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guile/module/language/cps/closure-conversion.scm
Andy Wingo c3240d09b2 Unbox indexes of vectors, strings, and structs 
* libguile/vm-engine.c (string-length, string-ref)
  (make-vector, vector-ref, vector-set!)
  (allocate-struct, struct-ref, struct-set!): Take indexes and return
  lengths as untagged u64 values.

* libguile/vm.c (vm_error_not_a_string): New helper.

* module/language/tree-il/compile-cps.scm (convert):
* module/language/cps/constructors.scm (inline-vector):
* module/language/cps/closure-conversion.scm (convert-one): Untag
  arguments to {string,vector,struct}-{ref,set!}, make-vector, and
  allocate-struct.  Tag return values from {string,vector}-length.

* module/language/cps/slot-allocation.scm (compute-var-representations):
  vector-length and string-length define u64 slots.

* module/language/cps/effects-analysis.scm: make-vector no longer causes
  a &type-check effect.

* module/language/cps/types.scm: Update to expect &u64 values for
  lengths and indexes.
2015-12-01 15:42:24 +01:00

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;;; Continuation-passing style (CPS) intermediate language (IL)
;; Copyright (C) 2013, 2014, 2015 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
;;; Commentary:
;;;
;;; This pass converts a CPS term in such a way that no function has any
;;; free variables. Instead, closures are built explicitly with
;;; make-closure primcalls, and free variables are referenced through
;;; the closure.
;;;
;;; Closure conversion also removes any $rec expressions that
;;; contification did not handle. See (language cps) for a further
;;; discussion of $rec.
;;;
;;; Code:
(define-module (language cps closure-conversion)
#:use-module (ice-9 match)
#:use-module ((srfi srfi-1) #:select (fold
filter-map
))
#:use-module (srfi srfi-11)
#:use-module (language cps)
#:use-module (language cps utils)
#:use-module (language cps with-cps)
#:use-module (language cps intmap)
#:use-module (language cps intset)
#:export (convert-closures))
(define (compute-function-bodies conts kfun)
"Compute a map from FUN-LABEL->BODY-LABEL... for all $fun instances in
conts."
(let visit-fun ((kfun kfun) (out empty-intmap))
(let ((body (compute-function-body conts kfun)))
(intset-fold
(lambda (label out)
(match (intmap-ref conts label)
(($ $kargs _ _ ($ $continue _ _ ($ $fun kfun)))
(visit-fun kfun out))
(($ $kargs _ _ ($ $continue _ _ ($ $rec _ _ (($ $fun kfun) ...))))
(fold visit-fun out kfun))
(_ out)))
body
(intmap-add out kfun body)))))
(define (compute-program-body functions)
(intmap-fold (lambda (label body out) (intset-union body out))
functions
empty-intset))
(define (filter-reachable conts functions)
(let ((reachable (compute-program-body functions)))
(intmap-fold
(lambda (label cont out)
(if (intset-ref reachable label)
out
(intmap-remove out label)))
conts conts)))
(define (compute-non-operator-uses conts)
(persistent-intset
(intmap-fold
(lambda (label cont uses)
(define (add-use var uses) (intset-add! uses var))
(define (add-uses vars uses)
(match vars
(() uses)
((var . vars) (add-uses vars (add-use var uses)))))
(match cont
(($ $kargs _ _ ($ $continue _ _ exp))
(match exp
((or ($ $const) ($ $prim) ($ $fun) ($ $rec)) uses)
(($ $values args)
(add-uses args uses))
(($ $call proc args)
(add-uses args uses))
(($ $branch kt ($ $values (arg)))
(add-use arg uses))
(($ $branch kt ($ $primcall name args))
(add-uses args uses))
(($ $primcall name args)
(add-uses args uses))
(($ $prompt escape? tag handler)
(add-use tag uses))))
(_ uses)))
conts
empty-intset)))
(define (compute-singly-referenced-labels conts body)
(define (add-ref label single multiple)
(define (ref k single multiple)
(if (intset-ref single k)
(values single (intset-add! multiple k))
(values (intset-add! single k) multiple)))
(define (ref0) (values single multiple))
(define (ref1 k) (ref k single multiple))
(define (ref2 k k*)
(if k*
(let-values (((single multiple) (ref k single multiple)))
(ref k* single multiple))
(ref1 k)))
(match (intmap-ref conts label)
(($ $kreceive arity k) (ref1 k))
(($ $kfun src meta self ktail kclause) (ref2 ktail kclause))
(($ $ktail) (ref0))
(($ $kclause arity kbody kalt) (ref2 kbody kalt))
(($ $kargs names syms ($ $continue k src exp))
(ref2 k (match exp (($ $branch k) k) (($ $prompt _ _ k) k) (_ #f))))))
(let*-values (((single multiple) (values empty-intset empty-intset))
((single multiple) (intset-fold add-ref body single multiple)))
(intset-subtract (persistent-intset single)
(persistent-intset multiple))))
(define (compute-function-names conts functions)
"Compute a map of FUN-LABEL->BOUND-VAR... for each labelled function
whose bound vars we know."
