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guile-bootstrap / guile /module /ice-9 /psyntax.scm

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	;;;; --scheme--
	;;;;
	;;;; Copyright (C) 2001, 2003, 2006, 2009, 2010-2022
	;;;; Free Software Foundation, Inc.
	;;;;
	;;;; This library is free software; you can redistribute it and/or
	;;;; modify it under the terms of the GNU Lesser General Public
	;;;; License as published by the Free Software Foundation; either
	;;;; version 3 of the License, or (at your option) any later version.
	;;;;
	;;;; This library is distributed in the hope that it will be useful,
	;;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
	;;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	;;;; Lesser General Public License for more details.
	;;;;
	;;;; You should have received a copy of the GNU Lesser General Public
	;;;; License along with this library; if not, write to the Free Software
	;;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	;;;;


	;;; Portable implementation of syntax-case
	;;; Originally extracted from Chez Scheme Version 5.9f
	;;; Authors: R. Kent Dybvig, Oscar Waddell, Bob Hieb, Carl Bruggeman

	;;; Copyright (c) 1992-1997 Cadence Research Systems
	;;; Permission to copy this software, in whole or in part, to use this
	;;; software for any lawful purpose, and to redistribute this software
	;;; is granted subject to the restriction that all copies made of this
	;;; software must include this copyright notice in full. This software
	;;; is provided AS IS, with NO WARRANTY, EITHER EXPRESS OR IMPLIED,
	;;; INCLUDING BUT NOT LIMITED TO IMPLIED WARRANTIES OF MERCHANTABILITY
	;;; OR FITNESS FOR ANY PARTICULAR PURPOSE. IN NO EVENT SHALL THE
	;;; AUTHORS BE LIABLE FOR CONSEQUENTIAL OR INCIDENTAL DAMAGES OF ANY
	;;; NATURE WHATSOEVER.

	;;; Modified by Mikael Djurfeldt <[email protected]> according
	;;; to the ChangeLog distributed in the same directory as this file:
	;;; 1997-08-19, 1997-09-03, 1997-09-10, 2000-08-13, 2000-08-24,
	;;; 2000-09-12, 2001-03-08

	;;; Modified by Andy Wingo <[email protected]> according to the Git
	;;; revision control logs corresponding to this file: 2009, 2010.

	;;; Modified by Mark H Weaver <[email protected]> according to the Git
	;;; revision control logs corresponding to this file: 2012, 2013.


	;;; This code is based on "Syntax Abstraction in Scheme"
	;;; by R. Kent Dybvig, Robert Hieb, and Carl Bruggeman.
	;;; Lisp and Symbolic Computation 5:4, 295-326, 1992.
	;;; <http://www.cs.indiana.edu/~dyb/pubs/LaSC-5-4-pp295-326.pdf>


	;;; This file defines the syntax-case expander, macroexpand, and a set
	;;; of associated syntactic forms and procedures. Of these, the
	;;; following are documented in The Scheme Programming Language,
	;;; Fourth Edition (R. Kent Dybvig, MIT Press, 2009), and in the
	;;; R6RS:
	;;;
	;;; bound-identifier=?
	;;; datum->syntax
	;;; define-syntax
	;;; syntax-parameterize
	;;; free-identifier=?
	;;; generate-temporaries
	;;; identifier?
	;;; identifier-syntax
	;;; let-syntax
	;;; letrec-syntax
	;;; syntax
	;;; syntax-case
	;;; syntax->datum
	;;; syntax-rules
	;;; with-syntax
	;;;
	;;; Additionally, the expander provides definitions for a number of core
	;;; Scheme syntactic bindings, such as `let', `lambda', and the like.

	;;; The remaining exports are listed below:
	;;;
	;;; (macroexpand datum)
	;;; if datum represents a valid expression, macroexpand returns an
	;;; expanded version of datum in a core language that includes no
	;;; syntactic abstractions. The core language includes begin,
	;;; define, if, lambda, letrec, quote, and set!.
	;;; (eval-when situations expr ...)
	;;; conditionally evaluates expr ... at compile-time or run-time
	;;; depending upon situations (see the Chez Scheme System Manual,
	;;; Revision 3, for a complete description)
	;;; (syntax-violation who message form [subform])
	;;; used to report errors found during expansion
	;;; ($sc-dispatch e p)
	;;; used by expanded code to handle syntax-case matching

	;;; This file is shipped along with an expanded version of itself,
	;;; psyntax-pp.scm, which is loaded when psyntax.scm has not yet been
	;;; compiled. In this way, psyntax bootstraps off of an expanded
	;;; version of itself.


	;;; Implementation notes:

	;;; Objects with no standard print syntax, including objects containing
	;;; cycles and syntax object, are allowed in quoted data as long as they
	;;; are contained within a syntax form or produced by datum->syntax.
	;;; Such objects are never copied.

	;;; All identifiers that don't have macro definitions and are not bound
	;;; lexically are assumed to be global variables.

	;;; Top-level definitions of macro-introduced identifiers are allowed.
	;;; This may not be appropriate for implementations in which the
	;;; model is that bindings are created by definitions, as opposed to
	;;; one in which initial values are assigned by definitions.

	;;; Identifiers and syntax objects are implemented as vectors for
	;;; portability. As a result, it is possible to "forge" syntax objects.

	;;; The implementation of generate-temporaries assumes that it is
	;;; possible to generate globally unique symbols (gensyms).

	;;; The source location associated with incoming expressions is tracked
	;;; via the source-properties mechanism, a weak map from expression to
	;;; source information. At times the source is separated from the
	;;; expression; see the note below about "efficiency and confusion".


	;;; Bootstrapping:

	;;; When changing syntax representations, it is necessary to support
	;;; both old and new syntax representations in id-var-name. It
	;;; should be sufficient to recognize old representations and treat
	;;; them as not lexically bound.



	(eval-when (compile)
	(set-current-module (resolve-module '(guile))))

	(let ((syntax? (module-ref (current-module) 'syntax?))
	(make-syntax (module-ref (current-module) 'make-syntax))
	(syntax-expression (module-ref (current-module) 'syntax-expression))
	(syntax-wrap (module-ref (current-module) 'syntax-wrap))
	(syntax-module (module-ref (current-module) 'syntax-module))
	(syntax-sourcev (module-ref (current-module) 'syntax-sourcev)))

	(define-syntax define-expansion-constructors
	(lambda (x)
	(syntax-case x ()
	((_)
	(let lp ((n 0) (out '()))
	(if (< n (vector-length %expanded-vtables))
	(lp (1+ n)
	(let* ((vtable (vector-ref %expanded-vtables n))
	(stem (struct-ref vtable (+ vtable-offset-user 0)))
	(fields (struct-ref vtable (+ vtable-offset-user 2)))
	(sfields (map (lambda (f) (datum->syntax x f)) fields))
	(ctor (datum->syntax x (symbol-append 'make- stem))))
	(cons #`(define (#,ctor #,@sfields)
	(make-struct/simple
	(vector-ref %expanded-vtables #,n)
	#,@sfields))
	out)))
	#`(begin #,@(reverse out))))))))

	(define-syntax define-expansion-accessors
	(lambda (x)
	(syntax-case x ()
	((_ stem field ...)
	(let lp ((n 0))
	(let ((vtable (vector-ref %expanded-vtables n))
	(stem (syntax->datum #'stem)))
	(if (eq? (struct-ref vtable (+ vtable-offset-user 0)) stem)
	#`(begin
	(define (#,(datum->syntax x (symbol-append stem '?)) x)
	(and (struct? x)
	(eq? (struct-vtable x)
	(vector-ref %expanded-vtables #,n))))
	#,@(map
	(lambda (f)
	(let ((get (datum->syntax x (symbol-append stem '- f)))
	(set (datum->syntax x (symbol-append 'set- stem '- f '!)))
	(idx (list-index (struct-ref vtable
	(+ vtable-offset-user 2))
	f)))
	#`(begin
	(define (#,get x)
	(struct-ref x #,idx))
	(define (#,set x v)
	(struct-set! x #,idx v)))))
	(syntax->datum #'(field ...))))
	(lp (1+ n)))))))))

	(define-syntax define-structure
	(lambda (x)
	(define construct-name
	(lambda (template-identifier . args)
	(datum->syntax
	template-identifier
	(string->symbol
	(apply string-append
	(map (lambda (x)
	(if (string? x)
	x
	(symbol->string (syntax->datum x))))
	args))))))
	(syntax-case x ()
	((_ (name id1 ...))
	(and-map identifier? #'(name id1 ...))
	(with-syntax
	((constructor (construct-name #'name "make-" #'name))
	(predicate (construct-name #'name #'name "?"))
	((access ...)
	(map (lambda (x) (construct-name x #'name "-" x))
	#'(id1 ...)))
	((assign ...)
	(map (lambda (x)
	(construct-name x "set-" #'name "-" x "!"))
	#'(id1 ...)))
	(structure-length
	(+ (length #'(id1 ...)) 1))
	((index ...)
	(let f ((i 1) (ids #'(id1 ...)))
	(if (null? ids)
	'()
	(cons i (f (+ i 1) (cdr ids)))))))
	#'(begin
	(define constructor
	(lambda (id1 ...)
	(vector 'name id1 ... )))
	(define predicate
	(lambda (x)
	(and (vector? x)
	(= (vector-length x) structure-length)
	(eq? (vector-ref x 0) 'name))))
	(define access
	(lambda (x)
	(vector-ref x index)))
	...
	(define assign
	(lambda (x update)
	(vector-set! x index update)))
	...))))))

	(let ()
	(define-expansion-constructors)
	(define-expansion-accessors lambda meta)

	;; hooks to nonportable run-time helpers
	(begin
	(define-syntax fx+ (identifier-syntax +))
	(define-syntax fx- (identifier-syntax -))
	(define-syntax fx= (identifier-syntax =))
	(define-syntax fx< (identifier-syntax <))

	(define top-level-eval-hook
	(lambda (x mod)
	(primitive-eval x)))

	(define local-eval-hook
	(lambda (x mod)
	(primitive-eval x)))

	;; Capture syntax-session-id before we shove it off into a module.
	(define session-id
	(let ((v (module-variable (current-module) 'syntax-session-id)))
	(lambda ()
	((variable-ref v))))))

	(define (sourcev-filename s) (vector-ref s 0))
	(define (sourcev-line s) (vector-ref s 1))
	(define (sourcev-column s) (vector-ref s 2))
	(define (sourcev->alist sourcev)
	(define (maybe-acons k v tail) (if v (acons k v tail) tail))
	(and sourcev
	(maybe-acons 'filename (sourcev-filename sourcev)
	`((line . ,(sourcev-line sourcev))
	(column . ,(sourcev-column sourcev))))))

	(define (maybe-name-value! name val)
	(if (lambda? val)
	(let ((meta (lambda-meta val)))
	(if (not (assq 'name meta))
	(set-lambda-meta! val (acons 'name name meta))))))

	;; output constructors
	(define build-void
	(lambda (sourcev)
	(make-void sourcev)))

	(define build-call
	(lambda (sourcev fun-exp arg-exps)
	(make-call sourcev fun-exp arg-exps)))

	(define build-conditional
	(lambda (sourcev test-exp then-exp else-exp)
	(make-conditional sourcev test-exp then-exp else-exp)))

	(define build-lexical-reference
	(lambda (type sourcev name var)
	(make-lexical-ref sourcev name var)))

	(define build-lexical-assignment
	(lambda (sourcev name var exp)
	(maybe-name-value! name exp)
	(make-lexical-set sourcev name var exp)))

	(define (analyze-variable mod var modref-cont bare-cont)
	(if (not mod)
	(bare-cont #f var)
	(let ((kind (car mod))
	(mod (cdr mod)))
	(case kind
	((public) (modref-cont mod var #t))
	((private hygiene) (if (equal? mod (module-name (current-module)))
	(bare-cont mod var)
	(modref-cont mod var #f)))
	((bare) (bare-cont var))
	((primitive)
	(syntax-violation #f "primitive not in operator position" var))
	(else (syntax-violation #f "bad module kind" var mod))))))

	(define build-global-reference
	(lambda (sourcev var mod)
	(analyze-variable
	mod var
	(lambda (mod var public?)
	(make-module-ref sourcev mod var public?))
	(lambda (mod var)
	(make-toplevel-ref sourcev mod var)))))

	(define build-global-assignment
	(lambda (sourcev var exp mod)
	(maybe-name-value! var exp)
	(analyze-variable
	mod var
	(lambda (mod var public?)
	(make-module-set sourcev mod var public? exp))
	(lambda (mod var)
	(make-toplevel-set sourcev mod var exp)))))

	(define build-global-definition
	(lambda (sourcev mod var exp)
	(maybe-name-value! var exp)
	(make-toplevel-define sourcev (and mod (cdr mod)) var exp)))

	(define build-simple-lambda
	(lambda (src req rest vars meta exp)
	(make-lambda src
	meta
	;; hah, a case in which kwargs would be nice.
	(make-lambda-case
	;; src req opt rest kw inits vars body else
	src req #f rest #f '() vars exp #f))))

	(define build-case-lambda
	(lambda (src meta body)
	(make-lambda src meta body)))

	(define build-lambda-case
	;; req := (name ...)
	;; opt := (name ...) \| #f
	;; rest := name \| #f
	;; kw := (allow-other-keys? (keyword name var) ...) \| #f
	;; inits: (init ...)
	;; vars: (sym ...)
	;; vars map to named arguments in the following order:
	;; required, optional (positional), rest, keyword.
	;; the body of a lambda: anything, already expanded
	;; else: lambda-case \| #f
	(lambda (src req opt rest kw inits vars body else-case)
	(make-lambda-case src req opt rest kw inits vars body else-case)))

	(define build-primcall
	(lambda (src name args)
	(make-primcall src name args)))

	(define build-primref
	(lambda (src name)
	(make-primitive-ref src name)))

	(define (build-data src exp)
	(make-const src exp))

	(define build-sequence
	(lambda (src exps)
	(if (null? (cdr exps))
	(car exps)
	(make-seq src (car exps) (build-sequence #f (cdr exps))))))

	(define build-let
	(lambda (src ids vars val-exps body-exp)
	(for-each maybe-name-value! ids val-exps)
	(if (null? vars)
	body-exp
	(make-let src ids vars val-exps body-exp))))

	(define build-named-let
	(lambda (src ids vars val-exps body-exp)
	(let ((f (car vars))
	(f-name (car ids))
	(vars (cdr vars))
	(ids (cdr ids)))
	(let ((proc (build-simple-lambda src ids #f vars '() body-exp)))
	(maybe-name-value! f-name proc)
	(for-each maybe-name-value! ids val-exps)
	(make-letrec
	src #f
	(list f-name) (list f) (list proc)
	(build-call src (build-lexical-reference 'fun src f-name f)
	val-exps))))))

	(define build-letrec
	(lambda (src in-order? ids vars val-exps body-exp)
	(if (null? vars)
	body-exp
	(begin
	(for-each maybe-name-value! ids val-exps)
	(make-letrec src in-order? ids vars val-exps body-exp)))))


	(define-syntax-rule (build-lexical-var src id)
	;; Use a per-module counter instead of the global counter of
	;; 'gensym' so that the generated identifier is reproducible.
	(module-gensym (symbol->string id)))

	(define-syntax no-source (identifier-syntax #f))

	(define (datum-sourcev datum)
	(let ((props (source-properties datum)))
	(and (pair? props)
	(vector (assq-ref props 'filename)
	(assq-ref props 'line)
	(assq-ref props 'column)))))

	(define source-annotation
	(lambda (x)
	;; Normally X is a syntax object. However, if it comes from a
	;; read hash extension, X might be a plain sexp with source
	;; properties.
	(if (syntax? x)
	(syntax-sourcev x)
	(datum-sourcev x))))

	(define-syntax-rule (arg-check pred? e who)
	(let ((x e))
	(if (not (pred? x)) (syntax-violation who "invalid argument" x))))

	;; compile-time environments

	;; wrap and environment comprise two level mapping.
	;; wrap : id --> label
	;; env : label --> <element>

	;; environments are represented in two parts: a lexical part and a
	;; global part. The lexical part is a simple list of associations
	;; from labels to bindings. The global part is implemented by
	;; Guile's module system and associates symbols with bindings.

