1 ; File: "picobit.scm", Time-stamp: <2006-05-08 16:04:37 feeley>
3 ; Copyright (C) 2006 by Marc Feeley, All Rights Reserved.
6 (proper-tail-calls-set! #f)
10 ;-----------------------------------------------------------------------------
12 (define compiler-error
13 (lambda (msg . others)
14 (display "*** ERROR -- ")
16 (for-each (lambda (x) (display " ") (write x)) others)
20 ;-----------------------------------------------------------------------------
24 (cond ((null? lst) '())
25 ((keep? (car lst)) (cons (car lst) (keep keep? (cdr lst))))
26 (else (keep keep? (cdr lst))))))
31 (cons (car lst) (take (- n 1) (cdr lst)))
37 (drop (- n 1) (cdr lst))
43 (cons x (repeat (- n 1) x))
48 (let loop ((lst lst) (i 0))
49 (cond ((not (pair? lst)) #f)
51 (else (loop (cdr lst) (+ i 1)))))))
56 (and (pred? (car lst))
57 (every pred? (cdr lst))))))
59 ;-----------------------------------------------------------------------------
61 ;; Syntax-tree node representation.
64 extender: define-type-of-node
69 (define-type-of-node cst
73 (define-type-of-node ref
77 (define-type-of-node def
81 (define-type-of-node set
85 (define-type-of-node if
88 (define-type-of-node prc
94 (define-type-of-node call
97 (define-type-of-node seq
100 (define-type-of-node fix
107 (let ((val (cst-val node)))
112 (var-id (ref-var node)))
115 (var-id (def-var node))
116 (node->expr (child1 node))))
119 (var-id (set-var node))
120 (node->expr (child1 node))))
123 (node->expr (child1 node))
124 (node->expr (child2 node))
125 (node->expr (child3 node))))
127 (if (seq? (child1 node))
129 (cons (build-pattern (prc-params node) (prc-rest? node))
130 (nodes->exprs (node-children (child1 node)))))
132 (build-pattern (prc-params node) (prc-rest? node))
133 (node->expr (child1 node)))))
135 (map node->expr (node-children node)))
137 (let ((children (node-children node)))
138 (cond ((null? children)
140 ((null? (cdr children))
141 (node->expr (car children)))
144 (nodes->exprs children))))))
146 (let ((children (node-children node)))
148 (map (lambda (var val)
152 (take (- (length children) 1) children))
153 (node->expr (list-ref children (- (length children) 1))))))
155 (compiler-error "unknown expression type" node)))))
161 (if (seq? (car nodes))
162 (append (nodes->exprs (node-children (car nodes)))
163 (nodes->exprs (cdr nodes)))
164 (cons (node->expr (car nodes))
165 (nodes->exprs (cdr nodes)))))))
167 (define build-pattern
168 (lambda (params rest?)
169 (cond ((null? params)
171 ((null? (cdr params))
173 (var-id (car params))
174 (list (var-id (car params)))))
176 (cons (var-id (car params))
177 (build-pattern (cdr params) rest?))))))
179 ;-----------------------------------------------------------------------------
181 ;; Environment representation.