(define (add-named-fun var kfun out)
(let ((self (match (intmap-ref conts kfun)
(($ $kfun src meta self) self))))
(intmap-add out kfun (intset var self))))
(intmap-fold
(lambda (label body out)
(let ((single (compute-singly-referenced-labels conts body)))
(intset-fold
(lambda (label out)
(match (intmap-ref conts label)
(($ $kargs _ _ ($ $continue k _ ($ $fun kfun)))
(if (intset-ref single k)
(match (intmap-ref conts k)
(($ $kargs (_) (var)) (add-named-fun var kfun out))
(_ out))
out))
(($ $kargs _ _ ($ $continue k _ ($ $rec _ vars (($ $fun kfun) ...))))
(unless (intset-ref single k)
(error "$rec continuation has multiple predecessors??"))
(fold add-named-fun out vars kfun))
(_ out)))
body
out)))
functions
empty-intmap))
(define (compute-well-known-functions conts bound->label)
"Compute a set of labels indicating the well-known functions in
@var{conts}. A well-known function is a function whose bound names we
know and which is never used in a non-operator position."
(intset-subtract
(persistent-intset
(intmap-fold (lambda (bound label candidates)
(intset-add! candidates label))
bound->label
empty-intset))
(persistent-intset
(intset-fold (lambda (var not-well-known)
(match (intmap-ref bound->label var (lambda (_) #f))
(#f not-well-known)
(label (intset-add! not-well-known label))))
(compute-non-operator-uses conts)
empty-intset))))
(define (intset-cons i set)
(intset-add set i))
(define (compute-shared-closures conts well-known)
"Compute a map LABEL->VAR indicating the sets of functions that will
share a closure. If a functions's label is in the map, it is shared.
The entries indicate the var of the shared closure, which will be one of
the bound vars of the closure."
(intmap-fold
(lambda (label cont out)
(match cont
(($ $kargs _ _
($ $continue _ _ ($ $rec names vars (($ $fun kfuns) ...))))
;; The split-rec pass should have ensured that this $rec forms a
;; strongly-connected component, so the free variables from all of
;; the functions will be alive as long as one of the closures is
;; alive. For that reason we can consider storing all free
;; variables in one closure and sharing it.
(let* ((kfuns-set (fold intset-cons empty-intset kfuns))
(unknown-kfuns (intset-subtract kfuns-set well-known)))
(cond
((or (eq? empty-intset kfuns-set) (trivial-intset kfuns-set))
;; There is only zero or one function bound here. Trivially
;; shared already.
out)
((eq? empty-intset unknown-kfuns)
;; All functions are well-known; we can share a closure. Use
;; the first bound variable.
(let ((closure (car vars)))
(intset-fold (lambda (kfun out)
(intmap-add out kfun closure))
kfuns-set out)))
((trivial-intset unknown-kfuns)
=> (lambda (unknown-kfun)
;; Only one function is not-well-known. Use that
;; function's closure as the shared closure.