	;; global (assumed global variable) and displaced-lexical (see below)
	;; do not show up in any environment; instead, they are fabricated by
	;; resolve-identifier when it finds no other bindings.

	;; <environment> ::= ((<label> . <binding>)*)

	;; identifier bindings include a type and a value

	;; <binding> ::= (macro . <procedure>) macros
	;; (syntax-parameter . <procedure>) syntax parameters
	;; (core . <procedure>) core forms
	;; (module-ref . <procedure>) @ or @@
	;; (begin) begin
	;; (define) define
	;; (define-syntax) define-syntax
	;; (define-syntax-parameter) define-syntax-parameter
	;; (local-syntax . rec?) let-syntax/letrec-syntax
	;; (eval-when) eval-when
	;; (syntax . (<var> . <level>)) pattern variables
	;; (global) assumed global variable
	;; (lexical . <var>) lexical variables
	;; (ellipsis . <identifier>) custom ellipsis
	;; (displaced-lexical) displaced lexicals
	;; <level> ::= <non-negative integer>
	;; <var> ::= variable returned by build-lexical-var

	;; a macro is a user-defined syntactic-form. a core is a
	;; system-defined syntactic form. begin, define, define-syntax,
	;; define-syntax-parameter, and eval-when are treated specially
	;; since they are sensitive to whether the form is at top-level and
	;; (except for eval-when) can denote valid internal definitions.

	;; a pattern variable is a variable introduced by syntax-case and can
	;; be referenced only within a syntax form.

	;; any identifier for which no top-level syntax definition or local
	;; binding of any kind has been seen is assumed to be a global
	;; variable.

	;; a lexical variable is a lambda- or letrec-bound variable.

	;; an ellipsis binding is introduced by the 'with-ellipsis' special
	;; form.

	;; a displaced-lexical identifier is a lexical identifier removed from
	;; it's scope by the return of a syntax object containing the identifier.
	;; a displaced lexical can also appear when a letrec-syntax-bound
	;; keyword is referenced on the rhs of one of the letrec-syntax clauses.
	;; a displaced lexical should never occur with properly written macros.

	(define-syntax make-binding
	(syntax-rules (quote)
	((_ type value) (cons type value))
	((_ 'type) '(type))
	((_ type) (cons type '()))))
	(define-syntax-rule (binding-type x)
	(car x))
	(define-syntax-rule (binding-value x)
	(cdr x))

	(define-syntax null-env (identifier-syntax '()))

	(define extend-env
	(lambda (labels bindings r)
	(if (null? labels)
	r
	(extend-env (cdr labels) (cdr bindings)
	(cons (cons (car labels) (car bindings)) r)))))

	(define extend-var-env
	;; variant of extend-env that forms "lexical" binding
	(lambda (labels vars r)
	(if (null? labels)
	r
	(extend-var-env (cdr labels) (cdr vars)
	(cons (cons (car labels) (make-binding 'lexical (car vars))) r)))))

	;; we use a "macros only" environment in expansion of local macro
	;; definitions so that their definitions can use local macros without
	;; attempting to use other lexical identifiers.
	(define macros-only-env
	(lambda (r)
	(if (null? r)
	'()
	(let ((a (car r)))
	(if (memq (cadr a) '(macro syntax-parameter ellipsis))
	(cons a (macros-only-env (cdr r)))
	(macros-only-env (cdr r)))))))

	(define global-extend
	(lambda (type sym val)
	(module-define! (current-module)
	sym
	(make-syntax-transformer sym type val))))


	;; Conceptually, identifiers are always syntax objects. Internally,
	;; however, the wrap is sometimes maintained separately (a source of
	;; efficiency and confusion), so that symbols are also considered
	;; identifiers by id?. Externally, they are always wrapped.

	(define nonsymbol-id?
	(lambda (x)
	(and (syntax? x)
	(symbol? (syntax-expression x)))))

	(define id?
	(lambda (x)
	(cond
	((symbol? x) #t)
	((syntax? x) (symbol? (syntax-expression x)))
	(else #f))))

	(define-syntax-rule (id-sym-name e)
	(let ((x e))
	(if (syntax? x)
	(syntax-expression x)
	x)))

	(define id-sym-name&marks
	(lambda (x w)
	(if (syntax? x)
	(values
	(syntax-expression x)
	(join-marks (wrap-marks w) (wrap-marks (syntax-wrap x))))
	(values x (wrap-marks w)))))

	;; syntax object wraps

	;; <wrap> ::= ((<mark> ...) . (<subst> ...))
	;; <subst> ::= shift \| <subs>
	;; <subs> ::= #(ribcage #(<sym> ...) #(<mark> ...) #(<label> ...))
	;; \| #(ribcage (<sym> ...) (<mark> ...) (<label> ...))

	(define-syntax make-wrap (identifier-syntax cons))
	(define-syntax wrap-marks (identifier-syntax car))
	(define-syntax wrap-subst (identifier-syntax cdr))

	;; labels must be comparable with "eq?", have read-write invariance,
	;; and distinct from symbols.
	(define (gen-label)
	(symbol->string (module-gensym "l")))

	(define gen-labels
	(lambda (ls)
	(if (null? ls)
	'()
	(cons (gen-label) (gen-labels (cdr ls))))))

	(define-structure (ribcage symnames marks labels))

	(define-syntax empty-wrap (identifier-syntax '(())))
	(define-syntax top-wrap (identifier-syntax '((top))))

	;; Marks must be comparable with "eq?" and distinct from pairs and
	;; the symbol top. We do not use integers so that marks will remain
	;; unique even across file compiles.

	(define-syntax the-anti-mark (identifier-syntax #f))

	(define anti-mark
	(lambda (w)
	(make-wrap (cons the-anti-mark (wrap-marks w))
	(cons 'shift (wrap-subst w)))))

	(define-syntax-rule (new-mark)
	(module-gensym "m"))

	;; make-empty-ribcage and extend-ribcage maintain list-based ribcages for
	;; internal definitions, in which the ribcages are built incrementally
	(define-syntax-rule (make-empty-ribcage)
	(make-ribcage '() '() '()))

	(define extend-ribcage!
	;; must receive ids with complete wraps
	(lambda (ribcage id label)
	(set-ribcage-symnames! ribcage
	(cons (syntax-expression id)
	(ribcage-symnames ribcage)))
	(set-ribcage-marks! ribcage
	(cons (wrap-marks (syntax-wrap id))
	(ribcage-marks ribcage)))
	(set-ribcage-labels! ribcage
	(cons label (ribcage-labels ribcage)))))

	;; make-binding-wrap creates vector-based ribcages
	(define make-binding-wrap
	(lambda (ids labels w)
	(if (null? ids)
	w
	(make-wrap
	(wrap-marks w)
	(cons
	(let ((labelvec (list->vector labels)))
	(let ((n (vector-length labelvec)))
	(let ((symnamevec (make-vector n)) (marksvec (make-vector n)))
	(let f ((ids ids) (i 0))
	(if (not (null? ids))
	(call-with-values
	(lambda () (id-sym-name&marks (car ids) w))
	(lambda (symname marks)
	(vector-set! symnamevec i symname)
	(vector-set! marksvec i marks)
	(f (cdr ids) (fx+ i 1))))))
	(make-ribcage symnamevec marksvec labelvec))))
	(wrap-subst w))))))

	(define smart-append
	(lambda (m1 m2)
	(if (null? m2)
	m1
	(append m1 m2))))

	(define join-wraps
	(lambda (w1 w2)
	(let ((m1 (wrap-marks w1)) (s1 (wrap-subst w1)))
	(if (null? m1)
	(if (null? s1)
	w2
	(make-wrap
	(wrap-marks w2)
	(smart-append s1 (wrap-subst w2))))
	(make-wrap
	(smart-append m1 (wrap-marks w2))
	(smart-append s1 (wrap-subst w2)))))))

	(define join-marks
	(lambda (m1 m2)
	(smart-append m1 m2)))

	(define same-marks?
	(lambda (x y)
	(or (eq? x y)
	(and (not (null? x))
	(not (null? y))
	(eq? (car x) (car y))
	(same-marks? (cdr x) (cdr y))))))

	(define id-var-name
	;; Syntax objects use wraps to associate names with marked
	;; identifiers. This function returns the name corresponding to
	;; the given identifier and wrap, or the original identifier if no
	;; corresponding name was found.
	;;
	;; The name may be a string created by gen-label, indicating a
	;; lexical binding, or another syntax object, indicating a
	;; reference to a top-level definition created during a previous
	;; macroexpansion.
	;;
	;; For lexical variables, finding a label simply amounts to
	;; looking for an entry with the same symbolic name and the same
	;; marks. Finding a toplevel definition is the same, except we
	;; also have to compare modules, hence the `mod' parameter.
	;; Instead of adding a separate entry in the ribcage for modules,
	;; which wouldn't be used for lexicals, we arrange for the entry
	;; for the name entry to be a pair with the module in its car, and
	;; the name itself in the cdr. So if the name that we find is a
	;; pair, we have to check modules.
	;;
	;; The identifer may be passed in wrapped or unwrapped. In any
	;; case, this routine returns either a symbol, a syntax object, or
	;; a string label.
	;;
	(lambda (id w mod)
	(define-syntax-rule (first e)
	;; Rely on Guile's multiple-values truncation.
	e)
	(define search
	(lambda (sym subst marks mod)
	(if (null? subst)
	(values #f marks)
	(let ((fst (car subst)))
	(if (eq? fst 'shift)
	(search sym (cdr subst) (cdr marks) mod)
	(let ((symnames (ribcage-symnames fst)))
	(if (vector? symnames)
	(search-vector-rib sym subst marks symnames fst mod)
	(search-list-rib sym subst marks symnames fst mod))))))))
	(define search-list-rib
	(lambda (sym subst marks symnames ribcage mod)
	(let f ((symnames symnames)
	(rlabels (ribcage-labels ribcage))
	(rmarks (ribcage-marks ribcage)))
	(cond
	((null? symnames) (search sym (cdr subst) marks mod))
	((and (eq? (car symnames) sym) (same-marks? marks (car rmarks)))
	(let ((n (car rlabels)))
	(if (pair? n)
	(if (equal? mod (car n))
	(values (cdr n) marks)
	(f (cdr symnames) (cdr rlabels) (cdr rmarks)))
	(values n marks))))
	(else (f (cdr symnames) (cdr rlabels) (cdr rmarks)))))))
	(define search-vector-rib
	(lambda (sym subst marks symnames ribcage mod)
	(let ((n (vector-length symnames)))
	(let f ((i 0))
	(cond
	((fx= i n) (search sym (cdr subst) marks mod))
	((and (eq? (vector-ref symnames i) sym)
	(same-marks? marks (vector-ref (ribcage-marks ribcage) i)))
	(let ((n (vector-ref (ribcage-labels ribcage) i)))
	(if (pair? n)
	(if (equal? mod (car n))
	(values (cdr n) marks)
	(f (fx+ i 1)))
	(values n marks))))
	(else (f (fx+ i 1))))))))
	(cond
	((symbol? id)
	(or (first (search id (wrap-subst w) (wrap-marks w) mod)) id))
	((syntax? id)
	(let ((id (syntax-expression id))
	(w1 (syntax-wrap id))
	(mod (or (syntax-module id) mod)))
	(let ((marks (join-marks (wrap-marks w) (wrap-marks w1))))
	(call-with-values (lambda () (search id (wrap-subst w) marks mod))
	(lambda (new-id marks)
	(or new-id
	(first (search id (wrap-subst w1) marks mod))
	id))))))
	(else (syntax-violation 'id-var-name "invalid id" id)))))

	;; A helper procedure for syntax-locally-bound-identifiers, which
	;; itself is a helper for transformer procedures.
	;; `locally-bound-identifiers' returns a list of all bindings
	;; visible to a syntax object with the given wrap. They are in
	;; order from outer to inner.
	;;
	;; The purpose of this procedure is to give a transformer procedure
	;; references on bound identifiers, that the transformer can then
	;; introduce some of them in its output. As such, the identifiers
	;; are anti-marked, so that rebuild-macro-output doesn't apply new
	;; marks to them.
	;;
	(define locally-bound-identifiers
	(lambda (w mod)
	(define scan
	(lambda (subst results)
	(if (null? subst)
	results
	(let ((fst (car subst)))
	(if (eq? fst 'shift)
	(scan (cdr subst) results)
	(let ((symnames (ribcage-symnames fst))
	(marks (ribcage-marks fst)))
	(if (vector? symnames)
	(scan-vector-rib subst symnames marks results)
	(scan-list-rib subst symnames marks results))))))))
	(define scan-list-rib
	(lambda (subst symnames marks results)
	(let f ((symnames symnames) (marks marks) (results results))
	(if (null? symnames)
	(scan (cdr subst) results)
	(f (cdr symnames) (cdr marks)
	(cons (wrap (car symnames)
	(anti-mark (make-wrap (car marks) subst))
	mod)
	results))))))
	(define scan-vector-rib
	(lambda (subst symnames marks results)
	(let ((n (vector-length symnames)))
	(let f ((i 0) (results results))
	(if (fx= i n)
	(scan (cdr subst) results)
	(f (fx+ i 1)
	(cons (wrap (vector-ref symnames i)
	(anti-mark (make-wrap (vector-ref marks i) subst))
	mod)
	results)))))))
	(scan (wrap-subst w) '())))

