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- ;;; Part of Scheme 48 1.9. See file COPYING for notices and license.
- ;;;
- ;;; Port Author: Andrew Whatson
- ;;;
- ;;; Original Authors: Richard Kelsey
- ;;;
- ;;; scheme48-1.9.2/ps-compiler/simp/join.scm
- (define-module (ps-compiler simp join)
- #:use-module (prescheme scheme48)
- #:use-module (ps-compiler node arch)
- #:use-module (ps-compiler node let-nodes)
- #:use-module (ps-compiler node node)
- #:use-module (ps-compiler node node-util)
- #:use-module (ps-compiler node primop)
- #:export (substitute-join-arguments))
- ;; Call JOIN-SUBSTITUTE on all variable/value pairs.
- (define (substitute-join-arguments lambda-proc call)
- (let ((vec (call-args call))
- (vars (lambda-variables lambda-proc)))
- (do ((vars vars (cdr vars))
- (i 1 (+ i 1))
- (c? #f (or (join-substitute (car vars) (vector-ref vec i))
- c?)))
- ((null? vars) c?))))
- ;; Does VAL take only one argument and is that argument passed to $TEST?
- ;; Is VAR applied to constants?
- ;; Then two possiblities are checked for:
- ;; Does the tree rooted at the least-common-ancestor of VAR's references
- ;; contain no side-effects and necessarily passed control to VAR?
- ;; or
- ;; Does the join point contain no side-effects above the test?
- ;;
- ;; If so, make the transformation described below.
- (define (join-substitute var val)
- (let ((ref (and (lambda-node? val)
- (simple-test-procedure val))))
- (and ref
- (applied-to-useful-value? var ref)
- (let ((lca (least-common-ancestor (variable-refs var))))
- (cond ((or (suitable-join-conditional? lca var)
- (suitable-join-point? val (node-parent ref)))
- (really-join-substitute var val lca (node-parent ref))
- #t)
- (else #f))))))
- ;; Check that VAL (a lambda-node) takes one argument, is jumped to, tests its
- ;; argument, and that all references to the argument are at or below the test.
- (define (simple-test-procedure val)
- (let ((vars (lambda-variables val)))
- (if (or (null? vars)
- (not (null? (cdr vars)))
- (not (car vars))
- (not (calls-known? val))
- (neq? 'jump (lambda-type val)))
- #f
- (let* ((var (car vars))
- (ref (any simple-cond-ref (variable-refs var))))
- (if (and ref (all-refs-below? var (node-parent ref)))
- ref
- #f)))))
- (define (simple-cond-ref ref)
- (if (primop-conditional? (call-primop (node-parent ref)))
- ref
- #f))
- (define (all-refs-below? var node)
- (set-node-flag! node #t)
- (set-node-flag! (variable-binder var) #t)
- (let ((res (every? (lambda (r)
- (eq? node (marked-ancestor r)))
- (variable-refs var))))
- (set-node-flag! node #f)
- (set-node-flag! (variable-binder var) #f)
- res))
- ;; Is VAR applied to something that can be used to simplify the conditional?
- (define (applied-to-useful-value? var ref)
- (let ((call (node-parent ref))
- (index (node-index ref)))
- (any? (lambda (r)
- (simplify-conditional? call index (call-arg (node-parent r) 1)))
- (variable-refs var))))
- ;; CALL is the least-common-ancestor of the references to VAR. Check that
- ;; the tree rooted at CALL contains no side-effects and that the control flow
- ;; necessarily passes to VAR. (Could check for undefined-effect here...)
- ;; could do check that jumped-to proc if not VAR jumped to VAR eventually
- (define (suitable-join-conditional? call var)
- (let label ((call call))
- (cond ((call-side-effects? call)
- #f)
- ((= 0 (call-exits call))
- (and (eq? 'jump (primop-id (call-primop call)))
- (eq? var (reference-variable (called-node call)))))
- (else
- (let loop ((i 0))
- (cond ((>= i (call-exits call))
- #t)
- ((not (label (lambda-body (call-arg call i))))
- #f)
- (else
- (loop (+ i 1)))))))))
- ;; #t if CALL performs side-effects. The continuations to CALL are ignored.
- (define (call-side-effects? call)
- (or (primop-side-effects (call-primop call))
- (let loop ((i (call-exits call)))
- (cond ((>= i (call-arg-count call))
- #f)
- ((side-effects? (call-arg call i))
- #t)
- (else
- (loop (+ i 1)))))))
- ;; The alternative to the above test: does the join point contain no side-effects
- ;; above the test?
