
"LowStar.Buffer.fst.checked",
"FStar.UInt32.fsti.checked",
"FStar.Seq.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.HyperStack.ST.fsti.checked"
],
"interface_file": false,
"source_file": "MiniParse.Impl.Combinators.fst"
} | [
{
"abbrev": true,
"full_module": "FStar.HyperStack.ST",
"short_module": "HST"
},
{
"abbrev": true,
"full_module": "FStar.UInt32",
"short_module": "U32"
},
{
"abbrev": true,
"full_module": "LowStar.ModifiesPat",
"short_module": "M"
},
{
"abbrev": true,
"full_module": "LowStar.Buffer",
"short_module": "B"
},
{
"abbrev": false,
"full_module": "MiniParse.Spec.Combinators",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"short_module": null
},
{
"abbrev": false,
"full_module": "MiniParse.Impl",
"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 |
sz: Prims.nat ->
sz': FStar.UInt32.t{FStar.UInt32.v sz' == sz} ->
f:
(s: MiniParse.Spec.Base.bytes{FStar.Seq.Base.length s == sz}
-> Prims.GTot (FStar.Pervasives.Native.option t)) ->
u149: Prims.squash (MiniParse.Spec.Combinators.make_constant_size_parser_precond sz t f) ->
f':
(s: MiniParse.Impl.Base.buffer8{LowStar.Monotonic.Buffer.length s == sz}
-> FStar.HyperStack.ST.Stack (FStar.Pervasives.Native.option t))
-> MiniParse.Impl.Base.parser_impl (MiniParse.Spec.Combinators.make_constant_size_parser sz t f) | Prims.Tot | [
"total"
] | [] | [
"Prims.nat",
"FStar.UInt32.t",
"Prims.eq2",
"Prims.int",
"Prims.l_or",
"FStar.UInt.size",
"FStar.UInt32.n",
"Prims.b2t",
"Prims.op_GreaterThanOrEqual",
"FStar.UInt32.v",
"MiniParse.Spec.Base.bytes",
"FStar.Seq.Base.length",
"MiniParse.Spec.Base.byte",
"FStar.Pervasives.Native.option",
"Prims.squash",
"MiniParse.Spec.Combinators.make_constant_size_parser_precond",
"MiniParse.Impl.Base.buffer8",
"LowStar.Monotonic.Buffer.length",
"FStar.UInt8.t",
"LowStar.Buffer.trivial_preorder",
"FStar.Monotonic.HyperStack.mem",
"LowStar.Monotonic.Buffer.live",
"Prims.l_and",
"LowStar.Monotonic.Buffer.modifies",
"LowStar.Monotonic.Buffer.loc_none",
"LowStar.Monotonic.Buffer.as_seq",
"LowStar.Monotonic.Buffer.len",
"FStar.UInt32.lt",
"FStar.Pervasives.Native.None",
"FStar.Pervasives.Native.tuple2",
"Prims.bool",
"FStar.Pervasives.Native.Some",
"FStar.Pervasives.Native.Mktuple2",
"LowStar.Monotonic.Buffer.mbuffer",
"LowStar.Buffer.sub",
"FStar.UInt32.__uint_to_t",
"FStar.Ghost.hide",
"MiniParse.Impl.Base.parser_impl",
"MiniParse.Spec.Combinators.make_constant_size_parser"
] | [] | false | false | false | false | false | let make_constant_size_parser_impl
(sz: nat)
(sz': U32.t{U32.v sz' == sz})
(#t: Type0)
(f: (s: bytes{Seq.length s == sz} -> GTot (option t)))
(u: squash (make_constant_size_parser_precond sz t f))
(f':
(s: buffer8{B.length s == sz}
-> HST.Stack (option t)
(requires (fun h -> B.live h s))
(ensures (fun h y h' -> M.modifies M.loc_none h h' /\ y == f (B.as_seq h s)))))
: Tot (parser_impl (make_constant_size_parser sz t f)) =
| fun (input: buffer8) (len: U32.t{len == B.len input}) ->
if U32.lt len sz'
then None
else
let s' = B.sub input 0ul sz' in
match f' s' with
| None -> None
| Some v -> Some (v, (sz' <: U32.t)) | false |
Spec.SHA3.Test.fst | Spec.SHA3.Test.test_vectors | val test_vectors:list vec | val test_vectors:list vec | let test_vectors : list vec = [
Vec SHA3_224 test1_plaintext test1_expected_sha3_224;
Vec SHA3_256 test1_plaintext test1_expected_sha3_256;
Vec SHA3_384 test1_plaintext test1_expected_sha3_384;
Vec SHA3_512 test1_plaintext test1_expected_sha3_512;
Vec SHA3_224 test2_plaintext test2_expected_sha3_224;
Vec SHA3_256 test2_plaintext test2_expected_sha3_256;
Vec SHA3_384 test2_plaintext test2_expected_sha3_384;
Vec SHA3_512 test2_plaintext test2_expected_sha3_512;
Vec SHA3_224 test3_plaintext test3_expected_sha3_224;
Vec SHA3_256 test3_plaintext test3_expected_sha3_256;
Vec SHA3_384 test3_plaintext test3_expected_sha3_384;
Vec SHA3_512 test3_plaintext test3_expected_sha3_512;
Vec SHA3_224 test4_plaintext test4_expected_sha3_224;
Vec SHA3_256 test4_plaintext test4_expected_sha3_256;
Vec SHA3_384 test4_plaintext test4_expected_sha3_384;
Vec SHA3_512 test4_plaintext test4_expected_sha3_512;
Vec1 SHAKE128 test5_plaintext_shake128 test5_expected_shake128;
Vec1 SHAKE128 test6_plaintext_shake128 test6_expected_shake128;
Vec1 SHAKE128 test7_plaintext_shake128 test7_expected_shake128;
Vec1 SHAKE128 test8_plaintext_shake128 test8_expected_shake128;
Vec1 SHAKE256 test9_plaintext_shake256 test9_expected_shake256;
Vec1 SHAKE256 test10_plaintext_shake256 test10_expected_shake256;
Vec1 SHAKE256 test11_plaintext_shake256 test11_expected_shake256;
Vec1 SHAKE256 test12_plaintext_shake256 test12_expected_shake256
] | {
"file_name": "specs/tests/Spec.SHA3.Test.fst",
"git_rev": "eb1badfa34c70b0bbe0fe24fe0f49fb1295c7872",
"git_url": "https://github.com/project-everest/hacl-star.git",
"project_name": "hacl-star"
} | {
"end_col": 1,
"end_line": 511,
"start_col": 0,
"start_line": 481
} | module Spec.SHA3.Test
open FStar.Mul
open Lib.IntTypes
open Lib.RawIntTypes
open Lib.Sequence
open Lib.ByteSequence
module PS = Lib.PrintSequence
#set-options "--z3rlimit 50 --fuel 0 --ifuel 0"
/// Test1_SHA3
let test1_plaintext : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test1_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x6buy; 0x4euy; 0x03uy; 0x42uy; 0x36uy; 0x67uy; 0xdbuy; 0xb7uy;
0x3buy; 0x6euy; 0x15uy; 0x45uy; 0x4fuy; 0x0euy; 0xb1uy; 0xabuy;
0xd4uy; 0x59uy; 0x7fuy; 0x9auy; 0x1buy; 0x07uy; 0x8euy; 0x3fuy;
0x5buy; 0x5auy; 0x6buy; 0xc7uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test1_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa7uy; 0xffuy; 0xc6uy; 0xf8uy; 0xbfuy; 0x1euy; 0xd7uy; 0x66uy;
0x51uy; 0xc1uy; 0x47uy; 0x56uy; 0xa0uy; 0x61uy; 0xd6uy; 0x62uy;
0xf5uy; 0x80uy; 0xffuy; 0x4duy; 0xe4uy; 0x3buy; 0x49uy; 0xfauy;
0x82uy; 0xd8uy; 0x0auy; 0x4buy; 0x80uy; 0xf8uy; 0x43uy; 0x4auy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test1_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x0cuy; 0x63uy; 0xa7uy; 0x5buy; 0x84uy; 0x5euy; 0x4fuy; 0x7duy;
0x01uy; 0x10uy; 0x7duy; 0x85uy; 0x2euy; 0x4cuy; 0x24uy; 0x85uy;
0xc5uy; 0x1auy; 0x50uy; 0xaauy; 0xaauy; 0x94uy; 0xfcuy; 0x61uy;
0x99uy; 0x5euy; 0x71uy; 0xbbuy; 0xeeuy; 0x98uy; 0x3auy; 0x2auy;
0xc3uy; 0x71uy; 0x38uy; 0x31uy; 0x26uy; 0x4auy; 0xdbuy; 0x47uy;
0xfbuy; 0x6buy; 0xd1uy; 0xe0uy; 0x58uy; 0xd5uy; 0xf0uy; 0x04uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test1_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xa6uy; 0x9fuy; 0x73uy; 0xccuy; 0xa2uy; 0x3auy; 0x9auy; 0xc5uy;
0xc8uy; 0xb5uy; 0x67uy; 0xdcuy; 0x18uy; 0x5auy; 0x75uy; 0x6euy;
0x97uy; 0xc9uy; 0x82uy; 0x16uy; 0x4fuy; 0xe2uy; 0x58uy; 0x59uy;
0xe0uy; 0xd1uy; 0xdcuy; 0xc1uy; 0x47uy; 0x5cuy; 0x80uy; 0xa6uy;
0x15uy; 0xb2uy; 0x12uy; 0x3auy; 0xf1uy; 0xf5uy; 0xf9uy; 0x4cuy;
0x11uy; 0xe3uy; 0xe9uy; 0x40uy; 0x2cuy; 0x3auy; 0xc5uy; 0x58uy;
0xf5uy; 0x00uy; 0x19uy; 0x9duy; 0x95uy; 0xb6uy; 0xd3uy; 0xe3uy;
0x01uy; 0x75uy; 0x85uy; 0x86uy; 0x28uy; 0x1duy; 0xcduy; 0x26uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test2_SHA3
let test2_plaintext : lbytes 3 =
let l = List.Tot.map u8_from_UInt8 [ 0x61uy; 0x62uy; 0x63uy ] in
assert_norm (List.Tot.length l == 3);
of_list l
let test2_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0xe6uy; 0x42uy; 0x82uy; 0x4cuy; 0x3fuy; 0x8cuy; 0xf2uy; 0x4auy;
0xd0uy; 0x92uy; 0x34uy; 0xeeuy; 0x7duy; 0x3cuy; 0x76uy; 0x6fuy;
0xc9uy; 0xa3uy; 0xa5uy; 0x16uy; 0x8duy; 0x0cuy; 0x94uy; 0xaduy;
0x73uy; 0xb4uy; 0x6fuy; 0xdfuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test2_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x3auy; 0x98uy; 0x5duy; 0xa7uy; 0x4fuy; 0xe2uy; 0x25uy; 0xb2uy;
0x04uy; 0x5cuy; 0x17uy; 0x2duy; 0x6buy; 0xd3uy; 0x90uy; 0xbduy;
0x85uy; 0x5fuy; 0x08uy; 0x6euy; 0x3euy; 0x9duy; 0x52uy; 0x5buy;
0x46uy; 0xbfuy; 0xe2uy; 0x45uy; 0x11uy; 0x43uy; 0x15uy; 0x32uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test2_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0xecuy; 0x01uy; 0x49uy; 0x82uy; 0x88uy; 0x51uy; 0x6fuy; 0xc9uy;
0x26uy; 0x45uy; 0x9fuy; 0x58uy; 0xe2uy; 0xc6uy; 0xaduy; 0x8duy;
0xf9uy; 0xb4uy; 0x73uy; 0xcbuy; 0x0fuy; 0xc0uy; 0x8cuy; 0x25uy;
0x96uy; 0xdauy; 0x7cuy; 0xf0uy; 0xe4uy; 0x9buy; 0xe4uy; 0xb2uy;
0x98uy; 0xd8uy; 0x8cuy; 0xeauy; 0x92uy; 0x7auy; 0xc7uy; 0xf5uy;