	;; Returns three values: binding type, binding value, and the module
	;; (for resolving toplevel vars).
	(define (resolve-identifier id w r mod resolve-syntax-parameters?)
	(define (resolve-global var mod)
	(when (and (not mod) (current-module))
	(warn "module system is booted, we should have a module" var))
	(let ((v (and (not (equal? mod '(primitive)))
	(module-variable (if mod
	(resolve-module (cdr mod))
	(current-module))
	var))))
	;; The expander needs to know when a top-level definition from
	;; outside the compilation unit is a macro.
	;;
	;; Additionally if a macro is actually a syntax-parameter, we
	;; might need to resolve its current binding. If the syntax
	;; parameter is locally bound (via syntax-parameterize), then
	;; its variable will be present in `r', the expand-time
	;; environment. It's a kind of double lookup: first we see
	;; that a name is bound to a syntax parameter, then we look
	;; for the current binding of the syntax parameter.
	;;
	;; We use the variable (box) holding the syntax parameter
	;; definition as the key for the second lookup. We use the
	;; variable for two reasons:
	;;
	;; 1. If the syntax parameter is redefined in parallel
	;; (perhaps via a parallel module compilation), the
	;; redefinition keeps the same variable. We don't want to
	;; use a "key" that could change during a redefinition. See
	;; https://debbugs.gnu.org/cgi/bugreport.cgi?bug=27476.
	;;
	;; 2. Using the variable instead of its (symname, modname)
	;; pair allows for syntax parameters to be renamed or
	;; aliased while preserving the syntax parameter's identity.
	;;
	(if (and v (variable-bound? v) (macro? (variable-ref v)))
	(let* ((m (variable-ref v))
	(type (macro-type m))
	(trans (macro-binding m))
	(trans (if (pair? trans) (car trans) trans)))
	(if (eq? type 'syntax-parameter)
	(if resolve-syntax-parameters?
	(let ((lexical (assq-ref r v)))
	;; A resolved syntax parameter is
	;; indistinguishable from a macro.
	(values 'macro
	(if lexical
	(binding-value lexical)
	trans)
	mod))
	;; Return box as value for use in second lookup.
	(values type v mod))
	(values type trans mod)))
	(values 'global var mod))))
	(define (resolve-lexical label mod)
	(let ((b (assq-ref r label)))
	(if b
	(let ((type (binding-type b))
	(value (binding-value b)))
	(if (eq? type 'syntax-parameter)
	(if resolve-syntax-parameters?
	(values 'macro value mod)
	;; If the syntax parameter was defined within
	;; this compilation unit, use its label as its
	;; lookup key.
	(values type label mod))
	(values type value mod)))
	(values 'displaced-lexical #f #f))))
	(let ((n (id-var-name id w mod)))
	(cond
	((syntax? n)
	(cond
	((not (eq? n id))
	;; This identifier aliased another; recurse to allow
	;; syntax-parameterize to override macro-introduced syntax
	;; parameters.
	(resolve-identifier n w r mod resolve-syntax-parameters?))
	(else
	;; Resolved to a free variable that was introduced by this
	;; macro; continue to resolve this global by name.
	(resolve-identifier (syntax-expression n)
	(syntax-wrap n)
	r
	(or (syntax-module n) mod)
	resolve-syntax-parameters?))))
	((symbol? n)
	(resolve-global n (or (and (syntax? id)
	(syntax-module id))
	mod)))
	((string? n)
	(resolve-lexical n (or (and (syntax? id)
	(syntax-module id))
	mod)))
	(else
	(error "unexpected id-var-name" id w n)))))

	(define transformer-environment
	(make-fluid
	(lambda (k)
	(error "called outside the dynamic extent of a syntax transformer"))))

	(define (with-transformer-environment k)
	((fluid-ref transformer-environment) k))

	;; free-id=? must be passed fully wrapped ids since (free-id=? x y)
	;; may be true even if (free-id=? (wrap x w) (wrap y w)) is not.

	(define free-id=?
	(lambda (i j)
	(let* ((mi (and (syntax? i) (syntax-module i)))
	(mj (and (syntax? j) (syntax-module j)))
	(ni (id-var-name i empty-wrap mi))
	(nj (id-var-name j empty-wrap mj)))
	(define (id-module-binding id mod)
	(module-variable
	(if mod
	;; The normal case.
	(resolve-module (cdr mod))
	;; Either modules have not been booted, or we have a
	;; raw symbol coming in, which is possible.
	(current-module))
	(id-sym-name id)))
	(cond
	((syntax? ni) (free-id=? ni j))
	((syntax? nj) (free-id=? i nj))
	((symbol? ni)
	;; `i' is not lexically bound. Assert that `j' is free,
	;; and if so, compare their bindings, that they are either
	;; bound to the same variable, or both unbound and have
	;; the same name.
	(and (eq? nj (id-sym-name j))
	(let ((bi (id-module-binding i mi)))
	(if bi
	(eq? bi (id-module-binding j mj))
	(and (not (id-module-binding j mj))
	(eq? ni nj))))
	(eq? (id-module-binding i mi) (id-module-binding j mj))))
	(else
	;; Otherwise `i' is bound, so check that `j' is bound, and
	;; bound to the same thing.
	(equal? ni nj))))))

	;; bound-id=? may be passed unwrapped (or partially wrapped) ids as
	;; long as the missing portion of the wrap is common to both of the ids
	;; since (bound-id=? x y) iff (bound-id=? (wrap x w) (wrap y w))

	(define bound-id=?
	(lambda (i j)
	(if (and (syntax? i) (syntax? j))
	(and (eq? (syntax-expression i)
	(syntax-expression j))
	(same-marks? (wrap-marks (syntax-wrap i))
	(wrap-marks (syntax-wrap j))))
	(eq? i j))))

	;; "valid-bound-ids?" returns #t if it receives a list of distinct ids.
	;; valid-bound-ids? may be passed unwrapped (or partially wrapped) ids
	;; as long as the missing portion of the wrap is common to all of the
	;; ids.

	(define valid-bound-ids?
	(lambda (ids)
	(and (let all-ids? ((ids ids))
	(or (null? ids)
	(and (id? (car ids))
	(all-ids? (cdr ids)))))
	(distinct-bound-ids? ids))))

	;; distinct-bound-ids? expects a list of ids and returns #t if there are
	;; no duplicates. It is quadratic on the length of the id list; long
	;; lists could be sorted to make it more efficient. distinct-bound-ids?
	;; may be passed unwrapped (or partially wrapped) ids as long as the
	;; missing portion of the wrap is common to all of the ids.

	(define distinct-bound-ids?
	(lambda (ids)
	(let distinct? ((ids ids))
	(or (null? ids)
	(and (not (bound-id-member? (car ids) (cdr ids)))
	(distinct? (cdr ids)))))))

	(define bound-id-member?
	(lambda (x list)
	(and (not (null? list))
	(or (bound-id=? x (car list))
	(bound-id-member? x (cdr list))))))

	;; wrapping expressions and identifiers

	(define wrap
	(lambda (x w defmod)
	(source-wrap x w #f defmod)))

	(define (wrap-syntax x w defmod)
	(make-syntax (syntax-expression x)
	w
	(or (syntax-module x) defmod)
	(syntax-sourcev x)))
	(define (source-wrap x w s defmod)
	(cond
	((and (null? (wrap-marks w))
	(null? (wrap-subst w))
	(not defmod)
	(not s))
	x)
	((syntax? x) (wrap-syntax x (join-wraps w (syntax-wrap x)) defmod))
	((null? x) x)
	(else (make-syntax x w defmod s))))

	;; expanding

	(define expand-sequence
	(lambda (body r w s mod)
	(build-sequence s
	(let dobody ((body body) (r r) (w w) (mod mod))
	(if (null? body)
	'()
	(let ((first (expand (car body) r w mod)))
	(cons first (dobody (cdr body) r w mod))))))))

	;; At top-level, we allow mixed definitions and expressions. Like
	;; expand-body we expand in two passes.
	;;
	;; First, from left to right, we expand just enough to know what
	;; expressions are definitions, syntax definitions, and splicing
	;; statements (`begin'). If we anything needs evaluating at
	;; expansion-time, it is expanded directly.
	;;
	;; Otherwise we collect expressions to expand, in thunks, and then
	;; expand them all at the end. This allows all syntax expanders
	;; visible in a toplevel sequence to be visible during the
	;; expansions of all normal definitions and expressions in the
	;; sequence.
	;;
	(define expand-top-sequence
	(lambda (body r w s m esew mod)
	(let* ((r (cons '("placeholder" . (placeholder)) r))
	(ribcage (make-empty-ribcage))
	(w (make-wrap (wrap-marks w) (cons ribcage (wrap-subst w)))))
	(define (record-definition! id var)
	(let ((mod (cons 'hygiene (module-name (current-module)))))
	;; Ribcages map symbol+marks to names, mostly for
	;; resolving lexicals. Here to add a mapping for toplevel
	;; definitions we also need to match the module. So, we
	;; put it in the name instead, and make id-var-name handle
	;; the special case of names that are pairs. See the
	;; comments in id-var-name for more.
	(extend-ribcage! ribcage id
	(cons (or (syntax-module id) mod)
	(wrap var top-wrap mod)))))
	(define (macro-introduced-identifier? id)
	(not (equal? (wrap-marks (syntax-wrap id)) '(top))))
	(define (ensure-fresh-name var)
	;; If a macro introduces a top-level identifier, we attempt
	;; to give it a fresh name by appending the hash of the
	;; expression in which it appears. However, this can fail
	;; for hash collisions, which is more common that one might
	;; think: Guile's hash function stops descending into cdr's
	;; at some point. So, within an expansion unit, fall back
	;; to appending a uniquifying integer.
	(define (ribcage-has-var? var)
	(let lp ((labels (ribcage-labels ribcage)))
	(and (pair? labels)
	(let ((wrapped (cdar labels)))
	(or (eq? (syntax-expression wrapped) var)
	(lp (cdr labels)))))))
	(let lp ((unique var) (n 1))
	(if (ribcage-has-var? unique)
	(let ((tail (string->symbol (number->string n))))
	(lp (symbol-append var '- tail) (1+ n)))
	unique)))
	(define (fresh-derived-name id orig-form)
	(ensure-fresh-name
	(symbol-append
	(syntax-expression id)
	'-
	(string->symbol
	;; FIXME: This encodes hash values into the ABI of
	;; compiled modules; a problem?
	(number->string
	(hash (syntax->datum orig-form) most-positive-fixnum)
	16)))))
	(define (parse body r w s m esew mod)
	(let lp ((body body) (exps '()))
	(if (null? body)
	exps
	(lp (cdr body)
	(append (parse1 (car body) r w s m esew mod)
	exps)))))
	(define (parse1 x r w s m esew mod)
	(define (current-module-for-expansion mod)
	(case (car mod)
	;; If the module was just put in place for hygiene, in a
	;; top-level `begin' always recapture the current
	;; module. If a user wants to override, then we need to
	;; use @@ or similar.
	((hygiene) (cons 'hygiene (module-name (current-module))))
	(else mod)))
	(call-with-values
	(lambda ()
	(let ((mod (current-module-for-expansion mod)))
	(syntax-type x r w (source-annotation x) ribcage mod #f)))
	(lambda (type value form e w s mod)
	(case type
	((define-form)
	(let* ((id (wrap value w mod))
	(label (gen-label))
	(var (if (macro-introduced-identifier? id)
	(fresh-derived-name id x)
	(syntax-expression id))))
	(record-definition! id var)
	(list
	(if (eq? m 'c&e)
	(let ((x (build-global-definition s mod var (expand e r w mod))))
	(top-level-eval-hook x mod)
	(lambda () x))
	(call-with-values
	(lambda () (resolve-identifier id empty-wrap r mod #t))
	(lambda (type* value* mod*)
	;; If the identifier to be bound is currently bound to a
	;; macro, then immediately discard that binding.
	(if (eq? type* 'macro)
	(top-level-eval-hook (build-global-definition
	s mod var (build-void s))
	mod))
	(lambda ()
	(build-global-definition s mod var (expand e r w mod)))))))))
	((define-syntax-form define-syntax-parameter-form)
	(let* ((id (wrap value w mod))
	(label (gen-label))
	(var (if (macro-introduced-identifier? id)
	(fresh-derived-name id x)
	(syntax-expression id))))
	(record-definition! id var)
	(case m
	((c)
	(cond
	((memq 'compile esew)
	(let ((e (expand-install-global mod var type (expand e r w mod))))
	(top-level-eval-hook e mod)
	(if (memq 'load esew)
	(list (lambda () e))
	'())))
	((memq 'load esew)
	(list (lambda ()
	(expand-install-global mod var type (expand e r w mod)))))
	(else '())))
	((c&e)
	(let ((e (expand-install-global mod var type (expand e r w mod))))
	(top-level-eval-hook e mod)
	(list (lambda () e))))
	(else
	(if (memq 'eval esew)
	(top-level-eval-hook
	(expand-install-global mod var type (expand e r w mod))
	mod))
	'()))))
	((begin-form)
	(syntax-case e ()
	((_ e1 ...)
	(parse #'(e1 ...) r w s m esew mod))))
	((local-syntax-form)
	(expand-local-syntax value e r w s mod
	(lambda (forms r w s mod)
	(parse forms r w s m esew mod))))
	((eval-when-form)
	(syntax-case e ()
	((_ (x ...) e1 e2 ...)
	(let ((when-list (parse-when-list e #'(x ...)))
	(body #'(e1 e2 ...)))
	(define (recurse m esew)
	(parse body r w s m esew mod))
	(cond
	((eq? m 'e)
	(if (memq 'eval when-list)
	(recurse (if (memq 'expand when-list) 'c&e 'e)
	'(eval))
	(begin
	(if (memq 'expand when-list)
	(top-level-eval-hook
	(expand-top-sequence body r w s 'e '(eval) mod)
	mod))
	'())))
	((memq 'load when-list)
	(if (or (memq 'compile when-list)
	(memq 'expand when-list)
	(and (eq? m 'c&e) (memq 'eval when-list)))
	(recurse 'c&e '(compile load))
	(if (memq m '(c c&e))
	(recurse 'c '(load))
	'())))
	((or (memq 'compile when-list)
	(memq 'expand when-list)
	(and (eq? m 'c&e) (memq 'eval when-list)))
	(top-level-eval-hook
	(expand-top-sequence body r w s 'e '(eval) mod)
	mod)
	'())
	(else
	'()))))))
	(else
	(list
	(if (eq? m 'c&e)
	(let ((x (expand-expr type value form e r w s mod)))
	(top-level-eval-hook x mod)
	(lambda () x))
	(lambda ()
	(expand-expr type value form e r w s mod)))))))))
	(let ((exps (map (lambda (x) (x))
	(reverse (parse body r w s m esew mod)))))
	(if (null? exps)
	(build-void s)
	(build-sequence s exps))))))

	(define expand-install-global
	(lambda (mod name type e)
	(build-global-definition
	no-source
	mod
	name
	(build-primcall
	no-source
	'make-syntax-transformer
	(list (build-data no-source name)
	(build-data no-source
	(if (eq? type 'define-syntax-parameter-form)
	'syntax-parameter
	'macro))
	e)))))

	(define parse-when-list
	(lambda (e when-list)
	;; `when-list' is syntax'd version of list of situations. We
	;; could match these keywords lexically, via free-id=?, but then
	;; we twingle the definition of eval-when to the bindings of
	;; eval, load, expand, and compile, which is totally unintended.
	;; So do a symbolic match instead.
	(let ((result (strip when-list)))
	(let lp ((l result))
	(if (null? l)
	result
	(if (memq (car l) '(compile load eval expand))
	(lp (cdr l))
	(syntax-violation 'eval-when "invalid situation" e
	(car l))))))))

	;; syntax-type returns seven values: type, value, form, e, w, s, and
	;; mod. The first two are described in the table below.
	;;
	;; type value explanation
	;; -------------------------------------------------------------------
	;; core procedure core singleton
	;; core-form procedure core form
	;; module-ref procedure @ or @@ singleton
	;; lexical name lexical variable reference
	;; global name global variable reference
	;; begin none begin keyword
	;; define none define keyword
	;; define-syntax none define-syntax keyword
	;; define-syntax-parameter none define-syntax-parameter keyword
	;; local-syntax rec? letrec-syntax/let-syntax keyword
	;; eval-when none eval-when keyword
	;; syntax level pattern variable
	;; displaced-lexical none displaced lexical identifier
	;; lexical-call name call to lexical variable
	;; global-call name call to global variable
	;; primitive-call name call to primitive
	;; call none any other call
	;; begin-form none begin expression
	;; define-form id variable definition
	;; define-syntax-form id syntax definition
	;; define-syntax-parameter-form id syntax parameter definition
	;; local-syntax-form rec? syntax definition
	;; eval-when-form none eval-when form
	;; constant none self-evaluating datum
	;; other none anything else
	;;
	;; form is the entire form. For definition forms (define-form,
	;; define-syntax-form, and define-syntax-parameter-form), e is the
	;; rhs expression. For all others, e is the entire form. w is the
	;; wrap for both form and e. s is the source for the entire form.
	;; mod is the module for both form and e.
	;;
	;; syntax-type expands macros and unwraps as necessary to get to one
	;; of the forms above. It also parses definition forms, although
	;; perhaps this should be done by the consumer.