193 (define-type primitive
199 (define-type renaming
203 (define make-global-env
205 (list (make-var '#%number? #t '() '() '() #f (make-primitive 1 #f #f))
206 (make-var '#%+ #t '() '() '() #f (make-primitive 2 #f #f))
207 (make-var '#%- #t '() '() '() #f (make-primitive 2 #f #f))
208 (make-var '#%* #t '() '() '() #f (make-primitive 2 #f #f))
209 (make-var '#%quotient #t '() '() '() #f (make-primitive 2 #f #f))
210 (make-var '#%remainder #t '() '() '() #f (make-primitive 2 #f #f))
211 (make-var '#%neg #t '() '() '() #f (make-primitive 1 #f #f))
212 (make-var '#%= #t '() '() '() #f (make-primitive 2 #f #f))
213 (make-var '#%< #t '() '() '() #f (make-primitive 2 #f #f))
214 (make-var '#%ior #t '() '() '() #f (make-primitive 2 #f #f)) ;; ADDED
215 (make-var '#%> #t '() '() '() #f (make-primitive 2 #f #f))
216 (make-var '#%xor #t '() '() '() #f (make-primitive 2 #f #f)) ;; ADDED
217 (make-var '#%pair? #t '() '() '() #f (make-primitive 1 #f #f))
218 (make-var '#%cons #t '() '() '() #f (make-primitive 2 #f #f))
219 (make-var '#%car #t '() '() '() #f (make-primitive 1 #f #f))
220 (make-var '#%cdr #t '() '() '() #f (make-primitive 1 #f #f))
221 (make-var '#%set-car! #t '() '() '() #f (make-primitive 2 #f #t))
222 (make-var '#%set-cdr! #t '() '() '() #f (make-primitive 2 #f #t))
223 (make-var '#%null? #t '() '() '() #f (make-primitive 1 #f #f))
224 (make-var '#%eq? #t '() '() '() #f (make-primitive 2 #f #f))
225 (make-var '#%not #t '() '() '() #f (make-primitive 1 #f #f))
226 (make-var '#%get-cont #t '() '() '() #f (make-primitive 0 #f #f))
227 (make-var '#%graft-to-cont #t '() '() '() #f (make-primitive 2 #f #f))
228 (make-var '#%return-to-cont #t '() '() '() #f (make-primitive 2 #f #f))
229 (make-var '#%halt #t '() '() '() #f (make-primitive 0 #f #t))
230 (make-var '#%symbol? #t '() '() '() #f (make-primitive 1 #f #f))
231 (make-var '#%string? #t '() '() '() #f (make-primitive 1 #f #f))
232 (make-var '#%string->list #t '() '() '() #f (make-primitive 1 #f #f))
233 (make-var '#%list->string #t '() '() '() #f (make-primitive 1 #f #f))
235 (make-var '#%make-u8vector #t '() '() '() #f (make-primitive 1 #f #f)) ;; ADDED
236 (make-var '#%u8vector-ref #t '() '() '() #f (make-primitive 2 #f #f)) ;; ADDED
237 (make-var '#%u8vector-set! #t '() '() '() #f (make-primitive 3 #f #t)) ;; ADDED
239 (make-var '#%print #t '() '() '() #f (make-primitive 1 #f #t))
240 (make-var '#%clock #t '() '() '() #f (make-primitive 0 #f #f))
241 (make-var '#%motor #t '() '() '() #f (make-primitive 2 #f #t))
242 (make-var '#%led #t '() '() '() #f (make-primitive 3 #f #t))
243 (make-var '#%led2-color #t '() '() '() #f (make-primitive 1 #f #t))
244 (make-var '#%getchar-wait #t '() '() '() #f (make-primitive 2 #f #f))
245 (make-var '#%putchar #t '() '() '() #f (make-primitive 2 #f #t))
246 (make-var '#%beep #t '() '() '() #f (make-primitive 2 #f #f))
247 (make-var '#%adc #t '() '() '() #f (make-primitive 1 #f #f))
248 (make-var '#%u8vector? #t '() '() '() #f (make-primitive 1 #f #f)) ;; ADDED, was dac
249 (make-var '#%sernum #t '() '() '() #f (make-primitive 0 #f #f))
250 (make-var '#%u8vector-length #t '() '() '() #f (make-primitive 1 #f #f)) ;; ADDED
252 (make-var '#%readyq #t '() '() '() #f #f)
256 ;; list of primitives that can be safely substituted for the equivalent
257 ;; function when it is called.
258 ;; this saves the calls to the primitive wrapper functions, which are still
259 ;; needed if a program needs the value of a "primitive", for example in :
261 ;; TODO have the arg length ?
262 (define substitute-primitives
263 '((number? . #%number?)
264 (quotient . #%quotient)
265 (remainder . #%remainder)
273 (set-car! . #%set-car!)
274 (set-cdr! . #%set-cdr!)
278 (modulo . #%remainder)
279 (string->list . #%string->list)
280 (list->string . #%list->string)
288 (bitwise-ior . #%ior)
289 (bitwise-xor . #%xor)
290 (current-time . #%clock)
291 (u8vector-length . #%u8vector-length)
292 (u8vector-ref . #%u8vector-ref)
293 (u8vector-set! . #%u8vector-set!)