0x39uy; 0xf1uy; 0xeduy; 0xf2uy; 0x28uy; 0x37uy; 0x6duy; 0x25uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test2_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xb7uy; 0x51uy; 0x85uy; 0x0buy; 0x1auy; 0x57uy; 0x16uy; 0x8auy;
0x56uy; 0x93uy; 0xcduy; 0x92uy; 0x4buy; 0x6buy; 0x09uy; 0x6euy;
0x08uy; 0xf6uy; 0x21uy; 0x82uy; 0x74uy; 0x44uy; 0xf7uy; 0x0duy;
0x88uy; 0x4fuy; 0x5duy; 0x02uy; 0x40uy; 0xd2uy; 0x71uy; 0x2euy;
0x10uy; 0xe1uy; 0x16uy; 0xe9uy; 0x19uy; 0x2auy; 0xf3uy; 0xc9uy;
0x1auy; 0x7euy; 0xc5uy; 0x76uy; 0x47uy; 0xe3uy; 0x93uy; 0x40uy;
0x57uy; 0x34uy; 0x0buy; 0x4cuy; 0xf4uy; 0x08uy; 0xd5uy; 0xa5uy;
0x65uy; 0x92uy; 0xf8uy; 0x27uy; 0x4euy; 0xecuy; 0x53uy; 0xf0uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test3_SHA3
let test3_plaintext : lbytes 56 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy
] in
assert_norm (List.Tot.length l == 56);
of_list l
let test3_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x8auy; 0x24uy; 0x10uy; 0x8buy; 0x15uy; 0x4auy; 0xdauy; 0x21uy;
0xc9uy; 0xfduy; 0x55uy; 0x74uy; 0x49uy; 0x44uy; 0x79uy; 0xbauy;
0x5cuy; 0x7euy; 0x7auy; 0xb7uy; 0x6euy; 0xf2uy; 0x64uy; 0xeauy;
0xd0uy; 0xfcuy; 0xceuy; 0x33uy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test3_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x41uy; 0xc0uy; 0xdbuy; 0xa2uy; 0xa9uy; 0xd6uy; 0x24uy; 0x08uy;
0x49uy; 0x10uy; 0x03uy; 0x76uy; 0xa8uy; 0x23uy; 0x5euy; 0x2cuy;
0x82uy; 0xe1uy; 0xb9uy; 0x99uy; 0x8auy; 0x99uy; 0x9euy; 0x21uy;
0xdbuy; 0x32uy; 0xdduy; 0x97uy; 0x49uy; 0x6duy; 0x33uy; 0x76uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test3_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x99uy; 0x1cuy; 0x66uy; 0x57uy; 0x55uy; 0xebuy; 0x3auy; 0x4buy;
0x6buy; 0xbduy; 0xfbuy; 0x75uy; 0xc7uy; 0x8auy; 0x49uy; 0x2euy;
0x8cuy; 0x56uy; 0xa2uy; 0x2cuy; 0x5cuy; 0x4duy; 0x7euy; 0x42uy;
0x9buy; 0xfduy; 0xbcuy; 0x32uy; 0xb9uy; 0xd4uy; 0xaduy; 0x5auy;
0xa0uy; 0x4auy; 0x1fuy; 0x07uy; 0x6euy; 0x62uy; 0xfeuy; 0xa1uy;
0x9euy; 0xefuy; 0x51uy; 0xacuy; 0xd0uy; 0x65uy; 0x7cuy; 0x22uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test3_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0x04uy; 0xa3uy; 0x71uy; 0xe8uy; 0x4euy; 0xcfuy; 0xb5uy; 0xb8uy;
0xb7uy; 0x7cuy; 0xb4uy; 0x86uy; 0x10uy; 0xfcuy; 0xa8uy; 0x18uy;
0x2duy; 0xd4uy; 0x57uy; 0xceuy; 0x6fuy; 0x32uy; 0x6auy; 0x0fuy;
0xd3uy; 0xd7uy; 0xecuy; 0x2fuy; 0x1euy; 0x91uy; 0x63uy; 0x6duy;
0xeeuy; 0x69uy; 0x1fuy; 0xbeuy; 0x0cuy; 0x98uy; 0x53uy; 0x02uy;
0xbauy; 0x1buy; 0x0duy; 0x8duy; 0xc7uy; 0x8cuy; 0x08uy; 0x63uy;
0x46uy; 0xb5uy; 0x33uy; 0xb4uy; 0x9cuy; 0x03uy; 0x0duy; 0x99uy;
0xa2uy; 0x7duy; 0xafuy; 0x11uy; 0x39uy; 0xd6uy; 0xe7uy; 0x5euy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test4_SHA3
let test4_plaintext : lbytes 112 =
let l = List.Tot.map u8_from_UInt8 [
0x61uy; 0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy;
0x62uy; 0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy;
0x63uy; 0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy;
0x64uy; 0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy;
0x65uy; 0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy;
0x66uy; 0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy;
0x67uy; 0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy;
0x68uy; 0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy;
0x69uy; 0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy;
0x6auy; 0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy;
0x6buy; 0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy;
0x6cuy; 0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy;
0x6duy; 0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy;
0x6euy; 0x6fuy; 0x70uy; 0x71uy; 0x72uy; 0x73uy; 0x74uy; 0x75uy
] in
assert_norm (List.Tot.length l == 112);
of_list l
let test4_expected_sha3_224 : lbytes 28 =
let l = List.Tot.map u8_from_UInt8 [
0x54uy; 0x3euy; 0x68uy; 0x68uy; 0xe1uy; 0x66uy; 0x6cuy; 0x1auy;
0x64uy; 0x36uy; 0x30uy; 0xdfuy; 0x77uy; 0x36uy; 0x7auy; 0xe5uy;
0xa6uy; 0x2auy; 0x85uy; 0x07uy; 0x0auy; 0x51uy; 0xc1uy; 0x4cuy;
0xbfuy; 0x66uy; 0x5cuy; 0xbcuy
] in
assert_norm (List.Tot.length l == 28);
of_list l
let test4_expected_sha3_256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x91uy; 0x6fuy; 0x60uy; 0x61uy; 0xfeuy; 0x87uy; 0x97uy; 0x41uy;
0xcauy; 0x64uy; 0x69uy; 0xb4uy; 0x39uy; 0x71uy; 0xdfuy; 0xdbuy;
0x28uy; 0xb1uy; 0xa3uy; 0x2duy; 0xc3uy; 0x6cuy; 0xb3uy; 0x25uy;
0x4euy; 0x81uy; 0x2buy; 0xe2uy; 0x7auy; 0xaduy; 0x1duy; 0x18uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test4_expected_sha3_384 : lbytes 48 =
let l = List.Tot.map u8_from_UInt8 [
0x79uy; 0x40uy; 0x7duy; 0x3buy; 0x59uy; 0x16uy; 0xb5uy; 0x9cuy;
0x3euy; 0x30uy; 0xb0uy; 0x98uy; 0x22uy; 0x97uy; 0x47uy; 0x91uy;
0xc3uy; 0x13uy; 0xfbuy; 0x9euy; 0xccuy; 0x84uy; 0x9euy; 0x40uy;
0x6fuy; 0x23uy; 0x59uy; 0x2duy; 0x04uy; 0xf6uy; 0x25uy; 0xdcuy;
0x8cuy; 0x70uy; 0x9buy; 0x98uy; 0xb4uy; 0x3buy; 0x38uy; 0x52uy;
0xb3uy; 0x37uy; 0x21uy; 0x61uy; 0x79uy; 0xaauy; 0x7fuy; 0xc7uy
] in
assert_norm (List.Tot.length l == 48);
of_list l
let test4_expected_sha3_512 : lbytes 64 =
let l = List.Tot.map u8_from_UInt8 [
0xafuy; 0xebuy; 0xb2uy; 0xefuy; 0x54uy; 0x2euy; 0x65uy; 0x79uy;
0xc5uy; 0x0cuy; 0xaduy; 0x06uy; 0xd2uy; 0xe5uy; 0x78uy; 0xf9uy;
0xf8uy; 0xdduy; 0x68uy; 0x81uy; 0xd7uy; 0xdcuy; 0x82uy; 0x4duy;
0x26uy; 0x36uy; 0x0fuy; 0xeeuy; 0xbfuy; 0x18uy; 0xa4uy; 0xfauy;
0x73uy; 0xe3uy; 0x26uy; 0x11uy; 0x22uy; 0x94uy; 0x8euy; 0xfcuy;
0xfduy; 0x49uy; 0x2euy; 0x74uy; 0xe8uy; 0x2euy; 0x21uy; 0x89uy;
0xeduy; 0x0fuy; 0xb4uy; 0x40uy; 0xd1uy; 0x87uy; 0xf3uy; 0x82uy;
0x27uy; 0x0cuy; 0xb4uy; 0x55uy; 0xf2uy; 0x1duy; 0xd1uy; 0x85uy
] in
assert_norm (List.Tot.length l == 64);
of_list l
/// Test5_SHAKE128
let test5_plaintext_shake128 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test5_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7fuy; 0x9cuy; 0x2buy; 0xa4uy; 0xe8uy; 0x8fuy; 0x82uy; 0x7duy;
0x61uy; 0x60uy; 0x45uy; 0x50uy; 0x76uy; 0x05uy; 0x85uy; 0x3euy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test6_SHAKE128
let test6_plaintext_shake128 : lbytes 14 =
let l = List.Tot.map u8_from_UInt8 [
0x52uy; 0x97uy; 0x7euy; 0x53uy; 0x2buy; 0xccuy; 0xdbuy; 0x89uy;
0xdfuy; 0xefuy; 0xf7uy; 0xe9uy; 0xe4uy; 0xaduy
] in
assert_norm (List.Tot.length l == 14);
of_list l
let test6_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0xfbuy; 0xfbuy; 0xa5uy; 0xc1uy; 0xe1uy; 0x79uy; 0xdfuy; 0x14uy;
0x69uy; 0xfcuy; 0xc8uy; 0x58uy; 0x8auy; 0xe5uy; 0xd2uy; 0xccuy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test7_SHAKE128
let test7_plaintext_shake128 : lbytes 34 =
let l = List.Tot.map u8_from_UInt8 [
0x4auy; 0x20uy; 0x6auy; 0x5buy; 0x8auy; 0xa3uy; 0x58uy; 0x6cuy;
0x06uy; 0x67uy; 0xa4uy; 0x00uy; 0x20uy; 0xd6uy; 0x5fuy; 0xf5uy;
0x11uy; 0xd5uy; 0x2buy; 0x73uy; 0x2euy; 0xf7uy; 0xa0uy; 0xc5uy;
0x69uy; 0xf1uy; 0xeeuy; 0x68uy; 0x1auy; 0x4fuy; 0xc3uy; 0x62uy;
0x00uy; 0x65uy
] in
assert_norm (List.Tot.length l == 34);
of_list l
let test7_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x7buy; 0xb4uy; 0x33uy; 0x75uy; 0x2buy; 0x98uy; 0xf9uy; 0x15uy;
0xbeuy; 0x51uy; 0x82uy; 0xbcuy; 0x1fuy; 0x09uy; 0x66uy; 0x48uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test8_SHAKE128
let test8_plaintext_shake128 : lbytes 83 =
let l = List.Tot.map u8_from_UInt8 [
0x24uy; 0x69uy; 0xf1uy; 0x01uy; 0xc9uy; 0xb4uy; 0x99uy; 0xa9uy;
0x30uy; 0xa9uy; 0x7euy; 0xf1uy; 0xb3uy; 0x46uy; 0x73uy; 0xecuy;
0x74uy; 0x39uy; 0x3fuy; 0xd9uy; 0xfauy; 0xf6uy; 0x58uy; 0xe3uy;
0x1fuy; 0x06uy; 0xeeuy; 0x0buy; 0x29uy; 0xa2uy; 0x2buy; 0x62uy;
0x37uy; 0x80uy; 0xbauy; 0x7buy; 0xdfuy; 0xeduy; 0x86uy; 0x20uy;
0x15uy; 0x1cuy; 0xc4uy; 0x44uy; 0x4euy; 0xbeuy; 0x33uy; 0x39uy;
0xe6uy; 0xd2uy; 0xa2uy; 0x23uy; 0xbfuy; 0xbfuy; 0xb4uy; 0xaduy;
0x2cuy; 0xa0uy; 0xe0uy; 0xfauy; 0x0duy; 0xdfuy; 0xbbuy; 0xdfuy;
0x3buy; 0x05uy; 0x7auy; 0x4fuy; 0x26uy; 0xd0uy; 0xb2uy; 0x16uy;
0xbcuy; 0x87uy; 0x63uy; 0xcauy; 0x8duy; 0x8auy; 0x35uy; 0xffuy;
0x2duy; 0x2duy; 0x01uy
] in
assert_norm (List.Tot.length l == 83);
of_list l
let test8_expected_shake128 : lbytes 16 =
let l = List.Tot.map u8_from_UInt8 [
0x00uy; 0xffuy; 0x5euy; 0xf0uy; 0xcduy; 0x7fuy; 0x8fuy; 0x90uy;
0xaduy; 0x94uy; 0xb7uy; 0x97uy; 0xe9uy; 0xd4uy; 0xdduy; 0x30uy
] in
assert_norm (List.Tot.length l == 16);
of_list l
/// Test9_SHAKE256
let test9_plaintext_shake256 : lbytes 0 =
let l = List.Tot.map u8_from_UInt8 [] in