	(define syntax-type
	(lambda (e r w s rib mod for-car?)
	(cond
	((symbol? e)
	(call-with-values (lambda () (resolve-identifier e w r mod #t))
	(lambda (type value mod*)
	(case type
	((macro)
	(if for-car?
	(values type value e e w s mod)
	(syntax-type (expand-macro value e r w s rib mod)
	r empty-wrap s rib mod #f)))
	((global)
	;; Toplevel definitions may resolve to bindings with
	;; different names or in different modules.
	(values type value e value w s mod*))
	(else (values type value e e w s mod))))))
	((pair? e)
	(let ((first (car e)))
	(call-with-values
	(lambda () (syntax-type first r w s rib mod #t))
	(lambda (ftype fval fform fe fw fs fmod)
	(case ftype
	((lexical)
	(values 'lexical-call fval e e w s mod))
	((global)
	(if (equal? fmod '(primitive))
	(values 'primitive-call fval e e w s mod)
	;; If we got here via an (@@ ...) expansion, we
	;; need to make sure the fmod information is
	;; propagated back correctly -- hence this
	;; consing.
	(values 'global-call (make-syntax fval w fmod fs)
	e e w s mod)))
	((macro)
	(syntax-type (expand-macro fval e r w s rib mod)
	r empty-wrap s rib mod for-car?))
	((module-ref)
	(call-with-values (lambda () (fval e r w mod))
	(lambda (e r w s mod)
	(syntax-type e r w s rib mod for-car?))))
	((core)
	(values 'core-form fval e e w s mod))
	((local-syntax)
	(values 'local-syntax-form fval e e w s mod))
	((begin)
	(values 'begin-form #f e e w s mod))
	((eval-when)
	(values 'eval-when-form #f e e w s mod))
	((define)
	(syntax-case e ()
	((_ name val)
	(id? #'name)
	(values 'define-form #'name e #'val w s mod))
	((_ (name . args) e1 e2 ...)
	(and (id? #'name)
	(valid-bound-ids? (lambda-var-list #'args)))
	;; need lambda here...
	(values 'define-form (wrap #'name w mod)
	(wrap e w mod)
	(source-wrap
	(cons #'lambda (wrap #'(args e1 e2 ...) w mod))
	empty-wrap s #f)
	empty-wrap s mod))
	((_ name)
	(id? #'name)
	(values 'define-form (wrap #'name w mod)
	(wrap e w mod)
	#'(if #f #f)
	empty-wrap s mod))))
	((define-syntax)
	(syntax-case e ()
	((_ name val)
	(id? #'name)
	(values 'define-syntax-form #'name e #'val w s mod))))
	((define-syntax-parameter)
	(syntax-case e ()
	((_ name val)
	(id? #'name)
	(values 'define-syntax-parameter-form #'name e #'val w s mod))))
	(else
	(values 'call #f e e w s mod)))))))
	((syntax? e)
	(syntax-type (syntax-expression e)
	r
	(join-wraps w (syntax-wrap e))
	(or (source-annotation e) s) rib
	(or (syntax-module e) mod) for-car?))
	((self-evaluating? e) (values 'constant #f e e w s mod))
	(else (values 'other #f e e w s mod)))))

	(define expand
	(lambda (e r w mod)
	(call-with-values
	(lambda () (syntax-type e r w (source-annotation e) #f mod #f))
	(lambda (type value form e w s mod)
	(expand-expr type value form e r w s mod)))))

	(define expand-expr
	(lambda (type value form e r w s mod)
	(case type
	((lexical)
	(build-lexical-reference 'value s e value))
	((core core-form)
	;; apply transformer
	(value e r w s mod))
	((module-ref)
	(call-with-values (lambda () (value e r w mod))
	(lambda (e r w s mod)
	(expand e r w mod))))
	((lexical-call)
	(expand-call
	(let ((id (car e)))
	(build-lexical-reference 'fun (source-annotation id)
	(if (syntax? id)
	(syntax->datum id)
	id)
	value))
	e r w s mod))
	((global-call)
	(expand-call
	(build-global-reference (or (source-annotation (car e)) s)
	(if (syntax? value)
	(syntax-expression value)
	value)
	(or (and (syntax? value)
	(syntax-module value))
	mod))
	e r w s mod))
	((primitive-call)
	(syntax-case e ()
	((_ e ...)
	(build-primcall s
	value
	(map (lambda (e) (expand e r w mod))
	#'(e ...))))))
	((constant) (build-data s (strip e)))
	((global) (build-global-reference s value mod))
	((call) (expand-call (expand (car e) r w mod) e r w s mod))
	((begin-form)
	(syntax-case e ()
	((_ e1 e2 ...) (expand-sequence #'(e1 e2 ...) r w s mod))
	((_)
	(syntax-violation #f "sequence of zero expressions"
	(source-wrap e w s mod)))))
	((local-syntax-form)
	(expand-local-syntax value e r w s mod expand-sequence))
	((eval-when-form)
	(syntax-case e ()
	((_ (x ...) e1 e2 ...)
	(let ((when-list (parse-when-list e #'(x ...))))
	(if (memq 'eval when-list)
	(expand-sequence #'(e1 e2 ...) r w s mod)
	(expand-void))))))
	((define-form define-syntax-form define-syntax-parameter-form)
	(syntax-violation #f "definition in expression context, where definitions are not allowed,"
	(source-wrap form w s mod)))
	((syntax)
	(syntax-violation #f "reference to pattern variable outside syntax form"
	(source-wrap e w s mod)))
	((displaced-lexical)
	(syntax-violation #f "reference to identifier outside its scope"
	(source-wrap e w s mod)))
	(else (syntax-violation #f "unexpected syntax"
	(source-wrap e w s mod))))))

	(define expand-call
	(lambda (x e r w s mod)
	(syntax-case e ()
	((e0 e1 ...)
	(build-call s x
	(map (lambda (e) (expand e r w mod)) #'(e1 ...)))))))

	;; (What follows is my interpretation of what's going on here -- Andy)
	;;
	;; A macro takes an expression, a tree, the leaves of which are identifiers
	;; and datums. Identifiers are symbols along with a wrap and a module. For
	;; efficiency, subtrees that share wraps and modules may be grouped as one
	;; syntax object.
	;;
	;; Going into the expansion, the expression is given an anti-mark, which
	;; logically propagates to all leaves. Then, in the new expression returned
	;; from the transfomer, if we see an expression with an anti-mark, we know it
	;; pertains to the original expression; conversely, expressions without the
	;; anti-mark are known to be introduced by the transformer.
	;;
	;; OK, good until now. We know this algorithm does lexical scoping
	;; appropriately because it's widely known in the literature, and psyntax is
	;; widely used. But what about modules? Here we're on our own. What we do is
	;; to mark the module of expressions produced by a macro as pertaining to the
	;; module that was current when the macro was defined -- that is, free
	;; identifiers introduced by a macro are scoped in the macro's module, not in
	;; the expansion's module. Seems to work well.
	;;
	;; The only wrinkle is when we want a macro to expand to code in another
	;; module, as is the case for the r6rs `library' form -- the body expressions
	;; should be scoped relative the the new module, the one defined by the macro.
	;; For that, use `(@@ mod-name body)'.
	;;
	;; Part of the macro output will be from the site of the macro use and part
	;; from the macro definition. We allow source information from the macro use
	;; to pass through, but we annotate the parts coming from the macro with the
	;; source location information corresponding to the macro use. It would be
	;; really nice if we could also annotate introduced expressions with the
	;; locations corresponding to the macro definition, but that is not yet
	;; possible.
	(define expand-macro
	(lambda (p e r w s rib mod)
	(define (decorate-source x)
	(source-wrap x empty-wrap s #f))
	(define (map* f x)
	(cond
	((null? x) x)
	((pair? x) (cons (f (car x)) (map* f (cdr x))))
	(else (f x))))
	(define rebuild-macro-output
	(lambda (x m)
	(cond ((pair? x)
	(decorate-source
	(map* (lambda (x) (rebuild-macro-output x m)) x)))
	((syntax? x)
	(let ((w (syntax-wrap x)))
	(let ((ms (wrap-marks w)) (ss (wrap-subst w)))
	(if (and (pair? ms) (eq? (car ms) the-anti-mark))
	;; output is from original text
	(wrap-syntax
	x
	(make-wrap (cdr ms)
	(if rib
	(cons rib (cdr ss))
	(cdr ss)))
	mod)
	;; output introduced by macro
	(wrap-syntax
	x
	(make-wrap (cons m ms)
	(if rib
	(cons rib (cons 'shift ss))
	(cons 'shift ss)))
	mod)))))

	((vector? x)
	(let* ((n (vector-length x))
	(v (make-vector n)))
	(do ((i 0 (fx+ i 1)))
	((fx= i n) v)
	(vector-set! v i
	(rebuild-macro-output (vector-ref x i) m)))
	(decorate-source v)))
	((symbol? x)
	(syntax-violation #f "encountered raw symbol in macro output"
	(source-wrap e w (wrap-subst w) mod) x))
	(else (decorate-source x)))))
	(with-fluids ((transformer-environment
	(lambda (k) (k e r w s rib mod))))
	(rebuild-macro-output (p (source-wrap e (anti-mark w) s mod))
	(new-mark)))))

	(define expand-body
	;; In processing the forms of the body, we create a new, empty wrap.
	;; This wrap is augmented (destructively) each time we discover that
	;; the next form is a definition. This is done:
	;;
	;; (1) to allow the first nondefinition form to be a call to
	;; one of the defined ids even if the id previously denoted a
	;; definition keyword or keyword for a macro expanding into a
	;; definition;
	;; (2) to prevent subsequent definition forms (but unfortunately
	;; not earlier ones) and the first nondefinition form from
	;; confusing one of the bound identifiers for an auxiliary
	;; keyword; and
	;; (3) so that we do not need to restart the expansion of the
	;; first nondefinition form, which is problematic anyway
	;; since it might be the first element of a begin that we
	;; have just spliced into the body (meaning if we restarted,
	;; we'd really need to restart with the begin or the macro
	;; call that expanded into the begin, and we'd have to give
	;; up allowing (begin <defn>+ <expr>+), which is itself
	;; problematic since we don't know if a begin contains only
	;; definitions until we've expanded it).
	;;
	;; Before processing the body, we also create a new environment
	;; containing a placeholder for the bindings we will add later and
	;; associate this environment with each form. In processing a
	;; let-syntax or letrec-syntax, the associated environment may be
	;; augmented with local keyword bindings, so the environment may
	;; be different for different forms in the body. Once we have
	;; gathered up all of the definitions, we evaluate the transformer
	;; expressions and splice into r at the placeholder the new variable
	;; and keyword bindings. This allows let-syntax or letrec-syntax
	;; forms local to a portion or all of the body to shadow the
	;; definition bindings.
	;;
	;; Subforms of a begin, let-syntax, or letrec-syntax are spliced
	;; into the body.
	;;
	;; outer-form is fully wrapped w/source
	(lambda (body outer-form r w mod)
	(let* ((r (cons '("placeholder" . (placeholder)) r))
	(ribcage (make-empty-ribcage))
	(w (make-wrap (wrap-marks w) (cons ribcage (wrap-subst w)))))
	(let parse ((body (map (lambda (x) (cons r (wrap x w mod))) body))
	(ids '()) (labels '())
	(var-ids '()) (vars '()) (vals '()) (bindings '())
	(expand-tail-expr #f))
	(cond
	((null? body)
	(unless expand-tail-expr
	(when (null? ids)
	(syntax-violation #f "empty body" outer-form))
	(syntax-violation #f "body should end with an expression" outer-form))
	(unless (valid-bound-ids? ids)
	(syntax-violation
	#f "invalid or duplicate identifier in definition"
	outer-form))
	(set-cdr! r (extend-env labels bindings (cdr r)))
	(let ((src (source-annotation outer-form)))
	(let lp ((var-ids var-ids) (vars vars) (vals vals)
	(tail (expand-tail-expr)))
	(cond
	((null? var-ids) tail)
	((not (car var-ids))
	(lp (cdr var-ids) (cdr vars) (cdr vals)
	(make-seq src ((car vals)) tail)))
	(else
	(let ((var-ids (map (lambda (id)
	(if id (syntax->datum id) '_))
	(reverse var-ids)))
	(vars (map (lambda (var) (or var (gen-label)))
	(reverse vars)))
	(vals (map (lambda (expand-expr id)
	(if id
	(expand-expr)
	(make-seq src
	(expand-expr)
	(build-void src))))
	(reverse vals) (reverse var-ids))))
	(build-letrec src #t var-ids vars vals tail)))))))
	(expand-tail-expr
	(parse body ids labels
	(cons #f var-ids)
	(cons #f vars)
	(cons expand-tail-expr vals)
	bindings #f))
	(else
	(let ((e (cdar body)) (er (caar body)) (body (cdr body)))
	(call-with-values
	(lambda () (syntax-type e er empty-wrap (source-annotation e) ribcage mod #f))
	(lambda (type value form e w s mod)
	(case type
	((define-form)
	(let ((id (wrap value w mod)) (label (gen-label)))
	(let ((var (gen-var id)))
	(extend-ribcage! ribcage id label)
	(parse body
	(cons id ids) (cons label labels)
	(cons id var-ids)
	(cons var vars)
	(cons (let ((wrapped (source-wrap e w s mod)))
	(lambda ()
	(expand wrapped er empty-wrap mod)))
	vals)
	(cons (make-binding 'lexical var) bindings)
	#f))))
	((define-syntax-form)
	(let ((id (wrap value w mod))
	(label (gen-label))
	(trans-r (macros-only-env er)))
	(extend-ribcage! ribcage id label)
	;; As required by R6RS, evaluate the right-hand-sides of internal
	;; syntax definition forms and add their transformers to the
	;; compile-time environment immediately, so that the newly-defined
	;; keywords may be used in definition context within the same
	;; lexical contour.
	(set-cdr! r (extend-env
	(list label)
	(list (make-binding
	'macro
	(eval-local-transformer
	(expand e trans-r w mod)
	mod)))
	(cdr r)))
	(parse body (cons id ids)
	labels var-ids vars vals bindings #f)))
	((define-syntax-parameter-form)
	;; Same as define-syntax-form, different binding type though.
	(let ((id (wrap value w mod))
	(label (gen-label))
	(trans-r (macros-only-env er)))
	(extend-ribcage! ribcage id label)
	(set-cdr! r (extend-env
	(list label)
	(list (make-binding
	'syntax-parameter
	(eval-local-transformer
	(expand e trans-r w mod)
	mod)))
	(cdr r)))
	(parse body (cons id ids)
	labels var-ids vars vals bindings #f)))
	((begin-form)
	(syntax-case e ()
	((_ e1 ...)
	(parse (let f ((forms #'(e1 ...)))
	(if (null? forms)
	body
	(cons (cons er (wrap (car forms) w mod))
	(f (cdr forms)))))
	ids labels var-ids vars vals bindings #f))))
	((local-syntax-form)
	(expand-local-syntax
	value e er w s mod
	(lambda (forms er w s mod)
	(parse (let f ((forms forms))
	(if (null? forms)
	body
	(cons (cons er (wrap (car forms) w mod))
	(f (cdr forms)))))
	ids labels var-ids vars vals bindings #f))))
	(else ; An expression, not a definition.
	(let ((wrapped (source-wrap e w s mod)))
	(parse body ids labels var-ids vars vals bindings
	(lambda ()
	(expand wrapped er empty-wrap mod)))))))))))))))