298 (let loop ((lst env) (id id))
300 (cond ((and (renaming? b)
301 (assq id (renaming-renamings b)))
304 (loop (cdr lst) (cadr x))))
309 (let ((x (make-var id #t '() '() '() #f #f)))
310 (set-cdr! lst (cons x '()))
313 (loop (cdr lst) id)))))))
316 (lambda (env ids def)
317 (append (map (lambda (id)
318 (make-var id #f '() '() (list def) #f #f))
322 (define env-extend-renamings
323 (lambda (env renamings)
324 (cons (make-renaming renamings) env)))
326 ;-----------------------------------------------------------------------------
330 (define parse-program
332 (let ((x (parse-top expr env)))
334 (parse 'value #f env))
338 (let ((r (make-seq #f x)))
339 (for-each (lambda (y) (node-parent-set! y r)) x)
344 (cond ((and (pair? expr)
345 (eq? (car expr) 'begin))
346 (parse-top-list (cdr expr) env))
348 (eq? (car expr) 'hide))
349 (parse-top-hide (cadr expr) (cddr expr) env))
351 (eq? (car expr) 'rename))
352 (parse-top-rename (cadr expr) (cddr expr) env))
354 (eq? (car expr) 'define))
356 (if (pair? (cadr expr))
360 (if (pair? (cadr expr))
361 (cons 'lambda (cons (cdr (cadr expr)) (cddr expr)))
363 (let* ((var2 (env-lookup env var))
364 (val2 (parse 'value val env))
365 (r (make-def #f (list val2) var2)))
366 (node-parent-set! val2 r)
367 (var-defs-set! var2 (cons r (var-defs var2)))
370 (list (parse 'value expr env))))))
372 (define parse-top-list
375 (append (parse-top (car lst) env)
376 (parse-top-list (cdr lst) env))
379 (define parse-top-hide
380 (lambda (renamings body env)
383 (env-extend-renamings env renamings))
386 (map (lambda (x) (list 'define (car x) (cadr x))) renamings)
391 (define parse-top-rename
392 (lambda (renamings body env)
394 (env-extend-renamings env renamings))))
397 (lambda (use expr env)
398 (cond ((self-eval? expr)
399 (make-cst #f '() expr))
401 (let* ((var (env-lookup env expr))
402 (r (make-ref #f '() var)))
403 (var-refs-set! var (cons r (var-refs var)))
405 ((and (pair? expr) ;; ADDED, when we have a true macroexpander, get rid
406 (eq? (car expr) 'cond))
409 (begin ,@(cdadr expr))
410 ,(if (null? (cddr expr))
412 `(cond ,@(cddr expr))))
415 (eq? (car expr) 'set!))
416 (let ((var (env-lookup env (cadr expr))))
417 (if (var-global? var)
418 (let* ((val (parse 'value (caddr expr) env))
419 (r (make-set #f (list val) var)))
420 (node-parent-set! val r)
421 (var-sets-set! var (cons r (var-sets var)))
423 (compiler-error "set! is only permitted on global variables"))))
424 ((and (pair? expr) ;; TODO since literal vectors are quoted, this does the job
425 (eq? (car expr) 'quote))
426 (make-cst #f '() (cadr expr)))
428 (eq? (car expr) 'if))
429 (let* ((a (parse 'test (cadr expr) env))
430 (b (parse use (caddr expr) env))
431 (c (if (null? (cdddr expr))
433 (parse use (cadddr expr) env)))
434 (r (make-if #f (list a b c))))
435 (node-parent-set! a r)
436 (node-parent-set! b r)
437 (node-parent-set! c r)
440 (eq? (car expr) 'lambda))
441 (let* ((pattern (cadr expr))
442 (ids (extract-ids pattern))
443 (r (make-prc #f '() #f (has-rest-param? pattern) #f))
444 (new-env (env-extend env ids r))
445 (body (parse-body (cddr expr) new-env)))
446 (prc-params-set! r (map (lambda (id) (env-lookup new-env id)) ids))
447 (node-children-set! r (list body))
448 (node-parent-set! body r)
451 (eq? (car expr) 'begin))
452 (let* ((exprs (map (lambda (x) (parse 'value x env)) (cdr expr)))
453 (r (make-seq #f exprs)))
454 (for-each (lambda (x) (node-parent-set! x r)) exprs)
457 (eq? (car expr) 'let))
458 (if (symbol? (cadr expr))
459 (compiler-error "named let is not implemented")
462 (cons (map car (cadr expr))
464 (map cadr (cadr expr)))
467 (eq? (car expr) 'let*))
468 (if (null? (cadr expr))
470 (cons 'let (cdr expr))
474 (list (list (caar (cadr expr))
475 (cadar (cadr expr))))
477 (cons (cdr (cadr expr))
481 (eq? (car expr) 'and))
482 (cond ((null? (cdr expr))
494 (cons 'and (cddr expr))
498 (eq? (car expr) 'or))
499 (cond ((null? (cdr expr))
512 (cons 'or (cddr expr)))
518 (list (list v (cadr expr)))
522 (cons 'or (cddr expr)))))
524 ;; primitive substitution here
525 ;; TODO do this optimization in the following pass instead of at parse time ?