assert_norm (List.Tot.length l == 0);
of_list l
let test9_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x46uy; 0xb9uy; 0xdduy; 0x2buy; 0x0buy; 0xa8uy; 0x8duy; 0x13uy;
0x23uy; 0x3buy; 0x3fuy; 0xebuy; 0x74uy; 0x3euy; 0xebuy; 0x24uy;
0x3fuy; 0xcduy; 0x52uy; 0xeauy; 0x62uy; 0xb8uy; 0x1buy; 0x82uy;
0xb5uy; 0x0cuy; 0x27uy; 0x64uy; 0x6euy; 0xd5uy; 0x76uy; 0x2fuy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test10_SHAKE256
let test10_plaintext_shake256 : lbytes 17 =
let l = List.Tot.map u8_from_UInt8 [
0xf9uy; 0xdauy; 0x78uy; 0xc8uy; 0x90uy; 0x84uy; 0x70uy; 0x40uy;
0x45uy; 0x4buy; 0xa6uy; 0x42uy; 0x98uy; 0x82uy; 0xb0uy; 0x54uy;
0x09uy
] in
assert_norm (List.Tot.length l == 17);
of_list l
let test10_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xa8uy; 0x49uy; 0x83uy; 0xc9uy; 0xfeuy; 0x75uy; 0xaduy; 0x0duy;
0xe1uy; 0x9euy; 0x2cuy; 0x84uy; 0x20uy; 0xa7uy; 0xeauy; 0x85uy;
0xb2uy; 0x51uy; 0x02uy; 0x19uy; 0x56uy; 0x14uy; 0xdfuy; 0xa5uy;
0x34uy; 0x7duy; 0xe6uy; 0x0auy; 0x1cuy; 0xe1uy; 0x3buy; 0x60uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test11_SHAKE256
let test11_plaintext_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0xefuy; 0x89uy; 0x6cuy; 0xdcuy; 0xb3uy; 0x63uy; 0xa6uy; 0x15uy;
0x91uy; 0x78uy; 0xa1uy; 0xbbuy; 0x1cuy; 0x99uy; 0x39uy; 0x46uy;
0xc5uy; 0x04uy; 0x02uy; 0x09uy; 0x5cuy; 0xdauy; 0xeauy; 0x4fuy;
0xd4uy; 0xd4uy; 0x19uy; 0xaauy; 0x47uy; 0x32uy; 0x1cuy; 0x88uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
let test11_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x7auy; 0xbbuy; 0xa4uy; 0xe8uy; 0xb8uy; 0xdduy; 0x76uy; 0x6buy;
0xbauy; 0xbeuy; 0x98uy; 0xf8uy; 0xf1uy; 0x69uy; 0xcbuy; 0x62uy;
0x08uy; 0x67uy; 0x4duy; 0xe1uy; 0x9auy; 0x51uy; 0xd7uy; 0x3cuy;
0x92uy; 0xb7uy; 0xdcuy; 0x04uy; 0xa4uy; 0xb5uy; 0xeeuy; 0x3duy
] in
assert_norm (List.Tot.length l == 32);
of_list l
/// Test12_SHAKE256
let test12_plaintext_shake256 : lbytes 78 =
let l = List.Tot.map u8_from_UInt8 [
0xdeuy; 0x70uy; 0x1fuy; 0x10uy; 0xaduy; 0x39uy; 0x61uy; 0xb0uy;
0xdauy; 0xccuy; 0x96uy; 0x87uy; 0x3auy; 0x3cuy; 0xd5uy; 0x58uy;
0x55uy; 0x81uy; 0x88uy; 0xffuy; 0x69uy; 0x6duy; 0x85uy; 0x01uy;
0xb2uy; 0xe2uy; 0x7buy; 0x67uy; 0xe9uy; 0x41uy; 0x90uy; 0xcduy;
0x0buy; 0x25uy; 0x48uy; 0xb6uy; 0x5buy; 0x52uy; 0xa9uy; 0x22uy;
0xaauy; 0xe8uy; 0x9duy; 0x63uy; 0xd6uy; 0xdduy; 0x97uy; 0x2cuy;
0x91uy; 0xa9uy; 0x79uy; 0xebuy; 0x63uy; 0x43uy; 0xb6uy; 0x58uy;
0xf2uy; 0x4duy; 0xb3uy; 0x4euy; 0x82uy; 0x8buy; 0x74uy; 0xdbuy;
0xb8uy; 0x9auy; 0x74uy; 0x93uy; 0xa3uy; 0xdfuy; 0xd4uy; 0x29uy;
0xfduy; 0xbduy; 0xb8uy; 0x40uy; 0xaduy; 0x0buy
] in
assert_norm (List.Tot.length l == 78);
of_list l
let test12_expected_shake256 : lbytes 32 =
let l = List.Tot.map u8_from_UInt8 [
0x64uy; 0x2fuy; 0x3fuy; 0x23uy; 0x5auy; 0xc7uy; 0xe3uy; 0xd4uy;
0x34uy; 0x06uy; 0x3buy; 0x5fuy; 0xc9uy; 0x21uy; 0x5fuy; 0xc3uy;
0xf0uy; 0xe5uy; 0x91uy; 0xe2uy; 0xe7uy; 0xfduy; 0x17uy; 0x66uy;
0x8duy; 0x1auy; 0x0cuy; 0x87uy; 0x46uy; 0x87uy; 0x35uy; 0xc2uy
] in
assert_norm (List.Tot.length l == 32);
of_list l
type keccak_alg =
| SHA3_224
| SHA3_256
| SHA3_384
| SHA3_512
type shake_alg =
| SHAKE128
| SHAKE256
let sha3_length (a:keccak_alg) =
allow_inversion keccak_alg;
match a with
| SHA3_224 -> 28
| SHA3_256 -> 32
| SHA3_384 -> 48
| SHA3_512 -> 64
noeq type vec =
| Vec :
a:keccak_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash = sha3_length a} -> vec
| Vec1 :
a:shake_alg
-> plain:bytes{length plain <= max_size_t}
-> hash:bytes{length hash <= max_size_t} -> vec | {
"checked_file": "/",
"dependencies": [
"Spec.SHA3.fst.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.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.Mul.fst.checked",
"FStar.List.Tot.fst.checked",
"FStar.List.fst.checked",
"FStar.IO.fst.checked"
],
"interface_file": false,
"source_file": "Spec.SHA3.Test.fst"
} | [
{
"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.SHA3",
"short_module": null
},
{
"abbrev": false,
"full_module": "Spec.SHA3",
"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.SHA3.Test.vec | Prims.Tot | [
"total"
] | [] | [
"Prims.Cons",
"Spec.SHA3.Test.vec",
"Spec.SHA3.Test.Vec",
"Spec.SHA3.Test.SHA3_224",
"Spec.SHA3.Test.test1_plaintext",
"Spec.SHA3.Test.test1_expected_sha3_224",
"Spec.SHA3.Test.SHA3_256",
"Spec.SHA3.Test.test1_expected_sha3_256",
"Spec.SHA3.Test.SHA3_384",
"Spec.SHA3.Test.test1_expected_sha3_384",
"Spec.SHA3.Test.SHA3_512",
"Spec.SHA3.Test.test1_expected_sha3_512",
"Spec.SHA3.Test.test2_plaintext",
"Spec.SHA3.Test.test2_expected_sha3_224",
"Spec.SHA3.Test.test2_expected_sha3_256",
"Spec.SHA3.Test.test2_expected_sha3_384",
"Spec.SHA3.Test.test2_expected_sha3_512",
"Spec.SHA3.Test.test3_plaintext",
"Spec.SHA3.Test.test3_expected_sha3_224",
"Spec.SHA3.Test.test3_expected_sha3_256",
"Spec.SHA3.Test.test3_expected_sha3_384",
"Spec.SHA3.Test.test3_expected_sha3_512",
"Spec.SHA3.Test.test4_plaintext",
"Spec.SHA3.Test.test4_expected_sha3_224",
"Spec.SHA3.Test.test4_expected_sha3_256",
"Spec.SHA3.Test.test4_expected_sha3_384",
"Spec.SHA3.Test.test4_expected_sha3_512",
"Spec.SHA3.Test.Vec1",
"Spec.SHA3.Test.SHAKE128",
"Spec.SHA3.Test.test5_plaintext_shake128",
"Spec.SHA3.Test.test5_expected_shake128",
"Spec.SHA3.Test.test6_plaintext_shake128",
"Spec.SHA3.Test.test6_expected_shake128",
"Spec.SHA3.Test.test7_plaintext_shake128",
"Spec.SHA3.Test.test7_expected_shake128",
"Spec.SHA3.Test.test8_plaintext_shake128",
"Spec.SHA3.Test.test8_expected_shake128",
"Spec.SHA3.Test.SHAKE256",
"Spec.SHA3.Test.test9_plaintext_shake256",
"Spec.SHA3.Test.test9_expected_shake256",
"Spec.SHA3.Test.test10_plaintext_shake256",
"Spec.SHA3.Test.test10_expected_shake256",
"Spec.SHA3.Test.test11_plaintext_shake256",
"Spec.SHA3.Test.test11_expected_shake256",
"Spec.SHA3.Test.test12_plaintext_shake256",
"Spec.SHA3.Test.test12_expected_shake256",
"Prims.Nil"
] | [] | false | false | false | true | false | let test_vectors:list vec =
| [
Vec SHA3_224 test1_plaintext test1_expected_sha3_224;
Vec SHA3_256 test1_plaintext test1_expected_sha3_256;
Vec SHA3_384 test1_plaintext test1_expected_sha3_384;
Vec SHA3_512 test1_plaintext test1_expected_sha3_512;
Vec SHA3_224 test2_plaintext test2_expected_sha3_224;
Vec SHA3_256 test2_plaintext test2_expected_sha3_256;
Vec SHA3_384 test2_plaintext test2_expected_sha3_384;
Vec SHA3_512 test2_plaintext test2_expected_sha3_512;
Vec SHA3_224 test3_plaintext test3_expected_sha3_224;
Vec SHA3_256 test3_plaintext test3_expected_sha3_256;
Vec SHA3_384 test3_plaintext test3_expected_sha3_384;
Vec SHA3_512 test3_plaintext test3_expected_sha3_512;
Vec SHA3_224 test4_plaintext test4_expected_sha3_224;
Vec SHA3_256 test4_plaintext test4_expected_sha3_256;
Vec SHA3_384 test4_plaintext test4_expected_sha3_384;
Vec SHA3_512 test4_plaintext test4_expected_sha3_512;
Vec1 SHAKE128 test5_plaintext_shake128 test5_expected_shake128;
Vec1 SHAKE128 test6_plaintext_shake128 test6_expected_shake128;
Vec1 SHAKE128 test7_plaintext_shake128 test7_expected_shake128;
Vec1 SHAKE128 test8_plaintext_shake128 test8_expected_shake128;
Vec1 SHAKE256 test9_plaintext_shake256 test9_expected_shake256;
Vec1 SHAKE256 test10_plaintext_shake256 test10_expected_shake256;
Vec1 SHAKE256 test11_plaintext_shake256 test11_expected_shake256;
Vec1 SHAKE256 test12_plaintext_shake256 test12_expected_shake256
] | false |
GC.fst | GC.valid | val valid : a: GC.abs_node -> Prims.bool | let valid a = a <> no_abs | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 25,
"end_line": 30,
"start_col": 0,
"start_line": 30
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a} | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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: GC.abs_node -> Prims.bool | Prims.Tot | [
"total"
] | [] | [
"GC.abs_node",
"Prims.op_disEquality",
"GC.no_abs",
"Prims.bool"
] | [] | false | false | false | true | false | let valid a =
| a <> no_abs | false |
|
GC.fst | GC.is_mem_addr | val is_mem_addr : i: Prims.int -> Prims.bool | let is_mem_addr i = mem_lo <= i && i < mem_hi | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 45,
"end_line": 22,
"start_col": 0,
"start_line": 22
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x} | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | i: Prims.int -> Prims.bool | Prims.Tot | [
"total"
] | [] | [