(let ((closure (assq-ref (map cons kfuns vars) unknown-kfun)))
(intset-fold (lambda (kfun out)
(intmap-add out kfun closure))
kfuns-set out))))
(else
;; More than one not-well-known function means we need more
;; than one proper closure, so we can't share.
out))))
(_ out)))
conts
empty-intmap))
(define* (rewrite-shared-closure-calls cps functions label->bound shared kfun)
"Rewrite CPS such that every call to a function with a shared closure
instead is a $callk to that label, but passing the shared closure as the
proc argument. For recursive calls, use the appropriate 'self'
variable, if possible. Also rewrite uses of the non-well-known but
shared closures to use the appropriate 'self' variable, if possible."
;; env := var -> (var . label)
(define (rewrite-fun kfun cps env)
(define (subst var)
(match (intmap-ref env var (lambda (_) #f))
(#f var)
((var . label) var)))
(define (rename-exp label cps names vars k src exp)
(intmap-replace!
cps label
(build-cont
($kargs names vars
($continue k src
,(rewrite-exp exp
((or ($ $const) ($ $prim)) ,exp)
(($ $call proc args)
,(let ((args (map subst args)))
(rewrite-exp (intmap-ref env proc (lambda (_) #f))
(#f ($call proc ,args))
((closure . label) ($callk label closure ,args)))))
(($ $primcall name args)
($primcall name ,(map subst args)))
(($ $branch k ($ $values (arg)))
($branch k ($values ((subst arg)))))
(($ $branch k ($ $primcall name args))
($branch k ($primcall name ,(map subst args))))
(($ $values args)
($values ,(map subst args)))
(($ $prompt escape? tag handler)
($prompt escape? (subst tag) handler))))))))
(define (visit-exp label cps names vars k src exp)
(define (compute-env label bound self rec-bound rec-labels env)
(define (add-bound-var bound label env)
(intmap-add env bound (cons self label) (lambda (old new) new)))
(if (intmap-ref shared label (lambda (_) #f))
;; Within a function with a shared closure, rewrite
;; references to bound vars to use the "self" var.
(fold add-bound-var env rec-bound rec-labels)
;; Otherwise be sure to use "self" references in any
;; closure.
(add-bound-var bound label env)))
(match exp
(($ $fun label)
(rewrite-fun label cps env))
(($ $rec names vars (($ $fun labels) ...))
(fold (lambda (label var cps)
(match (intmap-ref cps label)
(($ $kfun src meta self)
(rewrite-fun label cps
(compute-env label var self vars labels
env)))))
cps labels vars))
(_ (rename-exp label cps names vars k src exp))))
(define (rewrite-cont label cps)
(match (intmap-ref cps label)
(($ $kargs names vars ($ $continue k src exp))
(visit-exp label cps names vars k src exp))
(_ cps)))
(intset-fold rewrite-cont (intmap-ref functions kfun) cps))
;; Initial environment is bound-var -> (shared-var . label) map for
;; functions with shared closures.
(let ((env (intmap-fold (lambda (label shared env)
(intset-fold (lambda (bound env)
(intmap-add env bound
(cons shared label)))
(intset-remove
(intmap-ref label->bound label)
(match (intmap-ref cps label)
(($ $kfun src meta self) self)))
env))
shared
empty-intmap)))
(persistent-intmap (rewrite-fun kfun cps env))))
(define (compute-free-vars conts kfun shared)
"Compute a FUN-LABEL->FREE-VAR... map describing all free variable
references."
(define (add-def var defs) (intset-add! defs var))
(define (add-defs vars defs)
(match vars
(() defs)
((var . vars) (add-defs vars (add-def var defs)))))
(define (add-use var uses)
(intset-add! uses var))
(define (add-uses vars uses)
(match vars
(() uses)
((var . vars) (add-uses vars (add-use var uses)))))
(define (visit-nested-funs body)
(intset-fold
(lambda (label out)
(match (intmap-ref conts label)
(($ $kargs _ _ ($ $continue _ _
($ $fun kfun)))
(intmap-union out (visit-fun kfun)))
(($ $kargs _ _ ($ $continue _ _
($ $rec _ _ (($ $fun labels) ...))))
(let* ((out (fold (lambda (kfun out)
(intmap-union out (visit-fun kfun)))
out labels))
(free (fold (lambda (kfun free)
(intset-union free (intmap-ref out kfun)))
empty-intset labels)))
(fold (lambda (kfun out)
;; For functions that share a closure, the free
;; variables for one will be the union of the free
;; variables for all.