	(define expand-local-syntax
	(lambda (rec? e r w s mod k)
	(syntax-case e ()
	((_ ((id val) ...) e1 e2 ...)
	(let ((ids #'(id ...)))
	(if (not (valid-bound-ids? ids))
	(syntax-violation #f "duplicate bound keyword" e)
	(let ((labels (gen-labels ids)))
	(let ((new-w (make-binding-wrap ids labels w)))
	(k #'(e1 e2 ...)
	(extend-env
	labels
	(let ((w (if rec? new-w w))
	(trans-r (macros-only-env r)))
	(map (lambda (x)
	(make-binding 'macro
	(eval-local-transformer
	(expand x trans-r w mod)
	mod)))
	#'(val ...)))
	r)
	new-w
	s
	mod))))))
	(_ (syntax-violation #f "bad local syntax definition"
	(source-wrap e w s mod))))))

	(define eval-local-transformer
	(lambda (expanded mod)
	(let ((p (local-eval-hook expanded mod)))
	(if (procedure? p)
	p
	(syntax-violation #f "nonprocedure transformer" p)))))

	(define expand-void
	(lambda ()
	(build-void no-source)))

	(define ellipsis?
	(lambda (e r mod)
	(and (nonsymbol-id? e)
	;; If there is a binding for the special identifier
	;; #{ $sc-ellipsis }# in the lexical environment of E,
	;; and if the associated binding type is 'ellipsis',
	;; then the binding's value specifies the custom ellipsis
	;; identifier within that lexical environment, and the
	;; comparison is done using 'bound-id=?'.
	(call-with-values
	(lambda () (resolve-identifier
	(make-syntax '#{ $sc-ellipsis }#
	(syntax-wrap e)
	(or (syntax-module e) mod)
	#f)
	empty-wrap r mod #f))
	(lambda (type value mod)
	(if (eq? type 'ellipsis)
	(bound-id=? e value)
	(free-id=? e #'(... ...))))))))

	(define lambda-formals
	(lambda (orig-args)
	(define (req args rreq)
	(syntax-case args ()
	(()
	(check (reverse rreq) #f))
	((a . b) (id? #'a)
	(req #'b (cons #'a rreq)))
	(r (id? #'r)
	(check (reverse rreq) #'r))
	(else
	(syntax-violation 'lambda "invalid argument list" orig-args args))))
	(define (check req rest)
	(cond
	((distinct-bound-ids? (if rest (cons rest req) req))
	(values req #f rest #f))
	(else
	(syntax-violation 'lambda "duplicate identifier in argument list"
	orig-args))))
	(req orig-args '())))

	(define expand-simple-lambda
	(lambda (e r w s mod req rest meta body)
	(let* ((ids (if rest (append req (list rest)) req))
	(vars (map gen-var ids))
	(labels (gen-labels ids)))
	(build-simple-lambda
	s
	(map syntax->datum req) (and rest (syntax->datum rest)) vars
	meta
	(expand-body body (source-wrap e w s mod)
	(extend-var-env labels vars r)
	(make-binding-wrap ids labels w)
	mod)))))

	(define lambda*-formals
	(lambda (orig-args)
	(define (req args rreq)
	(syntax-case args ()
	(()
	(check (reverse rreq) '() #f '()))
	((a . b) (id? #'a)
	(req #'b (cons #'a rreq)))
	((a . b) (eq? (syntax->datum #'a) #:optional)
	(opt #'b (reverse rreq) '()))
	((a . b) (eq? (syntax->datum #'a) #:key)
	(key #'b (reverse rreq) '() '()))
	((a b) (eq? (syntax->datum #'a) #:rest)
	(rest #'b (reverse rreq) '() '()))
	(r (id? #'r)
	(rest #'r (reverse rreq) '() '()))
	(else
	(syntax-violation 'lambda* "invalid argument list" orig-args args))))
	(define (opt args req ropt)
	(syntax-case args ()
	(()
	(check req (reverse ropt) #f '()))
	((a . b) (id? #'a)
	(opt #'b req (cons #'(a #f) ropt)))
	(((a init) . b) (id? #'a)
	(opt #'b req (cons #'(a init) ropt)))
	((a . b) (eq? (syntax->datum #'a) #:key)
	(key #'b req (reverse ropt) '()))
	((a b) (eq? (syntax->datum #'a) #:rest)
	(rest #'b req (reverse ropt) '()))
	(r (id? #'r)
	(rest #'r req (reverse ropt) '()))
	(else
	(syntax-violation 'lambda* "invalid optional argument list"
	orig-args args))))
	(define (key args req opt rkey)
	(syntax-case args ()
	(()
	(check req opt #f (cons #f (reverse rkey))))
	((a . b) (id? #'a)
	(with-syntax ((k (symbol->keyword (syntax->datum #'a))))
	(key #'b req opt (cons #'(k a #f) rkey))))
	(((a init) . b) (id? #'a)
	(with-syntax ((k (symbol->keyword (syntax->datum #'a))))
	(key #'b req opt (cons #'(k a init) rkey))))
	(((a init k) . b) (and (id? #'a)
	(keyword? (syntax->datum #'k)))
	(key #'b req opt (cons #'(k a init) rkey)))
	((aok) (eq? (syntax->datum #'aok) #:allow-other-keys)
	(check req opt #f (cons #t (reverse rkey))))
	((aok a b) (and (eq? (syntax->datum #'aok) #:allow-other-keys)
	(eq? (syntax->datum #'a) #:rest))
	(rest #'b req opt (cons #t (reverse rkey))))
	((aok . r) (and (eq? (syntax->datum #'aok) #:allow-other-keys)
	(id? #'r))
	(rest #'r req opt (cons #t (reverse rkey))))
	((a b) (eq? (syntax->datum #'a) #:rest)
	(rest #'b req opt (cons #f (reverse rkey))))
	(r (id? #'r)
	(rest #'r req opt (cons #f (reverse rkey))))
	(else
	(syntax-violation 'lambda* "invalid keyword argument list"
	orig-args args))))
	(define (rest args req opt kw)
	(syntax-case args ()
	(r (id? #'r)
	(check req opt #'r kw))
	(else
	(syntax-violation 'lambda* "invalid rest argument"
	orig-args args))))
	(define (check req opt rest kw)
	(cond
	((distinct-bound-ids?
	(append req (map car opt) (if rest (list rest) '())
	(if (pair? kw) (map cadr (cdr kw)) '())))
	(values req opt rest kw))
	(else
	(syntax-violation 'lambda* "duplicate identifier in argument list"
	orig-args))))
	(req orig-args '())))

	(define expand-lambda-case
	(lambda (e r w s mod get-formals clauses)
	(define (parse-req req opt rest kw body)
	(let ((vars (map gen-var req))
	(labels (gen-labels req)))
	(let ((r* (extend-var-env labels vars r))
	(w* (make-binding-wrap req labels w)))
	(parse-opt (map syntax->datum req)
	opt rest kw body (reverse vars) r* w* '() '()))))
	(define (parse-opt req opt rest kw body vars r* w* out inits)
	(cond
	((pair? opt)
	(syntax-case (car opt) ()
	((id i)
	(let* ((v (gen-var #'id))
	(l (gen-labels (list v)))
	(r** (extend-var-env l (list v) r*))
	(w** (make-binding-wrap (list #'id) l w*)))
	(parse-opt req (cdr opt) rest kw body (cons v vars)
	r w (cons (syntax->datum #'id) out)
	(cons (expand #'i r* w* mod) inits))))))
	(rest
	(let* ((v (gen-var rest))
	(l (gen-labels (list v)))
	(r* (extend-var-env l (list v) r*))
	(w* (make-binding-wrap (list rest) l w*)))
	(parse-kw req (if (pair? out) (reverse out) #f)
	(syntax->datum rest)
	(if (pair? kw) (cdr kw) kw)
	body (cons v vars) r* w*
	(if (pair? kw) (car kw) #f)
	'() inits)))
	(else
	(parse-kw req (if (pair? out) (reverse out) #f) #f
	(if (pair? kw) (cdr kw) kw)
	body vars r* w*
	(if (pair? kw) (car kw) #f)
	'() inits))))
	(define (parse-kw req opt rest kw body vars r* w* aok out inits)
	(cond
	((pair? kw)
	(syntax-case (car kw) ()
	((k id i)
	(let* ((v (gen-var #'id))
	(l (gen-labels (list v)))
	(r** (extend-var-env l (list v) r*))
	(w** (make-binding-wrap (list #'id) l w*)))
	(parse-kw req opt rest (cdr kw) body (cons v vars)
	r w aok
	(cons (list (syntax->datum #'k)
	(syntax->datum #'id)
	v)
	out)
	(cons (expand #'i r* w* mod) inits))))))
	(else
	(parse-body req opt rest
	(if (or aok (pair? out)) (cons aok (reverse out)) #f)
	body (reverse vars) r* w* (reverse inits) '()))))
	(define (parse-body req opt rest kw body vars r* w* inits meta)
	(syntax-case body ()
	((docstring e1 e2 ...) (string? (syntax->datum #'docstring))
	(parse-body req opt rest kw #'(e1 e2 ...) vars r* w* inits
	(append meta
	`((documentation
	. ,(syntax->datum #'docstring))))))
	((#((k . v) ...) e1 e2 ...)
	(parse-body req opt rest kw #'(e1 e2 ...) vars r* w* inits
	(append meta (syntax->datum #'((k . v) ...)))))
	((e1 e2 ...)
	(values meta req opt rest kw inits vars
	(expand-body #'(e1 e2 ...) (source-wrap e w s mod)
	r* w* mod)))))

	(syntax-case clauses ()
	(() (values '() #f))
	(((args e1 e2 ...) (args* e1* e2* ...) ...)
	(call-with-values (lambda () (get-formals #'args))
	(lambda (req opt rest kw)
	(call-with-values (lambda ()
	(parse-req req opt rest kw #'(e1 e2 ...)))
	(lambda (meta req opt rest kw inits vars body)
	(call-with-values
	(lambda ()
	(expand-lambda-case e r w s mod get-formals
	#'((args* e1* e2* ...) ...)))
	(lambda (meta* else*)
	(values
	(append meta meta*)
	(build-lambda-case s req opt rest kw inits vars
	body else*))))))))))))

	;; data

	;; strips syntax objects, recursively.

	(define (strip x)
	(define (annotate proc datum)
	(let ((s (proc x)))
	(when (and s (supports-source-properties? datum))
	(set-source-properties! datum (sourcev->alist s)))
	datum))
	(cond
	((syntax? x)
	(annotate syntax-sourcev (strip (syntax-expression x))))
	((pair? x)
	(cons (strip (car x)) (strip (cdr x))))
	((vector? x)
	(list->vector (strip (vector->list x))))
	(else x)))

	;; lexical variables

	(define gen-var
	(lambda (id)
	(let ((id (if (syntax? id) (syntax-expression id) id)))
	(build-lexical-var no-source id))))

	;; appears to return a reversed list
	(define lambda-var-list
	(lambda (vars)
	(let lvl ((vars vars) (ls '()) (w empty-wrap))
	(cond
	((pair? vars) (lvl (cdr vars) (cons (wrap (car vars) w #f) ls) w))
	((id? vars) (cons (wrap vars w #f) ls))
	((null? vars) ls)
	((syntax? vars)
	(lvl (syntax-expression vars)
	ls
	(join-wraps w (syntax-wrap vars))))
	;; include anything else to be caught by subsequent error
	;; checking
	(else (cons vars ls))))))

	;; core transformers

	(global-extend 'local-syntax 'letrec-syntax #t)
	(global-extend 'local-syntax 'let-syntax #f)

	(global-extend
	'core 'syntax-parameterize
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ ((var val) ...) e1 e2 ...)
	(valid-bound-ids? #'(var ...))
	(let ((names
	(map (lambda (x)
	(call-with-values
	(lambda () (resolve-identifier x w r mod #f))
	(lambda (type value mod)
	(case type
	((displaced-lexical)
	(syntax-violation 'syntax-parameterize
	"identifier out of context"
	e
	(source-wrap x w s mod)))
	((syntax-parameter)
	value)
	(else
	(syntax-violation 'syntax-parameterize
	"invalid syntax parameter"
	e
	(source-wrap x w s mod)))))))
	#'(var ...)))
	(bindings
	(let ((trans-r (macros-only-env r)))
	(map (lambda (x)
	(make-binding
	'syntax-parameter
	(eval-local-transformer (expand x trans-r w mod) mod)))
	#'(val ...)))))
	(expand-body #'(e1 e2 ...)
	(source-wrap e w s mod)
	(extend-env names bindings r)
	w
	mod)))
	(_ (syntax-violation 'syntax-parameterize "bad syntax"
	(source-wrap e w s mod))))))

	(global-extend 'core 'quote
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ e) (build-data s (strip #'e)))
	(_ (syntax-violation 'quote "bad syntax"
	(source-wrap e w s mod))))))