"Prims.int",
"Prims.op_AmpAmp",
"Prims.op_LessThanOrEqual",
"GC.mem_lo",
"Prims.op_LessThan",
"GC.mem_hi",
"Prims.bool"
] | [] | false | false | false | true | false | let is_mem_addr i =
| mem_lo <= i && i < mem_hi | false |
|
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.inspect_unascribe | val inspect_unascribe (t: term) : Tac term_view | val inspect_unascribe (t: term) : Tac term_view | let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 12,
"end_line": 37,
"start_col": 8,
"start_line": 32
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | t: FStar.Tactics.NamedView.term -> FStar.Tactics.Effect.Tac FStar.Tactics.NamedView.term_view | FStar.Tactics.Effect.Tac | [] | [] | [
"FStar.Tactics.NamedView.term",
"FStar.Pervasives.Native.option",
"Prims.bool",
"FStar.Reflection.V2.Formula.inspect_unascribe",
"FStar.Tactics.NamedView.term_view",
"FStar.Tactics.NamedView.comp",
"FStar.Tactics.NamedView.named_term_view",
"FStar.Tactics.NamedView.inspect"
] | [
"recursion"
] | false | true | false | false | false | let rec inspect_unascribe (t: term) : Tac term_view =
| match inspect t with
| Tv_AscribedT t _ _ _ | Tv_AscribedC t _ _ _ -> inspect_unascribe t
| tv -> tv | false |
GC.fst | GC.gc_post | val gc_post : a: Type -> Type | let gc_post (a:Type) = a -> gc_state -> Type0 | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 45,
"end_line": 86,
"start_col": 0,
"start_line": 86
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 -> Type | Prims.Tot | [
"total"
] | [] | [
"GC.gc_state"
] | [] | false | false | false | true | true | let gc_post (a: Type) =
| a -> gc_state -> Type0 | false |
|
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.collect_app' | val collect_app' (args: list argv) (t: term) : Tac (term * list argv) (decreases t) | val collect_app' (args: list argv) (t: term) : Tac (term * list argv) (decreases t) | let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args) | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 20,
"end_line": 44,
"start_col": 8,
"start_line": 39
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | args: Prims.list FStar.Stubs.Reflection.V2.Data.argv -> t: FStar.Tactics.NamedView.term
-> FStar.Tactics.Effect.Tac
(FStar.Tactics.NamedView.term * Prims.list FStar.Stubs.Reflection.V2.Data.argv) | FStar.Tactics.Effect.Tac | [
""
] | [] | [
"Prims.list",
"FStar.Stubs.Reflection.V2.Data.argv",
"FStar.Tactics.NamedView.term",
"FStar.Reflection.V2.Formula.collect_app'",
"Prims.Cons",
"FStar.Pervasives.Native.tuple2",
"FStar.Tactics.NamedView.named_term_view",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Tactics.NamedView.term_view",
"FStar.Reflection.V2.Formula.inspect_unascribe"
] | [
"recursion"
] | false | true | false | false | false | let rec collect_app' (args: list argv) (t: term) : Tac (term * list argv) (decreases t) =
| match inspect_unascribe t with
| Tv_App l r -> collect_app' (r :: args) l
| _ -> (t, args) | false |
GC.fst | GC.upd_map | val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b | val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b | let upd_map #a #b f i v = fun j -> if i=j then v else f j | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 57,
"end_line": 108,
"start_col": 0,
"start_line": 108
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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: (_: a -> b) -> i: a -> v: b -> j: a -> b | Prims.Tot | [
"total"
] | [] | [
"Prims.eqtype",
"Prims.op_Equality",
"Prims.bool"
] | [] | false | false | false | false | false | let upd_map #a #b f i v =
| fun j -> if i = j then v else f j | false |
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.mk_Forall | val mk_Forall (typ pred: term) : Tot formula | val mk_Forall (typ pred: term) : Tot formula | let mk_Forall (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit))) | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 68,
"end_line": 77,
"start_col": 0,
"start_line": 73
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args)
private let collect_app = collect_app' []
/////
[@@plugin]
noeq type comparison =
| Eq of option typ (* Propositional equality (eq2), maybe annotated *)
| BoolEq of option typ (* Decidable, boolean equality (eq), maybe annotated *)
| Lt | Le | Gt | Ge (* Orderings, at type `int` (and subtypes) *)
[@@plugin]
noeq type formula =
| True_ : formula
| False_ : formula
| Comp : comparison -> term -> term -> formula
| And : term -> term -> formula
| Or : term -> term -> formula
| Not : term -> formula
| Implies: term -> term -> formula
| Iff : term -> term -> formula
| Forall : bv -> typ -> term -> formula
| Exists : bv -> typ -> term -> formula
| App : term -> term -> formula
| Name : namedv -> formula
| FV : fv -> formula
| IntLit : int -> formula
| F_Unknown : formula // Also a baked-in "None" | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | typ: FStar.Tactics.NamedView.term -> pred: FStar.Tactics.NamedView.term
-> FStar.Reflection.V2.Formula.formula | Prims.Tot | [
"total"
] | [] | [
"FStar.Tactics.NamedView.term",
"FStar.Reflection.V2.Formula.Forall",
"FStar.Tactics.NamedView.pack",
"FStar.Tactics.NamedView.Tv_App",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Stubs.Reflection.Types.term",
"FStar.Stubs.Reflection.V2.Data.aqualv",
"FStar.Tactics.NamedView.Tv_BVar",
"FStar.Stubs.Reflection.V2.Data.Q_Explicit",
"FStar.Tactics.NamedView.bv",
"FStar.Tactics.NamedView.pack_bv",
"FStar.Stubs.Reflection.V2.Data.Mkbv_view",
"FStar.Sealed.seal",
"FStar.Stubs.Reflection.Types.typ",
"FStar.Stubs.Reflection.V2.Data.as_ppname",
"FStar.Reflection.V2.Formula.formula"
] | [] | false | false | false | true | false | let mk_Forall (typ pred: term) : Tot formula =
| let b = pack_bv ({ ppname = as_ppname "x"; sort = seal typ; index = 0 }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit))) | false |
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.collect_app | val collect_app : t: FStar.Tactics.NamedView.term
-> FStar.Tactics.Effect.Tac
(FStar.Tactics.NamedView.term * Prims.list FStar.Stubs.Reflection.V2.Data.argv) | let collect_app = collect_app' [] | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 41,
"end_line": 46,
"start_col": 8,
"start_line": 46
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | t: FStar.Tactics.NamedView.term
-> FStar.Tactics.Effect.Tac
(FStar.Tactics.NamedView.term * Prims.list FStar.Stubs.Reflection.V2.Data.argv) | FStar.Tactics.Effect.Tac | [
""
] | [] | [
"FStar.Reflection.V2.Formula.collect_app'",
"Prims.Nil",
"FStar.Stubs.Reflection.V2.Data.argv"
] | [] | false | true | false | false | false | let collect_app =
| collect_app' [] | false |
|
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.mk_Exists | val mk_Exists (typ pred: term) : Tot formula | val mk_Exists (typ pred: term) : Tot formula | let mk_Exists (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Exists b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit))) | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 68,
"end_line": 83,
"start_col": 0,
"start_line": 79
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args)
private let collect_app = collect_app' []
/////
[@@plugin]
noeq type comparison =
| Eq of option typ (* Propositional equality (eq2), maybe annotated *)
| BoolEq of option typ (* Decidable, boolean equality (eq), maybe annotated *)
| Lt | Le | Gt | Ge (* Orderings, at type `int` (and subtypes) *)
[@@plugin]
noeq type formula =
| True_ : formula
| False_ : formula
| Comp : comparison -> term -> term -> formula
| And : term -> term -> formula
| Or : term -> term -> formula
| Not : term -> formula
| Implies: term -> term -> formula
| Iff : term -> term -> formula
| Forall : bv -> typ -> term -> formula
| Exists : bv -> typ -> term -> formula
| App : term -> term -> formula
| Name : namedv -> formula
| FV : fv -> formula
| IntLit : int -> formula
| F_Unknown : formula // Also a baked-in "None"
let mk_Forall (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit))) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | typ: FStar.Tactics.NamedView.term -> pred: FStar.Tactics.NamedView.term
-> FStar.Reflection.V2.Formula.formula | Prims.Tot | [
"total"
] | [] | [
"FStar.Tactics.NamedView.term",
"FStar.Reflection.V2.Formula.Exists",