(if (intmap-ref shared kfun (lambda (_) #f))
(intmap-replace out kfun free)
out))
out
labels)))
(_ out)))
body
empty-intmap))
(define (visit-fun kfun)
(let* ((body (compute-function-body conts kfun))
(free (visit-nested-funs body)))
(call-with-values
(lambda ()
(intset-fold
(lambda (label defs uses)
(match (intmap-ref conts label)
(($ $kargs names vars ($ $continue k src exp))
(values
(add-defs vars defs)
(match exp
((or ($ $const) ($ $prim)) uses)
(($ $fun kfun)
(intset-union (persistent-intset uses)
(intmap-ref free kfun)))
(($ $rec names vars (($ $fun kfun) ...))
(fold (lambda (kfun uses)
(intset-union (persistent-intset uses)
(intmap-ref free kfun)))
uses kfun))
(($ $values args)
(add-uses args uses))
(($ $call proc args)
(add-use proc (add-uses args uses)))
(($ $callk label proc args)
(add-use proc (add-uses args uses)))
(($ $branch kt ($ $values (arg)))
(add-use arg uses))
(($ $branch kt ($ $primcall name args))
(add-uses args uses))
(($ $primcall name args)
(add-uses args uses))
(($ $prompt escape? tag handler)
(add-use tag uses)))))
(($ $kfun src meta self)
(values (add-def self defs) uses))
(_ (values defs uses))))
body empty-intset empty-intset))
(lambda (defs uses)
(intmap-add free kfun (intset-subtract
(persistent-intset uses)
(persistent-intset defs)))))))
(visit-fun kfun))
(define (eliminate-closure? label free-vars)
(eq? (intmap-ref free-vars label) empty-intset))
(define (closure-label label shared bound->label)
(cond
((intmap-ref shared label (lambda (_) #f))
=> (lambda (closure)
(intmap-ref bound->label closure)))
(else label)))
(define (closure-alias label well-known free-vars)
(and (intset-ref well-known label)
(trivial-intset (intmap-ref free-vars label))))
(define (prune-free-vars free-vars bound->label well-known shared)
"Given the label->bound-var map @var{free-vars}, remove free variables
that are known functions with zero free variables, and replace
references to well-known functions with one free variable with that free
variable, until we reach a fixed point on the free-vars map."
(define (prune-free in-label free free-vars)
(intset-fold (lambda (var free)
(match (intmap-ref bound->label var (lambda (_) #f))
(#f free)
(label
(cond
((eliminate-closure? label free-vars)
(intset-remove free var))
((closure-alias (closure-label label shared bound->label)
well-known free-vars)
=> (lambda (alias)
;; If VAR is free in LABEL, then ALIAS must
;; also be free because its definition must
;; precede VAR's definition.
(intset-add (intset-remove free var) alias)))
(else free)))))
free free))
(fixpoint (lambda (free-vars)
(intmap-fold (lambda (label free free-vars)
(intmap-replace free-vars label
(prune-free label free free-vars)))
free-vars
free-vars))
free-vars))
(define (intset-find set i)
(let lp ((idx 0) (start #f))
(let ((start (intset-next set start)))
(cond
((not start) (error "not found" set i))
((= start i) idx)
(else (lp (1+ idx) (1+ start)))))))
(define (intset-count set)
(intset-fold (lambda (_ count) (1+ count)) set 0))
(define (convert-one cps label body free-vars bound->label well-known shared)
(define (well-known? label)
(intset-ref well-known label))
(let* ((free (intmap-ref free-vars label))
(nfree (intset-count free))
(self-known? (well-known? (closure-label label shared bound->label)))
(self (match (intmap-ref cps label) (($ $kfun _ _ self) self))))
(define (convert-arg cps var k)
"Convert one possibly free variable reference to a bound reference.
If @var{var} is free, it is replaced by a closure reference via a
@code{free-ref} primcall, and @var{k} is called with the new var.
Otherwise @var{var} is bound, so @var{k} is called with @var{var}."