	(global-extend 'core 'quote-syntax
	(lambda (e r w s mod)
	(syntax-case (source-wrap e w s mod) ()
	((_ e) (build-data s #'e))
	(e (syntax-violation 'quote "bad syntax" #'e)))))

	(global-extend
	'core 'syntax
	(let ()
	(define gen-syntax
	(lambda (src e r maps ellipsis? mod)
	(if (id? e)
	(call-with-values (lambda ()
	(resolve-identifier e empty-wrap r mod #f))
	(lambda (type value mod)
	(case type
	((syntax)
	(call-with-values
	(lambda () (gen-ref src (car value) (cdr value) maps))
	(lambda (var maps)
	(values `(ref ,var) maps))))
	(else
	(if (ellipsis? e r mod)
	(syntax-violation 'syntax "misplaced ellipsis" src)
	(values `(quote ,e) maps))))))
	(syntax-case e ()
	((dots e)
	(ellipsis? #'dots r mod)
	(gen-syntax src #'e r maps (lambda (e r mod) #f) mod))
	((x dots . y)
	;; this could be about a dozen lines of code, except that we
	;; choose to handle #'(x ... ...) forms
	(ellipsis? #'dots r mod)
	(let f ((y #'y)
	(k (lambda (maps)
	(call-with-values
	(lambda ()
	(gen-syntax src #'x r
	(cons '() maps) ellipsis? mod))
	(lambda (x maps)
	(if (null? (car maps))
	(syntax-violation 'syntax "extra ellipsis"
	src)
	(values (gen-map x (car maps))
	(cdr maps))))))))
	(syntax-case y ()
	((dots . y)
	(ellipsis? #'dots r mod)
	(f #'y
	(lambda (maps)
	(call-with-values
	(lambda () (k (cons '() maps)))
	(lambda (x maps)
	(if (null? (car maps))
	(syntax-violation 'syntax "extra ellipsis" src)
	(values (gen-mappend x (car maps))
	(cdr maps))))))))
	(_ (call-with-values
	(lambda () (gen-syntax src y r maps ellipsis? mod))
	(lambda (y maps)
	(call-with-values
	(lambda () (k maps))
	(lambda (x maps)
	(values (gen-append x y) maps)))))))))
	((x . y)
	(call-with-values
	(lambda () (gen-syntax src #'x r maps ellipsis? mod))
	(lambda (x maps)
	(call-with-values
	(lambda () (gen-syntax src #'y r maps ellipsis? mod))
	(lambda (y maps) (values (gen-cons x y) maps))))))
	(#(e1 e2 ...)
	(call-with-values
	(lambda ()
	(gen-syntax src #'(e1 e2 ...) r maps ellipsis? mod))
	(lambda (e maps) (values (gen-vector e) maps))))
	(x (eq? (syntax->datum #'x) #nil) (values '(quote #nil) maps))
	(() (values '(quote ()) maps))
	(_ (values `(quote ,e) maps))))))

	(define gen-ref
	(lambda (src var level maps)
	(if (fx= level 0)
	(values var maps)
	(if (null? maps)
	(syntax-violation 'syntax "missing ellipsis" src)
	(call-with-values
	(lambda () (gen-ref src var (fx- level 1) (cdr maps)))
	(lambda (outer-var outer-maps)
	(let ((b (assq outer-var (car maps))))
	(if b
	(values (cdr b) maps)
	(let ((inner-var (gen-var 'tmp)))
	(values inner-var
	(cons (cons (cons outer-var inner-var)
	(car maps))
	outer-maps)))))))))))

	(define gen-mappend
	(lambda (e map-env)
	`(apply (primitive append) ,(gen-map e map-env))))

	(define gen-map
	(lambda (e map-env)
	(let ((formals (map cdr map-env))
	(actuals (map (lambda (x) `(ref ,(car x))) map-env)))
	(cond
	((eq? (car e) 'ref)
	;; identity map equivalence:
	;; (map (lambda (x) x) y) == y
	(car actuals))
	((and-map
	(lambda (x) (and (eq? (car x) 'ref) (memq (cadr x) formals)))
	(cdr e))
	;; eta map equivalence:
	;; (map (lambda (x ...) (f x ...)) y ...) == (map f y ...)
	`(map (primitive ,(car e))
	,@(map (let ((r (map cons formals actuals)))
	(lambda (x) (cdr (assq (cadr x) r))))
	(cdr e))))
	(else `(map (lambda ,formals ,e) ,@actuals))))))

	(define gen-cons
	(lambda (x y)
	(case (car y)
	((quote)
	(if (eq? (car x) 'quote)
	`(quote (,(cadr x) . ,(cadr y)))
	(if (eq? (cadr y) '())
	`(list ,x)
	`(cons ,x ,y))))
	((list) `(list ,x ,@(cdr y)))
	(else `(cons ,x ,y)))))

	(define gen-append
	(lambda (x y)
	(if (equal? y '(quote ()))
	x
	`(append ,x ,y))))

	(define gen-vector
	(lambda (x)
	(cond
	((eq? (car x) 'list) `(vector ,@(cdr x)))
	((eq? (car x) 'quote) `(quote #(,@(cadr x))))
	(else `(list->vector ,x)))))


	(define regen
	(lambda (x)
	(case (car x)
	((ref) (build-lexical-reference 'value no-source (cadr x) (cadr x)))
	((primitive) (build-primref no-source (cadr x)))
	((quote) (build-data no-source (cadr x)))
	((lambda)
	(if (list? (cadr x))
	(build-simple-lambda no-source (cadr x) #f (cadr x) '() (regen (caddr x)))
	(error "how did we get here" x)))
	(else (build-primcall no-source (car x) (map regen (cdr x)))))))

	(lambda (e r w s mod)
	(let ((e (source-wrap e w s mod)))
	(syntax-case e ()
	((_ x)
	(call-with-values
	(lambda () (gen-syntax e #'x r '() ellipsis? mod))
	(lambda (e maps) (regen e))))
	(_ (syntax-violation 'syntax "bad `syntax' form" e)))))))

	(global-extend 'core 'lambda
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ args e1 e2 ...)
	(call-with-values (lambda () (lambda-formals #'args))
	(lambda (req opt rest kw)
	(let lp ((body #'(e1 e2 ...)) (meta '()))
	(syntax-case body ()
	((docstring e1 e2 ...) (string? (syntax->datum #'docstring))
	(lp #'(e1 e2 ...)
	(append meta
	`((documentation
	. ,(syntax->datum #'docstring))))))
	((#((k . v) ...) e1 e2 ...)
	(lp #'(e1 e2 ...)
	(append meta (syntax->datum #'((k . v) ...)))))
	(_ (expand-simple-lambda e r w s mod req rest meta body)))))))
	(_ (syntax-violation 'lambda "bad lambda" e)))))

	(global-extend 'core 'lambda*
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ args e1 e2 ...)
	(call-with-values
	(lambda ()
	(expand-lambda-case e r w s mod
	lambda*-formals #'((args e1 e2 ...))))
	(lambda (meta lcase)
	(build-case-lambda s meta lcase))))
	(_ (syntax-violation 'lambda "bad lambda*" e)))))

	(global-extend 'core 'case-lambda
	(lambda (e r w s mod)
	(define (build-it meta clauses)
	(call-with-values
	(lambda ()
	(expand-lambda-case e r w s mod
	lambda-formals
	clauses))
	(lambda (meta* lcase)
	(build-case-lambda s (append meta meta*) lcase))))
	(syntax-case e ()
	((_ (args e1 e2 ...) ...)
	(build-it '() #'((args e1 e2 ...) ...)))
	((_ docstring (args e1 e2 ...) ...)
	(string? (syntax->datum #'docstring))
	(build-it `((documentation
	. ,(syntax->datum #'docstring)))
	#'((args e1 e2 ...) ...)))
	(_ (syntax-violation 'case-lambda "bad case-lambda" e)))))

	(global-extend 'core 'case-lambda*
	(lambda (e r w s mod)
	(define (build-it meta clauses)
	(call-with-values
	(lambda ()
	(expand-lambda-case e r w s mod
	lambda*-formals
	clauses))
	(lambda (meta* lcase)
	(build-case-lambda s (append meta meta*) lcase))))
	(syntax-case e ()
	((_ (args e1 e2 ...) ...)
	(build-it '() #'((args e1 e2 ...) ...)))
	((_ docstring (args e1 e2 ...) ...)
	(string? (syntax->datum #'docstring))
	(build-it `((documentation
	. ,(syntax->datum #'docstring)))
	#'((args e1 e2 ...) ...)))
	(_ (syntax-violation 'case-lambda "bad case-lambda*" e)))))

	(global-extend 'core 'with-ellipsis
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ dots e1 e2 ...)
	(id? #'dots)
	(let ((id (if (symbol? #'dots)
	'#{ $sc-ellipsis }#
	(make-syntax '#{ $sc-ellipsis }#
	(syntax-wrap #'dots)
	(syntax-module #'dots)
	(syntax-sourcev #'dots)))))
	(let ((ids (list id))
	(labels (list (gen-label)))
	(bindings (list (make-binding 'ellipsis (source-wrap #'dots w s mod)))))
	(let ((nw (make-binding-wrap ids labels w))
	(nr (extend-env labels bindings r)))
	(expand-body #'(e1 e2 ...) (source-wrap e nw s mod) nr nw mod)))))
	(_ (syntax-violation 'with-ellipsis "bad syntax"
	(source-wrap e w s mod))))))

	(global-extend 'core 'let
	(let ()
	(define (expand-let e r w s mod constructor ids vals exps)
	(if (not (valid-bound-ids? ids))
	(syntax-violation 'let "duplicate bound variable" e)
	(let ((labels (gen-labels ids))
	(new-vars (map gen-var ids)))
	(let ((nw (make-binding-wrap ids labels w))
	(nr (extend-var-env labels new-vars r)))
	(constructor s
	(map syntax->datum ids)
	new-vars
	(map (lambda (x) (expand x r w mod)) vals)
	(expand-body exps (source-wrap e nw s mod)
	nr nw mod))))))
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ ((id val) ...) e1 e2 ...)
	(and-map id? #'(id ...))
	(expand-let e r w s mod
	build-let
	#'(id ...)
	#'(val ...)
	#'(e1 e2 ...)))
	((_ f ((id val) ...) e1 e2 ...)
	(and (id? #'f) (and-map id? #'(id ...)))
	(expand-let e r w s mod
	build-named-let
	#'(f id ...)
	#'(val ...)
	#'(e1 e2 ...)))
	(_ (syntax-violation 'let "bad let" (source-wrap e w s mod)))))))


	(global-extend 'core 'letrec
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ ((id val) ...) e1 e2 ...)
	(and-map id? #'(id ...))
	(let ((ids #'(id ...)))
	(if (not (valid-bound-ids? ids))
	(syntax-violation 'letrec "duplicate bound variable" e)
	(let ((labels (gen-labels ids))
	(new-vars (map gen-var ids)))
	(let ((w (make-binding-wrap ids labels w))
	(r (extend-var-env labels new-vars r)))
	(build-letrec s #f
	(map syntax->datum ids)
	new-vars
	(map (lambda (x) (expand x r w mod)) #'(val ...))
	(expand-body #'(e1 e2 ...)
	(source-wrap e w s mod) r w mod)))))))
	(_ (syntax-violation 'letrec "bad letrec" (source-wrap e w s mod))))))


	(global-extend 'core 'letrec*
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ ((id val) ...) e1 e2 ...)
	(and-map id? #'(id ...))
	(let ((ids #'(id ...)))
	(if (not (valid-bound-ids? ids))
	(syntax-violation 'letrec* "duplicate bound variable" e)
	(let ((labels (gen-labels ids))
	(new-vars (map gen-var ids)))
	(let ((w (make-binding-wrap ids labels w))
	(r (extend-var-env labels new-vars r)))
	(build-letrec s #t
	(map syntax->datum ids)
	new-vars
	(map (lambda (x) (expand x r w mod)) #'(val ...))
	(expand-body #'(e1 e2 ...)
	(source-wrap e w s mod) r w mod)))))))
	(_ (syntax-violation 'letrec* "bad letrec*" (source-wrap e w s mod))))))


	(global-extend
	'core 'set!
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ id val)
	(id? #'id)
	(call-with-values
	(lambda () (resolve-identifier #'id w r mod #t))
	(lambda (type value id-mod)
	(case type
	((lexical)
	(build-lexical-assignment s (syntax->datum #'id) value
	(expand #'val r w mod)))
	((global)
	(build-global-assignment s value (expand #'val r w mod) id-mod))
	((macro)
	(if (procedure-property value 'variable-transformer)
	;; As syntax-type does, call expand-macro with
	;; the mod of the expression. Hmm.
	(expand (expand-macro value e r w s #f mod) r empty-wrap mod)
	(syntax-violation 'set! "not a variable transformer"
	(wrap e w mod)
	(wrap #'id w id-mod))))
	((displaced-lexical)
	(syntax-violation 'set! "identifier out of context"
	(wrap #'id w mod)))
	(else
	(syntax-violation 'set! "bad set!" (source-wrap e w s mod)))))))
	((_ (head tail ...) val)
	(call-with-values
	(lambda () (syntax-type #'head r empty-wrap no-source #f mod #t))
	(lambda (type value ee* ee ww ss modmod)
	(case type
	((module-ref)
	(let ((val (expand #'val r w mod)))
	(call-with-values (lambda () (value #'(head tail ...) r w mod))
	(lambda (e r w s* mod)
	(syntax-case e ()
	(e (id? #'e)
	(build-global-assignment s (syntax->datum #'e)
	val mod)))))))
	(else
	(build-call s
	(expand #'(setter head) r w mod)
	(map (lambda (e) (expand e r w mod))
	#'(tail ... val))))))))
	(_ (syntax-violation 'set! "bad set!" (source-wrap e w s mod))))))

	(global-extend 'module-ref '@
	(lambda (e r w mod)
	(syntax-case e ()
	((_ (mod ...) id)
	(and (and-map id? #'(mod ...)) (id? #'id))
	;; Strip the wrap from the identifier and return top-wrap
	;; so that the identifier will not be captured by lexicals.
	(values (syntax->datum #'id) r top-wrap #f
	(syntax->datum
	#'(public mod ...)))))))