"FStar.Tactics.NamedView.pack",
"FStar.Tactics.NamedView.Tv_App",
"FStar.Pervasives.Native.Mktuple2",
"FStar.Stubs.Reflection.Types.term",
"FStar.Stubs.Reflection.V2.Data.aqualv",
"FStar.Tactics.NamedView.Tv_BVar",
"FStar.Stubs.Reflection.V2.Data.Q_Explicit",
"FStar.Tactics.NamedView.bv",
"FStar.Tactics.NamedView.pack_bv",
"FStar.Stubs.Reflection.V2.Data.Mkbv_view",
"FStar.Sealed.seal",
"FStar.Stubs.Reflection.Types.typ",
"FStar.Stubs.Reflection.V2.Data.as_ppname",
"FStar.Reflection.V2.Formula.formula"
] | [] | false | false | false | true | false | let mk_Exists (typ pred: term) : Tot formula =
| let b = pack_bv ({ ppname = as_ppname "x"; sort = seal typ; index = 0 }) in
Exists b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit))) | false |
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.term_as_formula_total | val term_as_formula_total (t: term) : Tac formula | val term_as_formula_total (t: term) : Tac formula | let term_as_formula_total (t:term) : Tac formula =
term_as_formula' (maybe_unsquash_term t) | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 44,
"end_line": 175,
"start_col": 0,
"start_line": 174
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args)
private let collect_app = collect_app' []
/////
[@@plugin]
noeq type comparison =
| Eq of option typ (* Propositional equality (eq2), maybe annotated *)
| BoolEq of option typ (* Decidable, boolean equality (eq), maybe annotated *)
| Lt | Le | Gt | Ge (* Orderings, at type `int` (and subtypes) *)
[@@plugin]
noeq type formula =
| True_ : formula
| False_ : formula
| Comp : comparison -> term -> term -> formula
| And : term -> term -> formula
| Or : term -> term -> formula
| Not : term -> formula
| Implies: term -> term -> formula
| Iff : term -> term -> formula
| Forall : bv -> typ -> term -> formula
| Exists : bv -> typ -> term -> formula
| App : term -> term -> formula
| Name : namedv -> formula
| FV : fv -> formula
| IntLit : int -> formula
| F_Unknown : formula // Also a baked-in "None"
let mk_Forall (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
let mk_Exists (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Exists b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
[@@plugin]
let term_as_formula' (t:term) : Tac formula =
match inspect_unascribe t with
| Tv_Var n ->
Name n
| Tv_FVar fv
| Tv_UInst fv _ ->
// Cannot use `when` clauses when verifying!
let qn = inspect_fv fv in
if qn = true_qn then True_
else if qn = false_qn then False_
else FV fv
// TODO: l_Forall
// ...or should we just try to drop all squashes?
// TODO: b2t at this point ?
| Tv_App h0 t -> begin
let (h, ts) = collect_app h0 in
let h = un_uinst h in
match inspect h, ts@[t] with
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit); (a3, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = eq2_qn then Comp (Eq (Some a1)) a2 a3
else if qn = eq1_qn then Comp (BoolEq (Some a1)) a2 a3
else if qn = lt_qn then Comp Lt a2 a3
else if qn = lte_qn then Comp Le a2 a3
else if qn = gt_qn then Comp Gt a2 a3
else if qn = gte_qn then Comp Ge a2 a3
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Explicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = imp_qn then Implies a1 a2
else if qn = and_qn then And a1 a2
else if qn = iff_qn then Iff a1 a2
else if qn = or_qn then Or a1 a2
// Non-annotated comparisons
else if qn = eq2_qn then Comp (Eq None) a1 a2
else if qn = eq1_qn then Comp (BoolEq None) a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = forall_qn then mk_Forall a1 a2
else if qn = exists_qn then mk_Exists a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = not_qn then Not a
else if qn = b2t_qn then begin
if term_eq a (`false) then False_
else if term_eq a (`true) then True_
else App h0 (fst t)
end
else App h0 (fst t)
| _ ->
App h0 (fst t)
end
| Tv_Const (C_Int i) ->
IntLit i
(* Not formulas. *)
| Tv_Let _ _ _ _ _
| Tv_Match _ _ _
| Tv_Type _
| Tv_Abs _ _
| Tv_Arrow _ _
| Tv_Uvar _ _
| Tv_Unknown
| Tv_Unsupp
| Tv_Refine _ _ -> F_Unknown
(* Other constants? *)
| Tv_Const _ -> F_Unknown
(* Should not occur, we're using inspect *)
| Tv_BVar _ -> F_Unknown
| _ -> raise (TacticFailure "???")
// Unsquashing
let term_as_formula (t:term) : Tac formula =
match unsquash_term t with
| None -> F_Unknown
| Some t ->
term_as_formula' t
// Badly named, this only means it always returns a formula even if not properly | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | t: FStar.Tactics.NamedView.term -> FStar.Tactics.Effect.Tac FStar.Reflection.V2.Formula.formula | FStar.Tactics.Effect.Tac | [] | [] | [
"FStar.Tactics.NamedView.term",
"FStar.Reflection.V2.Formula.term_as_formula'",
"FStar.Reflection.V2.Derived.maybe_unsquash_term",
"FStar.Reflection.V2.Formula.formula"
] | [] | false | true | false | false | false | let term_as_formula_total (t: term) : Tac formula =
| term_as_formula' (maybe_unsquash_term t) | false |
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.namedv_to_string | val namedv_to_string (namedv: namedv) : Tac string | val namedv_to_string (namedv: namedv) : Tac string | let namedv_to_string (namedv : namedv) : Tac string =
let namedvv = inspect_namedv namedv in
unseal namedvv.ppname | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 25,
"end_line": 220,
"start_col": 8,
"start_line": 218
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args)
private let collect_app = collect_app' []
/////
[@@plugin]
noeq type comparison =
| Eq of option typ (* Propositional equality (eq2), maybe annotated *)
| BoolEq of option typ (* Decidable, boolean equality (eq), maybe annotated *)
| Lt | Le | Gt | Ge (* Orderings, at type `int` (and subtypes) *)
[@@plugin]
noeq type formula =
| True_ : formula
| False_ : formula
| Comp : comparison -> term -> term -> formula
| And : term -> term -> formula
| Or : term -> term -> formula
| Not : term -> formula
| Implies: term -> term -> formula
| Iff : term -> term -> formula
| Forall : bv -> typ -> term -> formula
| Exists : bv -> typ -> term -> formula
| App : term -> term -> formula
| Name : namedv -> formula
| FV : fv -> formula
| IntLit : int -> formula
| F_Unknown : formula // Also a baked-in "None"
let mk_Forall (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
let mk_Exists (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Exists b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
[@@plugin]
let term_as_formula' (t:term) : Tac formula =
match inspect_unascribe t with
| Tv_Var n ->
Name n
| Tv_FVar fv
| Tv_UInst fv _ ->
// Cannot use `when` clauses when verifying!
let qn = inspect_fv fv in
if qn = true_qn then True_
else if qn = false_qn then False_
else FV fv
// TODO: l_Forall
// ...or should we just try to drop all squashes?
// TODO: b2t at this point ?
| Tv_App h0 t -> begin
let (h, ts) = collect_app h0 in
let h = un_uinst h in
match inspect h, ts@[t] with
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit); (a3, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = eq2_qn then Comp (Eq (Some a1)) a2 a3
else if qn = eq1_qn then Comp (BoolEq (Some a1)) a2 a3
else if qn = lt_qn then Comp Lt a2 a3
else if qn = lte_qn then Comp Le a2 a3
else if qn = gt_qn then Comp Gt a2 a3
else if qn = gte_qn then Comp Ge a2 a3
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Explicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = imp_qn then Implies a1 a2
else if qn = and_qn then And a1 a2
else if qn = iff_qn then Iff a1 a2
else if qn = or_qn then Or a1 a2
// Non-annotated comparisons
else if qn = eq2_qn then Comp (Eq None) a1 a2
else if qn = eq1_qn then Comp (BoolEq None) a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = forall_qn then mk_Forall a1 a2
else if qn = exists_qn then mk_Exists a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = not_qn then Not a
else if qn = b2t_qn then begin
if term_eq a (`false) then False_
else if term_eq a (`true) then True_
else App h0 (fst t)
end
else App h0 (fst t)
| _ ->
App h0 (fst t)
end
| Tv_Const (C_Int i) ->
IntLit i
(* Not formulas. *)
| Tv_Let _ _ _ _ _
| Tv_Match _ _ _
| Tv_Type _
| Tv_Abs _ _
| Tv_Arrow _ _
| Tv_Uvar _ _
| Tv_Unknown
| Tv_Unsupp
| Tv_Refine _ _ -> F_Unknown
(* Other constants? *)
| Tv_Const _ -> F_Unknown
(* Should not occur, we're using inspect *)
| Tv_BVar _ -> F_Unknown
| _ -> raise (TacticFailure "???")