- (define (suitable-join-point? join test)
- (let label ((call (lambda-body join)))
- (cond ((eq? call test)
- #t)
- ((call-side-effects? call)
- #f)
- (else
- (let loop ((i 0))
- (cond ((>= i (call-exits call))
- #t)
- ((not (label (lambda-body (call-arg call i))))
- #f)
- (else
- (loop (+ i 1)))))))))
- ;; (let ((j (lambda (v) ; VAR VAL
- ;; .a.
- ;; ($test c1 c2 ... v ...) ; TEST
- ;; .b.)))
- ;; .c.
- ;; (... (j x) ...) ; CALL
- ;; .d.)
- ;; ==>
- ;; .c.
- ;; (.a.
- ;; (let ((v1 (lambda (x) c1[x/v]))
- ;; (v2 (lambda (x) c2[x/v])))
- ;; (... ((lambda (v)
- ;; ($test (lambda () (v1 v)) (lambda () (v2 v)) ... v ...))
- ;; x)
- ;; ...))
- ;; .b.)
- ;; .d.
- ;;
- ;; CALL is the least common ancestor of the references to VAR, which is bound to
- ;; VAL, a procedure. TEST is a conditional that tests the argument passed to
- ;; VAL.
- ;;
- ;; (lambda-body VAL) is moved to where CALL is.
- ;; In the body of VAL, TEST is replaced by a LET that binds TEST's continuations
- ;; and then executes CALL. TEST's continuations are replaced by calls to
- ;; the variables bound by the LET.
- ;; Finally, references to VAR are replaced by a procedure whose body is TEST,
- ;; which is the point of the whole exercise.
- (define (really-join-substitute var val call test)
- (let ((value-var (car (lambda-variables val))))
- (receive (cont-call conts)
- (move-continuations test call value-var)
- (let ((test-parent (node-parent test))
- (val-parent (node-parent val))
- (val-index (node-index val)))
- (parameterize-continuations conts value-var)
- (detach-body test)
- (move-body cont-call
- (lambda (cont-call)
- (attach-body test-parent cont-call)
- (detach-body (lambda-body val))))
- (attach-body val test)
- (mark-changed (call-arg test 1)) ;; marks test as changed.
- (mark-changed cont-call)
- (substitute var val #t)
- (attach val-parent val-index (make-literal-node #f #f))
- (values)))))
- ;; Move the continuations of CALL to a LET call just above TO. Returns a list
- ;; of the variables now bound to the continuations and the continuations
- ;; themselves.
- (define (move-continuations call to arg-var)
- (let ((count (call-exits call)))
- (let loop ((i (- count 1)) (vs '()) (es '()))
- (cond ((< i 0)
- (let ((new-call (make-call-node (get-primop (enum primop-enum let))
- (+ count 1)
- 1))
- (new-proc (make-lambda-node 'j 'cont vs)))
- (attach-call-args new-call (cons new-proc es))
- (insert-body new-call new-proc (node-parent to))
- (values new-call es)))
- (else
- (let ((var (make-variable 'e (node-type (call-arg call i))))
- (cont (detach (call-arg call i))))
- (let-nodes ((new-cont () c1)
- (c1 (jump 0 (* var) (* arg-var))))
- (attach call i new-cont))
- (change-lambda-type cont 'jump)
- (loop (- i 1) (cons var vs) (cons cont es))))))))
- ;; Add a new variable to each of CONTS and substitute a reference to the correct
- ;; variable for each reference to VAR within CONTS.
- (define (parameterize-continuations conts var)
- (for-each (lambda (n)
- (let ((var (copy-variable var)))
- (set-lambda-variables! n (cons var (lambda-variables n)))
- (set-variable-binder! var n)
- (set-node-flag! n #t)))
- conts)
- (let ((backstop (variable-binder var)))
- (set-node-flag! backstop #t)
- (walk-refs-safely
- (lambda (n)
- (let ((cont (marked-ancestor n)))
- (if (not (eq? cont backstop))
- (replace n (make-reference-node (car (lambda-variables cont)))))))
- var)
- (set-node-flag! backstop #f)
- (for-each (lambda (n) (set-node-flag! n #f)) conts)
- (values)))
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