	(global-extend 'module-ref '@@
	(lambda (e r w mod)
	(define remodulate
	(lambda (x mod)
	(cond ((pair? x)
	(cons (remodulate (car x) mod)
	(remodulate (cdr x) mod)))
	((syntax? x)
	(make-syntax
	(remodulate (syntax-expression x) mod)
	(syntax-wrap x)
	;; hither the remodulation
	mod
	(syntax-sourcev x)))
	((vector? x)
	(let* ((n (vector-length x)) (v (make-vector n)))
	(do ((i 0 (fx+ i 1)))
	((fx= i n) v)
	(vector-set! v i (remodulate (vector-ref x i) mod)))))
	(else x))))
	(syntax-case e (@@ primitive)
	((_ primitive id)
	(and (id? #'id)
	(equal? (cdr (or (and (syntax? #'id)
	(syntax-module #'id))
	mod))
	'(guile)))
	;; Strip the wrap from the identifier and return top-wrap
	;; so that the identifier will not be captured by lexicals.
	(values (syntax->datum #'id) r top-wrap #f '(primitive)))
	((_ (mod ...) id)
	(and (and-map id? #'(mod ...)) (id? #'id))
	;; Strip the wrap from the identifier and return top-wrap
	;; so that the identifier will not be captured by lexicals.
	(values (syntax->datum #'id) r top-wrap #f
	(syntax->datum
	#'(private mod ...))))
	((_ @@ (mod ...) exp)
	(and-map id? #'(mod ...))
	;; This is a special syntax used to support R6RS library forms.
	;; Unlike the syntax above, the last item is not restricted to
	;; be a single identifier, and the syntax objects are kept
	;; intact, with only their module changed.
	(let ((mod (syntax->datum #'(private mod ...))))
	(values (remodulate #'exp mod)
	r w (source-annotation #'exp)
	mod))))))

	(global-extend 'core 'if
	(lambda (e r w s mod)
	(syntax-case e ()
	((_ test then)
	(build-conditional
	s
	(expand #'test r w mod)
	(expand #'then r w mod)
	(build-void no-source)))
	((_ test then else)
	(build-conditional
	s
	(expand #'test r w mod)
	(expand #'then r w mod)
	(expand #'else r w mod))))))

	(global-extend 'begin 'begin '())

	(global-extend 'define 'define '())

	(global-extend 'define-syntax 'define-syntax '())
	(global-extend 'define-syntax-parameter 'define-syntax-parameter '())

	(global-extend 'eval-when 'eval-when '())

	(global-extend 'core 'syntax-case
	(let ()
	(define convert-pattern
	;; accepts pattern & keys
	;; returns $sc-dispatch pattern & ids
	(lambda (pattern keys ellipsis?)
	(define cvt*
	(lambda (p* n ids)
	(syntax-case p* ()
	((x . y)
	(call-with-values
	(lambda () (cvt* #'y n ids))
	(lambda (y ids)
	(call-with-values
	(lambda () (cvt #'x n ids))
	(lambda (x ids)
	(values (cons x y) ids))))))
	(_ (cvt p* n ids)))))

	(define (v-reverse x)
	(let loop ((r '()) (x x))
	(if (not (pair? x))
	(values r x)
	(loop (cons (car x) r) (cdr x)))))

	(define cvt
	(lambda (p n ids)
	(if (id? p)
	(cond
	((bound-id-member? p keys)
	(values (vector 'free-id p) ids))
	((free-id=? p #'_)
	(values '_ ids))
	(else
	(values 'any (cons (cons p n) ids))))
	(syntax-case p ()
	((x dots)
	(ellipsis? (syntax dots))
	(call-with-values
	(lambda () (cvt (syntax x) (fx+ n 1) ids))
	(lambda (p ids)
	(values (if (eq? p 'any) 'each-any (vector 'each p))
	ids))))
	((x dots . ys)
	(ellipsis? (syntax dots))
	(call-with-values
	(lambda () (cvt* (syntax ys) n ids))
	(lambda (ys ids)
	(call-with-values
	(lambda () (cvt (syntax x) (+ n 1) ids))
	(lambda (x ids)
	(call-with-values
	(lambda () (v-reverse ys))
	(lambda (ys e)
	(values `#(each+ ,x ,ys ,e)
	ids))))))))
	((x . y)
	(call-with-values
	(lambda () (cvt (syntax y) n ids))
	(lambda (y ids)
	(call-with-values
	(lambda () (cvt (syntax x) n ids))
	(lambda (x ids)
	(values (cons x y) ids))))))
	(() (values '() ids))
	(#(x ...)
	(call-with-values
	(lambda () (cvt (syntax (x ...)) n ids))
	(lambda (p ids) (values (vector 'vector p) ids))))
	(x (values (vector 'atom (strip p)) ids))))))
	(cvt pattern 0 '())))

	(define build-dispatch-call
	(lambda (pvars exp y r mod)
	(let ((ids (map car pvars)) (levels (map cdr pvars)))
	(let ((labels (gen-labels ids)) (new-vars (map gen-var ids)))
	(build-primcall
	no-source
	'apply
	(list (build-simple-lambda no-source (map syntax->datum ids) #f new-vars '()
	(expand exp
	(extend-env
	labels
	(map (lambda (var level)
	(make-binding 'syntax `(,var . ,level)))
	new-vars
	(map cdr pvars))
	r)
	(make-binding-wrap ids labels empty-wrap)
	mod))
	y))))))

	(define gen-clause
	(lambda (x keys clauses r pat fender exp mod)
	(call-with-values
	(lambda () (convert-pattern pat keys (lambda (e) (ellipsis? e r mod))))
	(lambda (p pvars)
	(cond
	((not (and-map (lambda (x) (not (ellipsis? (car x) r mod))) pvars))
	(syntax-violation 'syntax-case "misplaced ellipsis" pat))
	((not (distinct-bound-ids? (map car pvars)))
	(syntax-violation 'syntax-case "duplicate pattern variable" pat))
	(else
	(let ((y (gen-var 'tmp)))
	;; fat finger binding and references to temp variable y
	(build-call no-source
	(build-simple-lambda no-source (list 'tmp) #f (list y) '()
	(let ((y (build-lexical-reference 'value no-source
	'tmp y)))
	(build-conditional no-source
	(syntax-case fender ()
	(#t y)
	(_ (build-conditional no-source
	y
	(build-dispatch-call pvars fender y r mod)
	(build-data no-source #f))))
	(build-dispatch-call pvars exp y r mod)
	(gen-syntax-case x keys clauses r mod))))
	(list (if (eq? p 'any)
	(build-primcall no-source 'list (list x))
	(build-primcall no-source '$sc-dispatch
	(list x (build-data no-source p)))))))))))))

	(define gen-syntax-case
	(lambda (x keys clauses r mod)
	(if (null? clauses)
	(build-primcall no-source 'syntax-violation
	(list (build-data no-source #f)
	(build-data no-source
	"source expression failed to match any pattern")
	x))
	(syntax-case (car clauses) ()
	((pat exp)
	(if (and (id? #'pat)
	(and-map (lambda (x) (not (free-id=? #'pat x)))
	(cons #'(... ...) keys)))
	(if (free-id=? #'pat #'_)
	(expand #'exp r empty-wrap mod)
	(let ((labels (list (gen-label)))
	(var (gen-var #'pat)))
	(build-call no-source
	(build-simple-lambda
	no-source (list (syntax->datum #'pat)) #f (list var)
	'()
	(expand #'exp
	(extend-env labels
	(list (make-binding 'syntax `(,var . 0)))
	r)
	(make-binding-wrap #'(pat)
	labels empty-wrap)
	mod))
	(list x))))
	(gen-clause x keys (cdr clauses) r
	#'pat #t #'exp mod)))
	((pat fender exp)
	(gen-clause x keys (cdr clauses) r
	#'pat #'fender #'exp mod))
	(_ (syntax-violation 'syntax-case "invalid clause"
	(car clauses)))))))

	(lambda (e r w s mod)
	(let ((e (source-wrap e w s mod)))
	(syntax-case e ()
	((_ val (key ...) m ...)
	(if (and-map (lambda (x) (and (id? x) (not (ellipsis? x r mod))))
	#'(key ...))
	(let ((x (gen-var 'tmp)))
	;; fat finger binding and references to temp variable x
	(build-call s
	(build-simple-lambda no-source (list 'tmp) #f (list x) '()
	(gen-syntax-case (build-lexical-reference 'value no-source
	'tmp x)
	#'(key ...) #'(m ...)
	r
	mod))
	(list (expand #'val r empty-wrap mod))))
	(syntax-violation 'syntax-case "invalid literals list" e))))))))

	;; The portable macroexpand seeds expand-top's mode m with 'e (for
	;; evaluating) and esew (which stands for "eval syntax expanders
	;; when") with '(eval). In Chez Scheme, m is set to 'c instead of e
	;; if we are compiling a file, and esew is set to
	;; (eval-syntactic-expanders-when), which defaults to the list
	;; '(compile load eval). This means that, by default, top-level
	;; syntactic definitions are evaluated immediately after they are
	;; expanded, and the expanded definitions are also residualized into
	;; the object file if we are compiling a file.
	(set! macroexpand
	(lambda* (x #:optional (m 'e) (esew '(eval)))
	(define (unstrip x)
	(define (annotate result)
	(let ((props (source-properties x)))
	(if (pair? props)
	(datum->syntax #f result #:source props)
	result)))
	(cond
	((pair? x)
	(annotate (cons (unstrip (car x)) (unstrip (cdr x)))))
	((vector? x)
	(let ((v (make-vector (vector-length x))))
	(annotate (list->vector (map unstrip (vector->list x))))))
	((syntax? x) x)
	(else (annotate x))))
	(expand-top-sequence (list (unstrip x)) null-env top-wrap #f m esew
	(cons 'hygiene (module-name (current-module))))))

	(set! identifier?
	(lambda (x)
	(nonsymbol-id? x)))

	(set! datum->syntax
	(lambda* (id datum #:key source)
	(define (props->sourcev alist)
	(and (pair? alist)
	(vector (assq-ref alist 'filename)
	(assq-ref alist 'line)
	(assq-ref alist 'column))))
	(make-syntax datum
	(if id
	(syntax-wrap id)
	empty-wrap)
	(if id
	(syntax-module id)
	#f)
	(cond
	((not source)
	(props->sourcev (source-properties datum)))
	((and (list? source) (and-map pair? source))
	(props->sourcev source))
	((and (vector? source) (= 3 (vector-length source)))
	source)
	(else (syntax-sourcev source))))))

	(set! syntax->datum
	;; accepts any object, since syntax objects may consist partially
	;; or entirely of unwrapped, nonsymbolic data
	(lambda (x)
	(strip x)))

	(set! generate-temporaries
	(lambda (ls)
	(arg-check list? ls 'generate-temporaries)
	(let ((mod (cons 'hygiene (module-name (current-module)))))
	(map (lambda (x)
	(wrap (module-gensym "t") top-wrap mod))
	ls))))

	(set! free-identifier=?
	(lambda (x y)
	(arg-check nonsymbol-id? x 'free-identifier=?)
	(arg-check nonsymbol-id? y 'free-identifier=?)
	(free-id=? x y)))

	(set! bound-identifier=?
	(lambda (x y)
	(arg-check nonsymbol-id? x 'bound-identifier=?)
	(arg-check nonsymbol-id? y 'bound-identifier=?)
	(bound-id=? x y)))

	(set! syntax-violation
	(lambda* (who message form #:optional subform)
	(arg-check (lambda (x) (or (not x) (string? x) (symbol? x)))
	who 'syntax-violation)
	(arg-check string? message 'syntax-violation)
	(throw 'syntax-error who message
	(sourcev->alist
	(or (source-annotation subform)
	(source-annotation form)))
	(strip form)
	(strip subform))))

	(let ()
	(define (%syntax-module id)
	(arg-check nonsymbol-id? id 'syntax-module)
	(let ((mod (syntax-module id)))
	(and mod
	(not (equal? mod '(primitive)))
	(cdr mod))))

	(define* (syntax-local-binding id #:key (resolve-syntax-parameters? #t))
	(arg-check nonsymbol-id? id 'syntax-local-binding)
	(with-transformer-environment
	(lambda (e r w s rib mod)
	(define (strip-anti-mark w)
	(let ((ms (wrap-marks w)) (s (wrap-subst w)))
	(if (and (pair? ms) (eq? (car ms) the-anti-mark))
	;; output is from original text
	(make-wrap (cdr ms) (if rib (cons rib (cdr s)) (cdr s)))
	;; output introduced by macro
	(make-wrap ms (if rib (cons rib s) s)))))
	(call-with-values (lambda ()
	(resolve-identifier
	(syntax-expression id)
	(strip-anti-mark (syntax-wrap id))
	r
	(or (syntax-module id) mod)
	resolve-syntax-parameters?))
	(lambda (type value mod)
	(case type
	((lexical) (values 'lexical value))
	((macro) (values 'macro value))
	((syntax-parameter) (values 'syntax-parameter value))
	((syntax) (values 'pattern-variable value))
	((displaced-lexical) (values 'displaced-lexical #f))
	((global)
	(if (equal? mod '(primitive))
	(values 'primitive value)
	(values 'global (cons value (cdr mod)))))
	((ellipsis)
	(values 'ellipsis
	(wrap-syntax value (anti-mark (syntax-wrap value))
	mod)))
	(else (values 'other #f))))))))

	(define (syntax-locally-bound-identifiers id)
	(arg-check nonsymbol-id? id 'syntax-locally-bound-identifiers)
	(locally-bound-identifiers (syntax-wrap id)
	(syntax-module id)))

	;; Using define! instead of set! to avoid warnings at
	;; compile-time, after the variables are stolen away into (system
	;; syntax). See the end of boot-9.scm.
	;;
	(define! '%syntax-module %syntax-module)
	(define! 'syntax-local-binding syntax-local-binding)
	(define! 'syntax-locally-bound-identifiers syntax-locally-bound-identifiers))

	;; $sc-dispatch expects an expression and a pattern. If the expression
	;; matches the pattern a list of the matching expressions for each
	;; "any" is returned. Otherwise, #f is returned. (This use of #f will
	;; not work on r4rs implementations that violate the ieee requirement
	;; that #f and () be distinct.)

	;; The expression is matched with the pattern as follows:

	;; pattern: matches:
	;; () empty list
	;; any anything
	;; (<pattern>1 . <pattern>2) (<pattern>1 . <pattern>2)
	;; each-any (any*)
	;; #(free-id <key>) <key> with free-identifier=?
	;; #(each <pattern>) (<pattern>*)
	;; #(each+ p1 (p2_1 ... p2_n) p3) (p1* (p2_n ... p2_1) . p3)
	;; #(vector <pattern>) (list->vector <pattern>)
	;; #(atom <object>) <object> with "equal?"