// Unsquashing
let term_as_formula (t:term) : Tac formula =
match unsquash_term t with
| None -> F_Unknown
| Some t ->
term_as_formula' t
// Badly named, this only means it always returns a formula even if not properly
// squashed at the top-level.
let term_as_formula_total (t:term) : Tac formula =
term_as_formula' (maybe_unsquash_term t)
let formula_as_term_view (f:formula) : Tot term_view =
let mk_app' tv args = List.Tot.Base.fold_left (fun tv a -> Tv_App (pack tv) a) tv args in
let e = Q_Explicit in
let i = Q_Implicit in
match f with
| True_ -> Tv_FVar (pack_fv true_qn)
| False_ -> Tv_FVar (pack_fv false_qn)
| Comp (Eq None) l r -> mk_app' (Tv_FVar (pack_fv eq2_qn)) [(l,e);(r,e)]
| Comp (Eq (Some t)) l r -> mk_app' (Tv_FVar (pack_fv eq2_qn)) [(t,i);(l,e);(r,e)]
| Comp (BoolEq None) l r -> mk_app' (Tv_FVar (pack_fv eq1_qn)) [(l,e);(r,e)]
| Comp (BoolEq (Some t)) l r -> mk_app' (Tv_FVar (pack_fv eq1_qn)) [(t,i);(l,e);(r,e)]
| Comp Lt l r -> mk_app' (Tv_FVar (pack_fv lt_qn)) [(l,e);(r,e)]
| Comp Le l r -> mk_app' (Tv_FVar (pack_fv lte_qn)) [(l,e);(r,e)]
| Comp Gt l r -> mk_app' (Tv_FVar (pack_fv gt_qn)) [(l,e);(r,e)]
| Comp Ge l r -> mk_app' (Tv_FVar (pack_fv gte_qn)) [(l,e);(r,e)]
| And p q -> mk_app' (Tv_FVar (pack_fv and_qn)) [(p,e);(q,e)]
| Or p q -> mk_app' (Tv_FVar (pack_fv or_qn)) [(p,e);(q,e)]
| Implies p q -> mk_app' (Tv_FVar (pack_fv imp_qn)) [(p,e);(q,e)]
| Not p -> mk_app' (Tv_FVar (pack_fv not_qn)) [(p,e)]
| Iff p q -> mk_app' (Tv_FVar (pack_fv iff_qn)) [(p,e);(q,e)]
| Forall b sort t -> Tv_Unknown // TODO: decide on meaning of this
| Exists b sort t -> Tv_Unknown // TODO: ^
| App p q ->
Tv_App p (q, Q_Explicit)
| Name b ->
Tv_Var b
| FV fv ->
Tv_FVar fv
| IntLit i ->
Tv_Const (C_Int i)
| F_Unknown ->
Tv_Unknown
let formula_as_term (f:formula) : Tot term =
pack (formula_as_term_view f) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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 | namedv: FStar.Tactics.NamedView.namedv -> FStar.Tactics.Effect.Tac Prims.string | FStar.Tactics.Effect.Tac | [] | [] | [
"FStar.Tactics.NamedView.namedv",
"FStar.Tactics.Unseal.unseal",
"Prims.string",
"FStar.Stubs.Reflection.V2.Data.__proj__Mknamedv_view__item__ppname",
"FStar.Tactics.NamedView.inspect_namedv"
] | [] | false | true | false | false | false | let namedv_to_string (namedv: namedv) : Tac string =
| let namedvv = inspect_namedv namedv in
unseal namedvv.ppname | false |
FStar.Reflection.V2.Formula.fst | FStar.Reflection.V2.Formula.formula_as_term | val formula_as_term (f: formula) : Tot term | val formula_as_term (f: formula) : Tot term | let formula_as_term (f:formula) : Tot term =
pack (formula_as_term_view f) | {
"file_name": "ulib/FStar.Reflection.V2.Formula.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 33,
"end_line": 216,
"start_col": 0,
"start_line": 215
} | (*
Copyright 2008-2018 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 FStar.Reflection.V2.Formula
open FStar.List.Tot.Base
open FStar.Stubs.Reflection.Types
open FStar.Reflection.Const
open FStar.Stubs.Reflection.V2.Builtins
open FStar.Reflection.V2.Derived
open FStar.Stubs.Reflection.V2.Data
open FStar.Stubs.Tactics.Common
open FStar.Tactics.Effect
open FStar.Stubs.Tactics.V2.Builtins
open FStar.Tactics.NamedView
///// Helpers (we cannot use the ones in Tactics.V2.Derived, those are for named views /////
private let rec inspect_unascribe (t:term) : Tac term_view =
match inspect t with
| Tv_AscribedT t _ _ _
| Tv_AscribedC t _ _ _ ->
inspect_unascribe t
| tv -> tv
private let rec collect_app' (args : list argv) (t : term)
: Tac (term * list argv) (decreases t) =
match inspect_unascribe t with
| Tv_App l r ->
collect_app' (r::args) l
| _ -> (t, args)
private let collect_app = collect_app' []
/////
[@@plugin]
noeq type comparison =
| Eq of option typ (* Propositional equality (eq2), maybe annotated *)
| BoolEq of option typ (* Decidable, boolean equality (eq), maybe annotated *)
| Lt | Le | Gt | Ge (* Orderings, at type `int` (and subtypes) *)
[@@plugin]
noeq type formula =
| True_ : formula
| False_ : formula
| Comp : comparison -> term -> term -> formula
| And : term -> term -> formula
| Or : term -> term -> formula
| Not : term -> formula
| Implies: term -> term -> formula
| Iff : term -> term -> formula
| Forall : bv -> typ -> term -> formula
| Exists : bv -> typ -> term -> formula
| App : term -> term -> formula
| Name : namedv -> formula
| FV : fv -> formula
| IntLit : int -> formula
| F_Unknown : formula // Also a baked-in "None"
let mk_Forall (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Forall b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
let mk_Exists (typ : term) (pred : term) : Tot formula =
let b = pack_bv ({ ppname = as_ppname "x";
sort = seal typ;
index = 0; }) in
Exists b typ (pack (Tv_App pred (pack (Tv_BVar b), Q_Explicit)))
[@@plugin]
let term_as_formula' (t:term) : Tac formula =
match inspect_unascribe t with
| Tv_Var n ->
Name n
| Tv_FVar fv
| Tv_UInst fv _ ->
// Cannot use `when` clauses when verifying!
let qn = inspect_fv fv in
if qn = true_qn then True_
else if qn = false_qn then False_
else FV fv
// TODO: l_Forall
// ...or should we just try to drop all squashes?
// TODO: b2t at this point ?
| Tv_App h0 t -> begin
let (h, ts) = collect_app h0 in
let h = un_uinst h in
match inspect h, ts@[t] with
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit); (a3, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = eq2_qn then Comp (Eq (Some a1)) a2 a3
else if qn = eq1_qn then Comp (BoolEq (Some a1)) a2 a3
else if qn = lt_qn then Comp Lt a2 a3
else if qn = lte_qn then Comp Le a2 a3
else if qn = gt_qn then Comp Gt a2 a3
else if qn = gte_qn then Comp Ge a2 a3
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Explicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = imp_qn then Implies a1 a2
else if qn = and_qn then And a1 a2
else if qn = iff_qn then Iff a1 a2
else if qn = or_qn then Or a1 a2
// Non-annotated comparisons
else if qn = eq2_qn then Comp (Eq None) a1 a2
else if qn = eq1_qn then Comp (BoolEq None) a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a1, Q_Implicit); (a2, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = forall_qn then mk_Forall a1 a2
else if qn = exists_qn then mk_Exists a1 a2
else App h0 (fst t)
| Tv_FVar fv, [(a, Q_Explicit)] ->
let qn = inspect_fv fv in
if qn = not_qn then Not a
else if qn = b2t_qn then begin
if term_eq a (`false) then False_
else if term_eq a (`true) then True_
else App h0 (fst t)
end
else App h0 (fst t)
| _ ->
App h0 (fst t)
end
| Tv_Const (C_Int i) ->
IntLit i
(* Not formulas. *)
| Tv_Let _ _ _ _ _
| Tv_Match _ _ _
| Tv_Type _
| Tv_Abs _ _
| Tv_Arrow _ _
| Tv_Uvar _ _
| Tv_Unknown
| Tv_Unsupp
| Tv_Refine _ _ -> F_Unknown
(* Other constants? *)
| Tv_Const _ -> F_Unknown
(* Should not occur, we're using inspect *)
| Tv_BVar _ -> F_Unknown
| _ -> raise (TacticFailure "???")
// Unsquashing
let term_as_formula (t:term) : Tac formula =
match unsquash_term t with
| None -> F_Unknown
| Some t ->
term_as_formula' t
// Badly named, this only means it always returns a formula even if not properly
// squashed at the top-level.
let term_as_formula_total (t:term) : Tac formula =
term_as_formula' (maybe_unsquash_term t)
let formula_as_term_view (f:formula) : Tot term_view =
let mk_app' tv args = List.Tot.Base.fold_left (fun tv a -> Tv_App (pack tv) a) tv args in
let e = Q_Explicit in
let i = Q_Implicit in
match f with
| True_ -> Tv_FVar (pack_fv true_qn)
| False_ -> Tv_FVar (pack_fv false_qn)
| Comp (Eq None) l r -> mk_app' (Tv_FVar (pack_fv eq2_qn)) [(l,e);(r,e)]
| Comp (Eq (Some t)) l r -> mk_app' (Tv_FVar (pack_fv eq2_qn)) [(t,i);(l,e);(r,e)]
| Comp (BoolEq None) l r -> mk_app' (Tv_FVar (pack_fv eq1_qn)) [(l,e);(r,e)]
| Comp (BoolEq (Some t)) l r -> mk_app' (Tv_FVar (pack_fv eq1_qn)) [(t,i);(l,e);(r,e)]
| Comp Lt l r -> mk_app' (Tv_FVar (pack_fv lt_qn)) [(l,e);(r,e)]
| Comp Le l r -> mk_app' (Tv_FVar (pack_fv lte_qn)) [(l,e);(r,e)]
| Comp Gt l r -> mk_app' (Tv_FVar (pack_fv gt_qn)) [(l,e);(r,e)]
| Comp Ge l r -> mk_app' (Tv_FVar (pack_fv gte_qn)) [(l,e);(r,e)]
| And p q -> mk_app' (Tv_FVar (pack_fv and_qn)) [(p,e);(q,e)]
| Or p q -> mk_app' (Tv_FVar (pack_fv or_qn)) [(p,e);(q,e)]
| Implies p q -> mk_app' (Tv_FVar (pack_fv imp_qn)) [(p,e);(q,e)]
| Not p -> mk_app' (Tv_FVar (pack_fv not_qn)) [(p,e)]
| Iff p q -> mk_app' (Tv_FVar (pack_fv iff_qn)) [(p,e);(q,e)]
| Forall b sort t -> Tv_Unknown // TODO: decide on meaning of this
| Exists b sort t -> Tv_Unknown // TODO: ^
| App p q ->
Tv_App p (q, Q_Explicit)
| Name b ->
Tv_Var b
| FV fv ->
Tv_FVar fv
| IntLit i ->
Tv_Const (C_Int i)
| F_Unknown ->
Tv_Unknown | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Tactics.NamedView.fsti.checked",
"FStar.Tactics.Effect.fsti.checked",
"FStar.Stubs.Tactics.V2.Builtins.fsti.checked",
"FStar.Stubs.Tactics.Common.fsti.checked",
"FStar.Stubs.Reflection.V2.Data.fsti.checked",
"FStar.Stubs.Reflection.V2.Builtins.fsti.checked",
"FStar.Stubs.Reflection.Types.fsti.checked",
"FStar.Reflection.V2.Derived.fst.checked",
"FStar.Reflection.Const.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked",
"FStar.List.Tot.Base.fst.checked"
],
"interface_file": false,
"source_file": "FStar.Reflection.V2.Formula.fst"
} | [
{
"abbrev": false,
"full_module": "FStar.Tactics.NamedView",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Tactics.Effect",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Tactics.Common",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Data",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2.Derived",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.V2.Builtins",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.Const",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Stubs.Reflection.Types",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.List.Tot.Base",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.V2",
"short_module": null
},
{
"abbrev": false,