;; We know that var is not the name of a well-known function.
(cond
((and=> (intmap-ref bound->label var (lambda (_) #f))
(lambda (kfun)
(and (eq? empty-intset (intmap-ref free-vars kfun))
kfun)))
;; A not-well-known function with zero free vars. Copy as a
;; constant, relying on the linker to reify just one copy.
=> (lambda (kfun)
(with-cps cps
(letv var*)
(let$ body (k var*))
(letk k* ($kargs (#f) (var*) ,body))
(build-term ($continue k* #f ($closure kfun 0))))))
((intset-ref free var)
(match (vector self-known? nfree)
(#(#t 1)
;; A reference to the one free var of a well-known function.
(with-cps cps
($ (k self))))
(#(#t 2)
;; A reference to one of the two free vars in a well-known
;; function.
(let ((op (if (= var (intset-next free)) 'car 'cdr)))
(with-cps cps
(letv var*)
(let$ body (k var*))
(letk k* ($kargs (#f) (var*) ,body))
(build-term ($continue k* #f ($primcall op (self)))))))
(_
(let ((idx (intset-find free var)))
(cond
(self-known?
(with-cps cps
(letv var* u64)
(let$ body (k var*))
(letk k* ($kargs (#f) (var*) ,body))
(letk kunbox ($kargs ('idx) (u64)
($continue k* #f
($primcall 'vector-ref (self u64)))))
($ (with-cps-constants ((idx idx))
(build-term
($continue kunbox #f
($primcall 'scm->u64 (idx))))))))
(else
(with-cps cps
(letv var*)
(let$ body (k var*))
(letk k* ($kargs (#f) (var*) ,body))
($ (with-cps-constants ((idx idx))
(build-term
($continue k* #f
($primcall 'free-ref (self idx)))))))))))))
(else
(with-cps cps
($ (k var))))))
(define (convert-args cps vars k)
"Convert a number of possibly free references to bound references.
@var{k} is called with the bound references, and should return the
term."
(match vars
(()
(with-cps cps
($ (k '()))))
((var . vars)
(convert-arg cps var
(lambda (cps var)
(convert-args cps vars
(lambda (cps vars)
(with-cps cps
($ (k (cons var vars)))))))))))
(define (allocate-closure cps k src label known? nfree)
"Allocate a new closure, and pass it to $var{k}."
(match (vector known? nfree)
(#(#f nfree)
;; The call sites cannot be enumerated; allocate a closure.
(with-cps cps
(build-term ($continue k src ($closure label nfree)))))
(#(#t 2)
;; Well-known closure with two free variables; the closure is a
;; pair.
(with-cps cps
($ (with-cps-constants ((false #f))
(build-term
($continue k src ($primcall 'cons (false false))))))))
;; Well-known callee with more than two free variables; the closure
;; is a vector.
(#(#t nfree)
(unless (> nfree 2)
(error "unexpected well-known nullary, unary, or binary closure"))
(with-cps cps
($ (with-cps-constants ((nfree nfree)
(false #f))
(letv u64)
(letk kunbox ($kargs ('nfree) (u64)
($continue k src
($primcall 'make-vector (u64 false)))))
(build-term
($continue kunbox src ($primcall 'scm->u64 (nfree))))))))))
(define (init-closure cps k src var known? free)
"Initialize the free variables @var{closure-free} in a closure
bound to @var{var}, and continue to @var{k}."
(match (vector known? (intset-count free))
;; Well-known callee with zero or one free variables; no
;; initialization necessary.
(#(#t (or 0 1))
(with-cps cps
(build-term ($continue k src ($values ())))))
;; Well-known callee with two free variables; do a set-car! and
;; set-cdr!.
(#(#t 2)
(let* ((free0 (intset-next free))
(free1 (intset-next free (1+ free0))))
(convert-arg cps free0
(lambda (cps v0)
(with-cps cps
(let$ body
(convert-arg free1
(lambda (cps v1)
(with-cps cps
(build-term
($continue k src
($primcall 'set-cdr! (var v1))))))))
(letk kcdr ($kargs () () ,body))
(build-term
($continue kcdr src ($primcall 'set-car! (var v0)))))))))
;; Otherwise residualize a sequence of vector-set! or free-set!,
;; depending on whether the callee is well-known or not.