	;; Vector cops out to pair under assumption that vectors are rare. If
	;; not, should convert to:
	;; #(vector <pattern>) #(<pattern>)

	(let ()

	(define match-each
	(lambda (e p w mod)
	(cond
	((pair? e)
	(let ((first (match (car e) p w '() mod)))
	(and first
	(let ((rest (match-each (cdr e) p w mod)))
	(and rest (cons first rest))))))
	((null? e) '())
	((syntax? e)
	(match-each (syntax-expression e)
	p
	(join-wraps w (syntax-wrap e))
	(or (syntax-module e) mod)))
	(else #f))))

	(define match-each+
	(lambda (e x-pat y-pat z-pat w r mod)
	(let f ((e e) (w w))
	(cond
	((pair? e)
	(call-with-values (lambda () (f (cdr e) w))
	(lambda (xr* y-pat r)
	(if r
	(if (null? y-pat)
	(let ((xr (match (car e) x-pat w '() mod)))
	(if xr
	(values (cons xr xr*) y-pat r)
	(values #f #f #f)))
	(values
	'()
	(cdr y-pat)
	(match (car e) (car y-pat) w r mod)))
	(values #f #f #f)))))
	((syntax? e)
	(f (syntax-expression e)
	(join-wraps w (syntax-wrap e))))
	(else
	(values '() y-pat (match e z-pat w r mod)))))))

	(define match-each-any
	(lambda (e w mod)
	(cond
	((pair? e)
	(let ((l (match-each-any (cdr e) w mod)))
	(and l (cons (wrap (car e) w mod) l))))
	((null? e) '())
	((syntax? e)
	(match-each-any (syntax-expression e)
	(join-wraps w (syntax-wrap e))
	mod))
	(else #f))))

	(define match-empty
	(lambda (p r)
	(cond
	((null? p) r)
	((eq? p '_) r)
	((eq? p 'any) (cons '() r))
	((pair? p) (match-empty (car p) (match-empty (cdr p) r)))
	((eq? p 'each-any) (cons '() r))
	(else
	(case (vector-ref p 0)
	((each) (match-empty (vector-ref p 1) r))
	((each+) (match-empty (vector-ref p 1)
	(match-empty
	(reverse (vector-ref p 2))
	(match-empty (vector-ref p 3) r))))
	((free-id atom) r)
	((vector) (match-empty (vector-ref p 1) r)))))))

	(define combine
	(lambda (r* r)
	(if (null? (car r*))
	r
	(cons (map car r) (combine (map cdr r) r)))))

	(define match*
	(lambda (e p w r mod)
	(cond
	((null? p) (and (null? e) r))
	((pair? p)
	(and (pair? e) (match (car e) (car p) w
	(match (cdr e) (cdr p) w r mod)
	mod)))
	((eq? p 'each-any)
	(let ((l (match-each-any e w mod))) (and l (cons l r))))
	(else
	(case (vector-ref p 0)
	((each)
	(if (null? e)
	(match-empty (vector-ref p 1) r)
	(let ((l (match-each e (vector-ref p 1) w mod)))
	(and l
	(let collect ((l l))
	(if (null? (car l))
	r
	(cons (map car l) (collect (map cdr l)))))))))
	((each+)
	(call-with-values
	(lambda ()
	(match-each+ e (vector-ref p 1) (vector-ref p 2) (vector-ref p 3) w r mod))
	(lambda (xr* y-pat r)
	(and r
	(null? y-pat)
	(if (null? xr*)
	(match-empty (vector-ref p 1) r)
	(combine xr* r))))))
	((free-id) (and (id? e) (free-id=? (wrap e w mod) (vector-ref p 1)) r))
	((atom) (and (equal? (vector-ref p 1) (strip e)) r))
	((vector)
	(and (vector? e)
	(match (vector->list e) (vector-ref p 1) w r mod))))))))

	(define match
	(lambda (e p w r mod)
	(cond
	((not r) #f)
	((eq? p '_) r)
	((eq? p 'any) (cons (wrap e w mod) r))
	((syntax? e)
	(match*
	(syntax-expression e)
	p
	(join-wraps w (syntax-wrap e))
	r
	(or (syntax-module e) mod)))
	(else (match* e p w r mod)))))

	(set! $sc-dispatch
	(lambda (e p)
	(cond
	((eq? p 'any) (list e))
	((eq? p '_) '())
	((syntax? e)
	(match* (syntax-expression e)
	p (syntax-wrap e) '() (syntax-module e)))
	(else (match* e p empty-wrap '() #f))))))))


	(define-syntax with-syntax
	(lambda (x)
	(syntax-case x ()
	((_ () e1 e2 ...)
	#'(let () e1 e2 ...))
	((_ ((out in)) e1 e2 ...)
	#'(syntax-case in ()
	(out (let () e1 e2 ...))))
	((_ ((out in) ...) e1 e2 ...)
	#'(syntax-case (list in ...) ()
	((out ...) (let () e1 e2 ...)))))))

	(define-syntax syntax-error
	(lambda (x)
	(syntax-case x ()
	;; Extended internal syntax which provides the original form
	;; as the first operand, for improved error reporting.
	((_ (keyword . operands) message arg ...)
	(string? (syntax->datum #'message))
	(syntax-violation (syntax->datum #'keyword)
	(string-join (cons (syntax->datum #'message)
	(map (lambda (x)
	(object->string
	(syntax->datum x)))
	#'(arg ...))))
	(and (syntax->datum #'keyword)
	#'(keyword . operands))))
	;; Standard R7RS syntax
	((_ message arg ...)
	(string? (syntax->datum #'message))
	#'(syntax-error (#f) message arg ...)))))

	(define-syntax syntax-rules
	(lambda (xx)
	(define (expand-clause clause)
	;; Convert a 'syntax-rules' clause into a 'syntax-case' clause.
	(syntax-case clause (syntax-error)
	;; If the template is a 'syntax-error' form, use the extended
	;; internal syntax, which adds the original form as the first
	;; operand for improved error reporting.
	(((keyword . pattern) (syntax-error message arg ...))
	(string? (syntax->datum #'message))
	#'((dummy . pattern) #'(syntax-error (dummy . pattern) message arg ...)))
	;; Normal case
	(((keyword . pattern) template)
	#'((dummy . pattern) #'template))))
	(define (expand-syntax-rules dots keys docstrings clauses)
	(with-syntax
	(((k ...) keys)
	((docstring ...) docstrings)
	((((keyword . pattern) template) ...) clauses)
	((clause ...) (map expand-clause clauses)))
	(with-syntax
	((form #'(lambda (x)
	docstring ... ; optional docstring
	#((macro-type . syntax-rules)
	(patterns pattern ...)) ; embed patterns as procedure metadata
	(syntax-case x (k ...)
	clause ...))))
	(if dots
	(with-syntax ((dots dots))
	#'(with-ellipsis dots form))
	#'form))))
	(syntax-case xx ()
	((_ (k ...) ((keyword . pattern) template) ...)
	(expand-syntax-rules #f #'(k ...) #'() #'(((keyword . pattern) template) ...)))
	((_ (k ...) docstring ((keyword . pattern) template) ...)
	(string? (syntax->datum #'docstring))
	(expand-syntax-rules #f #'(k ...) #'(docstring) #'(((keyword . pattern) template) ...)))
	((_ dots (k ...) ((keyword . pattern) template) ...)
	(identifier? #'dots)
	(expand-syntax-rules #'dots #'(k ...) #'() #'(((keyword . pattern) template) ...)))
	((_ dots (k ...) docstring ((keyword . pattern) template) ...)
	(and (identifier? #'dots) (string? (syntax->datum #'docstring)))
	(expand-syntax-rules #'dots #'(k ...) #'(docstring) #'(((keyword . pattern) template) ...))))))

	(define-syntax define-syntax-rule
	(lambda (x)
	(syntax-case x ()
	((_ (name . pattern) template)
	#'(define-syntax name
	(syntax-rules ()
	((_ . pattern) template))))
	((_ (name . pattern) docstring template)
	(string? (syntax->datum #'docstring))
	#'(define-syntax name
	(syntax-rules ()
	docstring
	((_ . pattern) template)))))))

	(define-syntax let*
	(lambda (x)
	(syntax-case x ()
	((let* ((x v) ...) e1 e2 ...)
	(and-map identifier? #'(x ...))
	(let f ((bindings #'((x v) ...)))
	(if (null? bindings)
	#'(let () e1 e2 ...)
	(with-syntax ((body (f (cdr bindings)))
	(binding (car bindings)))
	#'(let (binding) body))))))))

	(define-syntax quasiquote
	(let ()
	(define (quasi p lev)
	(syntax-case p (unquote quasiquote)
	((unquote p)
	(if (= lev 0)
	#'("value" p)
	(quasicons #'("quote" unquote) (quasi #'(p) (- lev 1)))))
	((quasiquote p) (quasicons #'("quote" quasiquote) (quasi #'(p) (+ lev 1))))
	((p . q)
	(syntax-case #'p (unquote unquote-splicing)
	((unquote p ...)
	(if (= lev 0)
	(quasilist* #'(("value" p) ...) (quasi #'q lev))
	(quasicons
	(quasicons #'("quote" unquote) (quasi #'(p ...) (- lev 1)))
	(quasi #'q lev))))
	((unquote-splicing p ...)
	(if (= lev 0)
	(quasiappend #'(("value" p) ...) (quasi #'q lev))
	(quasicons
	(quasicons #'("quote" unquote-splicing) (quasi #'(p ...) (- lev 1)))
	(quasi #'q lev))))
	(_ (quasicons (quasi #'p lev) (quasi #'q lev)))))
	(#(x ...) (quasivector (vquasi #'(x ...) lev)))
	(p #'("quote" p))))
	(define (vquasi p lev)
	(syntax-case p ()
	((p . q)
	(syntax-case #'p (unquote unquote-splicing)
	((unquote p ...)
	(if (= lev 0)
	(quasilist* #'(("value" p) ...) (vquasi #'q lev))
	(quasicons
	(quasicons #'("quote" unquote) (quasi #'(p ...) (- lev 1)))
	(vquasi #'q lev))))
	((unquote-splicing p ...)
	(if (= lev 0)
	(quasiappend #'(("value" p) ...) (vquasi #'q lev))
	(quasicons
	(quasicons
	#'("quote" unquote-splicing)
	(quasi #'(p ...) (- lev 1)))
	(vquasi #'q lev))))
	(_ (quasicons (quasi #'p lev) (vquasi #'q lev)))))
	(() #'("quote" ()))))
	(define (quasicons x y)
	(with-syntax ((x x) (y y))
	(syntax-case #'y ()
	(("quote" dy)
	(syntax-case #'x ()
	(("quote" dx) #'("quote" (dx . dy)))
	(_ (if (null? #'dy) #'("list" x) #'("list*" x y)))))
	(("list" . stuff) #'("list" x . stuff))
	(("list" . stuff) #'("list" x . stuff))
	(_ #'("list*" x y)))))
	(define (quasiappend x y)
	(syntax-case y ()
	(("quote" ())
	(cond
	((null? x) #'("quote" ()))
	((null? (cdr x)) (car x))
	(else (with-syntax (((p ...) x)) #'("append" p ...)))))
	(_
	(cond
	((null? x) y)
	(else (with-syntax (((p ...) x) (y y)) #'("append" p ... y)))))))
	(define (quasilist* x y)
	(let f ((x x))
	(if (null? x)
	y
	(quasicons (car x) (f (cdr x))))))
	(define (quasivector x)
	(syntax-case x ()
	(("quote" (x ...)) #'("quote" #(x ...)))
	(_
	(let f ((y x) (k (lambda (ls) #`("vector" #,@ls))))
	(syntax-case y ()
	(("quote" (y ...)) (k #'(("quote" y) ...)))
	(("list" y ...) (k #'(y ...)))
	(("list*" y ... z) (f #'z (lambda (ls) (k (append #'(y ...) ls)))))
	(else #`("list->vector" #,x)))))))
	(define (emit x)
	(syntax-case x ()
	(("quote" x) #''x)
	(("list" x ...) #`(list #,@(map emit #'(x ...))))
	;; could emit list* for 3+ arguments if implementation supports
	;; list*
	(("list*" x ... y)
	(let f ((x* #'(x ...)))
	(if (null? x*)
	(emit #'y)
	#`(cons #,(emit (car x)) #,(f (cdr x))))))
	(("append" x ...) #`(append #,@(map emit #'(x ...))))
	(("vector" x ...) #`(vector #,@(map emit #'(x ...))))
	(("list->vector" x) #`(list->vector #,(emit #'x)))
	(("value" x) #'x)))
	(lambda (x)
	(syntax-case x ()
	;; convert to intermediate language, combining introduced (but
	;; not unquoted source) quote expressions where possible and
	;; choosing optimal construction code otherwise, then emit
	;; Scheme code corresponding to the intermediate language forms.
	((_ e) (emit (quasi #'e 0)))))))

	(define call-with-include-port
	(let ((syntax-dirname (lambda (stx)
	(define src (syntax-source stx))
	(define filename (and src (assq-ref src 'filename)))
	(and (string? filename)
	(dirname filename)))))
	(lambda* (filename proc #:key (dirname (syntax-dirname filename)))
	"Like @code{call-with-input-file}, except relative paths are
	searched relative to the @var{dirname} instead of the current working
	directory. Also, @var{filename} can be a syntax object; in that case,
	and if @var{dirname} is not specified, the @code{syntax-source} of
	@var{filename} is used to obtain a base directory for relative file
	names."
	(let* ((filename (syntax->datum filename))
	(p (open-input-file
	(cond ((absolute-file-name? filename)
	filename)
	(dirname
	(in-vicinity dirname filename))
	(else
	(error
	"attempt to include relative file name but could not determine base dir")))))
	(enc (file-encoding p)))

	;; Choose the input encoding deterministically.
	(set-port-encoding! p (or enc "UTF-8"))

	(call-with-values (lambda () (proc p))
	(lambda results
	(close-port p)
	(apply values results)))))))

	(define-syntax include
	(lambda (stx)
	(syntax-case stx ()
	((_ filename)
	(call-with-include-port
	#'filename
	(lambda (p)
	;; In Guile, (cons #'a #'b) is the same as #'(a . b).
	(cons #'begin
	(let lp ()
	(let ((x (read-syntax p)))
	(if (eof-object? x)
	#'()
	(cons (datum->syntax #'filename x) (lp))))))))))))

	(define-syntax include-from-path
	(lambda (x)
	(syntax-case x ()
	((k filename)
	(let ((fn (syntax->datum #'filename)))
	(with-syntax ((fn (datum->syntax
	#'filename
	(canonicalize-path
	(or (%search-load-path fn)
	(syntax-violation 'include-from-path
	"file not found in path"
	x #'filename))))))
	#'(include fn)))))))

	(define-syntax unquote
	(lambda (x)
	(syntax-violation 'unquote
	"expression not valid outside of quasiquote"
	x)))

	(define-syntax unquote-splicing
	(lambda (x)
	(syntax-violation 'unquote-splicing
	"expression not valid outside of quasiquote"
	x)))

	(define (make-variable-transformer proc)
	(if (procedure? proc)
	(let ((trans (lambda (x)
	#((macro-type . variable-transformer))
	(proc x))))
	(set-procedure-property! trans 'variable-transformer #t)
	trans)
	(error "variable transformer not a procedure" proc)))

	(define-syntax identifier-syntax
	(lambda (xx)
	(syntax-case xx (set!)
	((_ e)
	#'(lambda (x)
	#((macro-type . identifier-syntax))
	(syntax-case x ()
	(id
	(identifier? #'id)
	#'e)
	((_ x (... ...))
	#'(e x (... ...))))))
	((_ (id exp1) ((set! var val) exp2))
	(and (identifier? #'id) (identifier? #'var))
	#'(make-variable-transformer
	(lambda (x)
	#((macro-type . variable-transformer))
	(syntax-case x (set!)
	((set! var val) #'exp2)
	((id x (... ...)) #'(exp1 x (... ...)))
	(id (identifier? #'id) #'exp1))))))))

	(define-syntax define*
	(lambda (x)
	(syntax-case x ()
	((_ (id . args) b0 b1 ...)
	#'(define id (lambda* args b0 b1 ...)))
	((_ id val) (identifier? #'id)
	#'(define id val)))))