"full_module": "FStar.Reflection.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: FStar.Reflection.V2.Formula.formula -> FStar.Tactics.NamedView.term | Prims.Tot | [
"total"
] | [] | [
"FStar.Reflection.V2.Formula.formula",
"FStar.Tactics.NamedView.pack",
"FStar.Reflection.V2.Formula.formula_as_term_view",
"FStar.Tactics.NamedView.term"
] | [] | false | false | false | true | false | let formula_as_term (f: formula) : Tot term =
| pack (formula_as_term_view f) | false |
GC.fst | GC.upd_map2 | val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c | val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c | let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 75,
"end_line": 111,
"start_col": 0,
"start_line": 111
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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: (_: a -> _: b -> c) -> i: a -> f: b -> v: c -> j: a -> g: b -> c | Prims.Tot | [
"total"
] | [] | [
"Prims.eqtype",
"Prims.op_Equality",
"FStar.Pervasives.Native.tuple2",
"FStar.Pervasives.Native.Mktuple2",
"Prims.bool"
] | [] | false | false | false | false | false | let upd_map2 #a #b #c m i f v =
| fun j g -> if (i, f) = (j, g) then v else m j g | false |
GC.fst | GC.initialize | val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g')) | val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g')) | let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 17,
"end_line": 128,
"start_col": 0,
"start_line": 116
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 -> GC.GC Prims.unit | GC.GC | [] | [] | [
"Prims.unit",
"GC.mem_lo",
"GC.mem_addr",
"GC.init_invariant",
"GC.gc_state",
"GC.mutator_inv",
"Prims.op_LessThan",
"Prims.op_Addition",
"GC.mem_hi",
"Prims.bool",
"GC.set",
"GC.Mkgc_state",
"GC.upd_map",
"GC.abs_node",
"GC.__proj__Mkgc_state__item__to_abs",
"GC.no_abs",
"GC.color",
"GC.__proj__Mkgc_state__item__color",
"GC.Unalloc",
"GC.__proj__Mkgc_state__item__abs_fields",
"GC.__proj__Mkgc_state__item__fields",
"GC.get"
] | [] | false | true | false | false | false | let initialize () =
| let rec aux_init: ptr: mem_addr
-> GC unit (requires (init_invariant ptr)) (ensures (fun gc _ gc' -> mutator_inv gc')) =
fun ptr ->
let gc = get () in
let gc' =
{ gc with color = upd_map gc.color ptr Unalloc; to_abs = upd_map gc.to_abs ptr no_abs }
in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1)
in
aux_init mem_lo | false |
GC.fst | GC.write_field | val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color)) | val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color)) | let write_field ptr f v =
cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' = {gc with
fields=upd_map gc.fields (ptr, f) v;
abs_fields=upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v);
} in
set gc' | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 9,
"end_line": 149,
"start_col": 0,
"start_line": 142
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f))))
let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f)
val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | ptr: GC.mem_addr -> f: GC.field -> v: GC.mem_addr -> GC.GCMut Prims.unit | GC.GCMut | [] | [] | [
"GC.mem_addr",
"GC.field",
"GC.set",
"Prims.unit",
"GC.gc_state",
"GC.Mkgc_state",
"GC.__proj__Mkgc_state__item__to_abs",
"GC.__proj__Mkgc_state__item__color",
"GC.upd_map",
"FStar.Pervasives.Native.tuple2",
"GC.abs_node",
"GC.__proj__Mkgc_state__item__abs_fields",
"FStar.Pervasives.Native.Mktuple2",
"GC.__proj__Mkgc_state__item__fields",
"GC.get",
"Prims.cut",
"Prims.l_and",
"GC.trigger"
] | [] | false | true | false | false | false | let write_field ptr f v =
| cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' =
{
gc with
fields = upd_map gc.fields (ptr, f) v;
abs_fields = upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v)
}
in
set gc' | false |
GC.fst | GC.test2 | val test2 : old: GC.gc_state -> Prims.unit | let test2 old = assert (gc_inv old /\ (forall i. old.color i <> Gray) ==> sweep_aux_inv old mem_lo old) | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 103,
"end_line": 194,
"start_col": 0,
"start_line": 194
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f))))
let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f)
val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color))
let write_field ptr f v =
cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' = {gc with
fields=upd_map gc.fields (ptr, f) v;
abs_fields=upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v);
} in
set gc'
val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White
/\ (exists c. gc' == {gc with color=c})))
let rec mark ptr =
let st = get () in
if st.color ptr = White
then begin
let st' = {st with color=upd_map st.color ptr Gray} in
set st';
mark (st'.fields (ptr, F1));
mark (st'.fields (ptr, F2));
let st'' = get () in
set ({st'' with color = upd_map st''.color ptr Black})
end
type sweep_aux_inv (old:gc_state) (ptr:int) (st:gc_state) =
gc_inv old
/\ (st.fields == old.fields /\ st.abs_fields == old.abs_fields)
/\ to_abs_inj st.to_abs
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i
==> st.color i <> Gray
/\ (old.color i = Black
==> (ptr_lifts st i
/\ obj_inv st i
/\ (forall f. st.fields (i, f) >= ptr ==> st.color (st.fields (i, f)) <> White)))
/\ (~(ptr_lifts st i) <==> st.color i=Unalloc)
/\ (ptr_lifts st i ==> old.to_abs i = st.to_abs i)
/\ (ptr <= i ==> old.color i = st.color i)
/\ (i < ptr ==> (st.color i = Unalloc \/ st.color i = White))
/\ (i < ptr /\ st.color i = White ==> old.color i = Black)
)
let test1 old n = assert (sweep_aux_inv old mem_hi n
==> mutator_inv n) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | old: GC.gc_state -> Prims.unit | Prims.Tot | [
"total"
] | [] | [
"GC.gc_state",
"Prims._assert",
"Prims.l_imp",
"Prims.l_and",
"GC.gc_inv",
"Prims.l_Forall",
"GC.mem_addr",
"Prims.b2t",
"Prims.op_disEquality",
"GC.color",
"GC.__proj__Mkgc_state__item__color",
"GC.Gray",
"GC.sweep_aux_inv",
"GC.mem_lo",
"Prims.unit"
] | [] | false | false | false | true | false | let test2 old =
| assert (gc_inv old /\ (forall i. old.color i <> Gray) ==> sweep_aux_inv old mem_lo old) | false |
|
GC.fst | GC.read_field | val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f)))) | val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f)))) | let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f) | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 20,
"end_line": 137,
"start_col": 0,
"start_line": 134
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc' | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | ptr: GC.mem_addr -> f: GC.field -> GC.GCMut GC.mem_addr | GC.GCMut | [] | [] | [
"GC.mem_addr",
"GC.field",
"GC.__proj__Mkgc_state__item__fields",
"FStar.Pervasives.Native.Mktuple2",
"GC.gc_state",
"GC.get",
"Prims.unit",
"Prims.cut",
"GC.trigger"
] | [] | false | true | false | false | false | let read_field ptr f =
| cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f) | false |
GC.fst | GC.test1 | val test1 : old: GC.gc_state -> n: GC.gc_state -> Prims.unit | let test1 old n = assert (sweep_aux_inv old mem_hi n
==> mutator_inv n) | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 45,
"end_line": 192,
"start_col": 0,
"start_line": 191
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f))))
let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f)
val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color))
let write_field ptr f v =
cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' = {gc with
fields=upd_map gc.fields (ptr, f) v;
abs_fields=upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v);
} in
set gc'
val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White
/\ (exists c. gc' == {gc with color=c})))
let rec mark ptr =
let st = get () in
if st.color ptr = White
then begin
let st' = {st with color=upd_map st.color ptr Gray} in
set st';
mark (st'.fields (ptr, F1));
mark (st'.fields (ptr, F2));
let st'' = get () in
set ({st'' with color = upd_map st''.color ptr Black})
end
type sweep_aux_inv (old:gc_state) (ptr:int) (st:gc_state) =
gc_inv old
/\ (st.fields == old.fields /\ st.abs_fields == old.abs_fields)
/\ to_abs_inj st.to_abs
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i
==> st.color i <> Gray
/\ (old.color i = Black
==> (ptr_lifts st i
/\ obj_inv st i
/\ (forall f. st.fields (i, f) >= ptr ==> st.color (st.fields (i, f)) <> White)))
/\ (~(ptr_lifts st i) <==> st.color i=Unalloc)
/\ (ptr_lifts st i ==> old.to_abs i = st.to_abs i)
/\ (ptr <= i ==> old.color i = st.color i)
/\ (i < ptr ==> (st.color i = Unalloc \/ st.color i = White))
/\ (i < ptr /\ st.color i = White ==> old.color i = Black)
) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | old: GC.gc_state -> n: GC.gc_state -> Prims.unit | Prims.Tot | [
"total"
] | [] | [
"GC.gc_state",
"Prims._assert",
"Prims.l_imp",
"GC.sweep_aux_inv",
"GC.mem_hi",
"GC.mutator_inv",
"Prims.unit"
] | [] | false | false | false | true | false | let test1 old n =
| assert (sweep_aux_inv old mem_hi n ==> mutator_inv n) | false |
|
GC.fst | GC.gc | val gc: root:mem_addr -> GCMut unit
(requires (fun gc -> root<>0 ==> ptr_lifts gc root))
(ensures (fun gc _ gc' -> (exists c a. gc' == {gc with color=c; to_abs=a})
/\ (root<>0 ==> ptr_lifts gc' root)
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i ==> (ptr_lifts gc' i ==> gc.to_abs i = gc'.to_abs i))
/\ (root <> 0 ==> gc.to_abs root = gc'.to_abs root))) | val gc: root:mem_addr -> GCMut unit
(requires (fun gc -> root<>0 ==> ptr_lifts gc root))
(ensures (fun gc _ gc' -> (exists c a. gc' == {gc with color=c; to_abs=a})
/\ (root<>0 ==> ptr_lifts gc' root)
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i ==> (ptr_lifts gc' i ==> gc.to_abs i = gc'.to_abs i))
/\ (root <> 0 ==> gc.to_abs root = gc'.to_abs root))) | let gc root =
cut (trigger root);
if (root <> 0)
then mark root;
sweep () | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 10,
"end_line": 247,
"start_col": 0,
"start_line": 243
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f))))
let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f)