(_
(let lp ((cps cps) (prev #f) (idx 0))
(match (intset-next free prev)
(#f (with-cps cps
(build-term ($continue k src ($values ())))))
(v (with-cps cps
(let$ body (lp (1+ v) (1+ idx)))
(letk k ($kargs () () ,body))
($ (convert-arg v
(lambda (cps v)
(cond
(known?
(with-cps cps
(letv u64)
(letk kunbox
($kargs ('idx) (u64)
($continue k src
($primcall 'vector-set! (var u64 v)))))
($ (with-cps-constants ((idx idx))
(build-term
($continue kunbox src
($primcall 'scm->u64 (idx))))))))
(else
(with-cps cps
($ (with-cps-constants ((idx idx))
(build-term
($continue k src
($primcall 'free-set!
(var idx v)))))))))))))))))))
(define (make-single-closure cps k src kfun)
(let ((free (intmap-ref free-vars kfun)))
(match (vector (well-known? kfun) (intset-count free))
(#(#f 0)
(with-cps cps
(build-term ($continue k src ($closure kfun 0)))))
(#(#t 0)
(with-cps cps
(build-term ($continue k src ($const #f)))))
(#(#t 1)
;; A well-known closure of one free variable is replaced
;; at each use with the free variable itself, so we don't
;; need a binding at all; and yet, the continuation
;; expects one value, so give it something. DCE should
;; clean up later.
(with-cps cps
(build-term ($continue k src ($const #f)))))
(#(well-known? nfree)
;; A bit of a mess, but beta conversion should remove the
;; final $values if possible.
(with-cps cps
(letv closure)
(letk k* ($kargs () () ($continue k src ($values (closure)))))
(let$ init (init-closure k* src closure well-known? free))
(letk knew ($kargs (#f) (closure) ,init))
($ (allocate-closure knew src kfun well-known? nfree)))))))
;; The callee is known, but not necessarily well-known.
(define (convert-known-proc-call cps k src label closure args)
(define (have-closure cps closure)
(convert-args cps args
(lambda (cps args)
(with-cps cps
(build-term
($continue k src ($callk label closure args)))))))
(cond
((eq? (intmap-ref free-vars label) empty-intset)
;; Known call, no free variables; no closure needed.
;; Pass #f as closure argument.
(with-cps cps
($ (with-cps-constants ((false #f))
($ (have-closure false))))))
((and (well-known? (closure-label label shared bound->label))
(trivial-intset (intmap-ref free-vars label)))
;; Well-known closures with one free variable are
;; replaced at their use sites by uses of the one free
;; variable.
=> (lambda (var)
(convert-arg cps var have-closure)))
(else
;; Otherwise just load the proc.
(convert-arg cps closure have-closure))))
(define (visit-term cps term)
(match term
(($ $continue k src (or ($ $const) ($ $prim)))
(with-cps cps
term))
(($ $continue k src ($ $fun kfun))
(with-cps cps
($ (make-single-closure k src kfun))))
;; Remove letrec.
(($ $continue k src ($ $rec names vars (($ $fun kfuns) ...)))
(match (vector names vars kfuns)
(#(() () ())
;; Trivial empty case.
(with-cps cps
(build-term ($continue k src ($values ())))))
(#((name) (var) (kfun))
;; Trivial single case. We have already proven that K has
;; only LABEL as its predecessor, so we have been able
;; already to rewrite free references to the bound name with
;; the self name.
(with-cps cps
($ (make-single-closure k src kfun))))
(#(_ _ (kfun0 . _))
;; A non-trivial strongly-connected component. Does it have
;; a shared closure?
(match (intmap-ref shared kfun0 (lambda (_) #f))
(#f
;; Nope. Allocate closures for each function.
(let lp ((cps (match (intmap-ref cps k)
;; Steal declarations from the continuation.