val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color))
let write_field ptr f v =
cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' = {gc with
fields=upd_map gc.fields (ptr, f) v;
abs_fields=upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v);
} in
set gc'
val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White
/\ (exists c. gc' == {gc with color=c})))
let rec mark ptr =
let st = get () in
if st.color ptr = White
then begin
let st' = {st with color=upd_map st.color ptr Gray} in
set st';
mark (st'.fields (ptr, F1));
mark (st'.fields (ptr, F2));
let st'' = get () in
set ({st'' with color = upd_map st''.color ptr Black})
end
type sweep_aux_inv (old:gc_state) (ptr:int) (st:gc_state) =
gc_inv old
/\ (st.fields == old.fields /\ st.abs_fields == old.abs_fields)
/\ to_abs_inj st.to_abs
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i
==> st.color i <> Gray
/\ (old.color i = Black
==> (ptr_lifts st i
/\ obj_inv st i
/\ (forall f. st.fields (i, f) >= ptr ==> st.color (st.fields (i, f)) <> White)))
/\ (~(ptr_lifts st i) <==> st.color i=Unalloc)
/\ (ptr_lifts st i ==> old.to_abs i = st.to_abs i)
/\ (ptr <= i ==> old.color i = st.color i)
/\ (i < ptr ==> (st.color i = Unalloc \/ st.color i = White))
/\ (i < ptr /\ st.color i = White ==> old.color i = Black)
)
let test1 old n = assert (sweep_aux_inv old mem_hi n
==> mutator_inv n)
let test2 old = assert (gc_inv old /\ (forall i. old.color i <> Gray) ==> sweep_aux_inv old mem_lo old)
val sweep: unit -> GC unit
(requires (fun gc -> gc_inv gc
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i
==> gc.color i <> Gray)))
(ensures (fun gc _ gc' -> (exists c a. gc' == {gc with color=c; to_abs=a}
/\ mutator_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i
==> (gc.color i=Black ==> ptr_lifts gc' i)
/\ (ptr_lifts gc' i ==> gc.to_abs i = gc'.to_abs i)))))
let sweep () =
let old = get () in
let rec sweep_aux : ptr:mem_addr -> GC unit
(requires (fun gc -> sweep_aux_inv old ptr gc))
(ensures (fun _ _ st ->
(st.abs_fields == old.abs_fields
/\ st.fields == old.fields
/\ mutator_inv st
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i
==> (old.color i=Black ==> ptr_lifts st i)
/\ (ptr_lifts st i ==> old.to_abs i = st.to_abs i)))))
= fun ptr ->
cut (trigger ptr);
let st = get () in
if st.color ptr = White //deallocate
then (let st' = {st with
color=upd_map st.color ptr Unalloc;
to_abs=upd_map st.to_abs ptr no_abs} in
set st')
else if st.color ptr = Black
then
begin let st' = {st with color=upd_map st.color ptr White} in
set st'
end;
if ptr + 1 < mem_hi
then sweep_aux (ptr + 1) in
sweep_aux mem_lo
val gc: root:mem_addr -> GCMut unit
(requires (fun gc -> root<>0 ==> ptr_lifts gc root))
(ensures (fun gc _ gc' -> (exists c a. gc' == {gc with color=c; to_abs=a})
/\ (root<>0 ==> ptr_lifts gc' root)
/\ (forall (i:mem_addr). {:pattern (trigger i)}
trigger i ==> (ptr_lifts gc' i ==> gc.to_abs i = gc'.to_abs i)) | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | root: GC.mem_addr -> GC.GCMut Prims.unit | GC.GCMut | [] | [] | [
"GC.mem_addr",
"GC.sweep",
"Prims.unit",
"Prims.op_disEquality",
"Prims.int",
"GC.mark",
"Prims.bool",
"Prims.cut",
"GC.trigger"
] | [] | false | true | false | false | false | let gc root =
| cut (trigger root);
if (root <> 0) then mark root;
sweep () | false |
GC.fst | GC.mark | val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White
/\ (exists c. gc' == {gc with color=c}))) | val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White
/\ (exists c. gc' == {gc with color=c}))) | let rec mark ptr =
let st = get () in
if st.color ptr = White
then begin
let st' = {st with color=upd_map st.color ptr Gray} in
set st';
mark (st'.fields (ptr, F1));
mark (st'.fields (ptr, F2));
let st'' = get () in
set ({st'' with color = upd_map st''.color ptr Black})
end | {
"file_name": "examples/algorithms/GC.fst",
"git_rev": "10183ea187da8e8c426b799df6c825e24c0767d3",
"git_url": "https://github.com/FStarLang/FStar.git",
"project_name": "FStar"
} | {
"end_col": 5,
"end_line": 170,
"start_col": 0,
"start_line": 160
} | (* Copyright Microsoft Research 2015
This module is an adaptation of Chris Hawblitzel and Erez Petrank's
simplified mark-sweep collector from the POPL 2009 paper
"Automated Verification of Practical Garbage Collectors"
While this module states and proves the same properties as the paper,
its implementation is currently still quite high-level, e.g, it
uses lots of recursive functions instead of while loops with mutable
local variables. Going lower level with this module is work in progress.
*)
module GC
type color =
| Unalloc
| White
| Gray
| Black
assume val mem_lo : x:int{0 < x}
assume val mem_hi : x:int{mem_lo < x}
let is_mem_addr i = mem_lo <= i && i < mem_hi
type field =
| F1
| F2
assume type abs_node : a:Type0{hasEq a}
assume val no_abs : abs_node
let valid a = a <> no_abs
type valid_node = a:abs_node{valid a}
type mem_addr = i:int{is_mem_addr i}
type color_map = mem_addr -> Tot color
type abs_map = mem_addr -> Tot abs_node
type field_map = mem_addr * field -> Tot mem_addr
type abs_field_map = abs_node * field -> Tot abs_node
type trigger (i:int) = True
type to_abs_inj (to_abs:abs_map) =
forall (i1:mem_addr) (i2:mem_addr).{:pattern (trigger i1); (trigger i2)}
trigger i1 /\
trigger i2 /\
valid (to_abs i1)
/\ valid (to_abs i2)
/\ i1 <> i2
==> to_abs i1 <> to_abs i2
noeq type gc_state = {
to_abs: abs_map;
color: color_map;
abs_fields: abs_field_map;
fields: field_map
}
type ptr_lifts gc_state (ptr:mem_addr) : Type =
b2t (valid (gc_state.to_abs ptr))
type ptr_lifts_to gc_state (ptr:mem_addr) (abs:abs_node) : Type =
valid abs
/\ gc_state.to_abs ptr = abs
type obj_inv gc_state (i:mem_addr) =
valid (gc_state.to_abs i)
==> (forall f. ptr_lifts_to gc_state (gc_state.fields (i, f)) (gc_state.abs_fields (gc_state.to_abs i, f)))
unfold type inv gc_state (color_invariant:mem_addr -> Type) =
to_abs_inj gc_state.to_abs
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
obj_inv gc_state i /\
color_invariant i /\
(not (valid (gc_state.to_abs i)) <==> gc_state.color i = Unalloc))
type gc_inv gc_state =
inv gc_state (fun i ->
(gc_state.color i = Black
==> (forall f. gc_state.color (gc_state.fields (i, f)) <> White)))
type mutator_inv gc_state =
inv gc_state (fun i -> gc_state.color i = Unalloc \/ gc_state.color i = White)
new_effect GC_STATE = STATE_h gc_state
let gc_post (a:Type) = a -> gc_state -> Type0
sub_effect
DIV ~> GC_STATE = fun (a:Type) (wp:pure_wp a) (p:gc_post a) (gc:gc_state) -> wp (fun a -> p a gc)
effect GC (a:Type) (pre:gc_state -> Type0) (post: gc_state -> Tot (gc_post a)) =
GC_STATE a
(fun (p:gc_post a) (gc:gc_state) ->
pre gc /\ (forall a gc'. (pre gc /\ post gc a gc') ==> p a gc')) (* WP *)
effect GCMut (res:Type) (req:gc_state -> Type0) (ens:gc_state -> Tot (gc_post res)) =
GC res (fun gc -> req gc /\ mutator_inv gc)
(fun gc res gc' -> ens gc res gc' /\ mutator_inv gc')
assume val get : unit -> GC gc_state (fun gc -> True) (fun gc res gc' -> gc==gc' /\ res==gc')
assume val set : g:gc_state -> GC unit (fun gc -> True) (fun _ _ gc' -> g==gc')
type init_invariant (ptr:mem_addr) (gc:gc_state) =
forall i. mem_lo <= i /\ i < ptr
==> not(valid (gc.to_abs i))
/\ gc.color i = Unalloc
val upd_map: #a:eqtype -> #b:Type -> (a -> Tot b) -> a -> b -> a -> Tot b
let upd_map #a #b f i v = fun j -> if i=j then v else f j
val upd_map2: #a:eqtype -> #b:eqtype -> #c:Type -> (a -> b -> Tot c) -> a -> b -> c -> a -> b -> Tot c
let upd_map2 #a #b #c m i f v = fun j g -> if (i,f)=(j,g) then v else m j g
val initialize: unit -> GC unit
(requires (fun g -> True))
(ensures (fun g _ g' -> mutator_inv g'))
let initialize () =
let rec aux_init : ptr:mem_addr -> GC unit
(requires (init_invariant ptr))
(ensures (fun gc _ gc' -> mutator_inv gc'))
= fun ptr ->
let gc = get () in
let gc' = {gc with
color=upd_map gc.color ptr Unalloc;
to_abs=upd_map gc.to_abs ptr no_abs
} in
set gc';
if ptr + 1 < mem_hi then aux_init (ptr + 1) in
aux_init mem_lo
val read_field : ptr:mem_addr -> f:field -> GCMut mem_addr
(requires (fun gc -> ptr_lifts_to gc ptr (gc.to_abs ptr)))
(ensures (fun gc i gc' -> gc==gc'
/\ ptr_lifts_to gc' i (gc.abs_fields (gc.to_abs ptr, f))))
let read_field ptr f =
cut (trigger ptr);
let gc = get () in
gc.fields (ptr, f)
val write_field: ptr:mem_addr -> f:field -> v:mem_addr -> GCMut unit
(requires (fun gc -> ptr_lifts gc ptr /\ ptr_lifts gc v))
(ensures (fun gc _ gc' -> gc'.color==gc.color))
let write_field ptr f v =
cut (trigger ptr /\ trigger v);
let gc = get () in
let gc' = {gc with
fields=upd_map gc.fields (ptr, f) v;
abs_fields=upd_map gc.abs_fields (gc.to_abs ptr, f) (gc.to_abs v);
} in
set gc'
val mark : ptr:mem_addr -> GC unit
(requires (fun gc -> gc_inv gc /\ trigger ptr /\ ptr_lifts gc ptr))
(ensures (fun gc _ gc' -> gc_inv gc'
/\ (forall (i:mem_addr).{:pattern (trigger i)}
trigger i ==>
(gc'.color i <> Black
==> gc.color i = gc'.color i))
/\ gc'.color ptr <> White | {
"checked_file": "/",
"dependencies": [
"prims.fst.checked",
"FStar.Pervasives.Native.fst.checked",
"FStar.Pervasives.fsti.checked"
],
"interface_file": false,
"source_file": "GC.fst"
} | [
{
"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 | ptr: GC.mem_addr -> GC.GC Prims.unit | GC.GC | [] | [] | [
"GC.mem_addr",
"Prims.op_Equality",
"GC.color",
"GC.__proj__Mkgc_state__item__color",
"GC.White",
"GC.set",
"GC.Mkgc_state",
"GC.__proj__Mkgc_state__item__to_abs",
"GC.upd_map",
"GC.Black",
"GC.__proj__Mkgc_state__item__abs_fields",
"GC.__proj__Mkgc_state__item__fields",
"Prims.unit",
"GC.gc_state",
"GC.get",
"GC.mark",
"FStar.Pervasives.Native.Mktuple2",
"GC.field",
"GC.F2",
"GC.F1",
"GC.Gray",
"Prims.bool"
] | [
"recursion"
] | false | true | false | false | false | let rec mark ptr =
| let st = get () in
if st.color ptr = White
then
let st' = { st with color = upd_map st.color ptr Gray } in
set st';
mark (st'.fields (ptr, F1));
mark (st'.fields (ptr, F2));
let st'' = get () in
set ({ st'' with color = upd_map st''.color ptr Black }) | false |
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