(($ $kargs names vals body)
(intmap-replace cps k
(build-cont
($kargs () () ,body))))))
(in (map vector names vars kfuns))
(init (lambda (cps)
(with-cps cps
(build-term
($continue k src ($values ())))))))
(match in
(() (init cps))
((#(name var kfun) . in)
(let* ((known? (well-known? kfun))
(free (intmap-ref free-vars kfun))
(nfree (intset-count free)))
(define (next-init cps)
(with-cps cps
(let$ body (init))
(letk k ($kargs () () ,body))
($ (init-closure k src var known? free))))
(with-cps cps
(let$ body (lp in next-init))
(letk k ($kargs (name) (var) ,body))
($ (allocate-closure k src kfun known? nfree))))))))
(shared
;; If shared is in the bound->var map, that means one of
;; the functions is not well-known. Otherwise use kfun0
;; as the function label, but just so make-single-closure
;; can find the free vars, not for embedding in the
;; closure.
(let* ((kfun (intmap-ref bound->label shared (lambda (_) kfun0)))
(cps (match (intmap-ref cps k)
;; Make continuation declare only the shared
;; closure.
(($ $kargs names vals body)
(intmap-replace cps k
(build-cont
($kargs (#f) (shared) ,body)))))))
(with-cps cps
($ (make-single-closure k src kfun)))))))))
(($ $continue k src ($ $call proc args))
(match (intmap-ref bound->label proc (lambda (_) #f))
(#f
(convert-arg cps proc
(lambda (cps proc)
(convert-args cps args
(lambda (cps args)
(with-cps cps
(build-term
($continue k src ($call proc args)))))))))
(label
(convert-known-proc-call cps k src label proc args))))
(($ $continue k src ($ $callk label proc args))
(convert-known-proc-call cps k src label proc args))
(($ $continue k src ($ $primcall name args))
(convert-args cps args
(lambda (cps args)
(with-cps cps
(build-term
($continue k src ($primcall name args)))))))
(($ $continue k src ($ $branch kt ($ $primcall name args)))
(convert-args cps args
(lambda (cps args)
(with-cps cps
(build-term
($continue k src
($branch kt ($primcall name args))))))))
(($ $continue k src ($ $branch kt ($ $values (arg))))
(convert-arg cps arg
(lambda (cps arg)
(with-cps cps
(build-term
($continue k src
($branch kt ($values (arg)))))))))
(($ $continue k src ($ $values args))
(convert-args cps args
(lambda (cps args)
(with-cps cps
(build-term
($continue k src ($values args)))))))
(($ $continue k src ($ $prompt escape? tag handler))
(convert-arg cps tag
(lambda (cps tag)
(with-cps cps
(build-term
($continue k src
($prompt escape? tag handler)))))))))
(intset-fold (lambda (label cps)
(match (intmap-ref cps label (lambda (_) #f))
(($ $kargs names vars term)
(with-cps cps
(let$ term (visit-term term))
(setk label ($kargs names vars ,term))))
(_ cps)))
body
cps)))
(define (convert-closures cps)
"Convert free reference in @var{cps} to primcalls to @code{free-ref},
and allocate and initialize flat closures."
(let* ((kfun 0) ;; Ass-u-me.
;; label -> body-label...
(functions (compute-function-bodies cps kfun))
(cps (filter-reachable cps functions))
;; label -> bound-var...
(label->bound (compute-function-names cps functions))
;; bound-var -> label
(bound->label (invert-partition label->bound))
;; label...
(well-known (compute-well-known-functions cps bound->label))
;; label -> closure-var
(shared (compute-shared-closures cps well-known))
(cps (rewrite-shared-closure-calls cps functions label->bound shared
kfun))
;; label -> free-var...
(free-vars (compute-free-vars cps kfun shared))
(free-vars (prune-free-vars free-vars bound->label well-known shared)))
(let ((free-in-program (intmap-ref free-vars kfun)))
(unless (eq? empty-intset free-in-program)
(error "Expected no free vars in program" free-in-program)))
(with-fresh-name-state cps
(persistent-intmap
(intmap-fold
(lambda (label body cps)
(convert-one cps label body free-vars bound->label well-known shared))
functions
cps)))))
;;; Local Variables:
;;; eval: (put 'convert-arg 'scheme-indent-function 2)
;;; eval: (put 'convert-args 'scheme-indent-function 2)
;;; End:
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