527 (assoc (car expr) substitute-primitives))
531 (cons (cdr prim) (cdr expr))
533 ;; binary arthimetic operations can use primitives directly
534 ;; TODO if more than one arg, unroll ? would save calls
536 (= (length (cdr expr)) 2)
537 (assoc (car expr) '((+ . #%+) (- . #%-) (* . #%*))))
541 (cons (cdr prim) (cdr expr))
545 '(quote quasiquote unquote unquote-splicing lambda if
546 set! cond and or case let let* letrec begin do define
548 (compiler-error "the compiler does not implement the special form" (car expr)))
550 (let* ((exprs (map (lambda (x) (parse 'value x env)) expr))
551 (r (make-call #f exprs)))
552 (for-each (lambda (x) (node-parent-set! x r)) exprs)
555 (compiler-error "unknown expression" expr)))))
559 (parse 'value (cons 'begin exprs) env)))
571 (cons (car pattern) (extract-ids (cdr pattern)))
572 (if (symbol? pattern)
576 (define has-rest-param?
579 (has-rest-param? (cdr pattern))
582 ;-----------------------------------------------------------------------------
584 ;; Compilation context representation.
592 (define context-change-code
596 (context-env2 ctx))))
598 (define context-change-env
600 (make-context (context-code ctx)
602 (context-env2 ctx))))
604 (define context-change-env2
606 (make-context (context-code ctx)
610 (define make-init-context
612 (make-context (make-init-code)
616 (define context-make-label
618 (context-change-code ctx (code-make-label (context-code ctx)))))
620 (define context-last-label
622 (code-last-label (context-code ctx))))
624 (define context-add-bb
626 (context-change-code ctx (code-add-bb (context-code ctx) label))))
628 (define context-add-instr
630 (context-change-code ctx (code-add-instr (context-code ctx) instr))))
632 ;; Representation of code.
644 (define make-init-code
647 (list (make-bb 0 (list))))))
649 (define code-make-label
651 (let ((label (+ (code-last-label code) 1)))
653 (code-rev-bbs code)))))
658 (code-last-label code)
659 (cons (make-bb label '())
660 (code-rev-bbs code)))))
662 (define code-add-instr
664 (let* ((rev-bbs (code-rev-bbs code))
666 (rev-instrs (bb-rev-instrs bb)))
668 (code-last-label code)
669 (cons (make-bb (bb-label bb)
670 (cons instr rev-instrs))
673 ;; Representation of compile-time stack.
676 size ; number of slots
677 slots ; for each slot, the variable (or #f) contained in the slot
680 (define make-init-stack
685 (lambda (x nb-slots stk)
686 (let ((size (stack-size stk)))
689 (append (repeat nb-slots x) (stack-slots stk))))))
691 (define stack-discard
692 (lambda (nb-slots stk)
693 (let ((size (stack-size stk)))
696 (list-tail (stack-slots stk) nb-slots)))))
698 ;; Representation of compile-time environment.
705 (define make-init-env
707 (make-env (make-init-stack)
710 (define env-change-local
715 (define env-change-closed
717 (make-env (env-local env)
720 (define find-local-var
722 (let ((i (pos-in-list var (stack-slots (env-local env)))))
724 (- (+ (pos-in-list var (env-closed env)) 1))))))
729 (let ((params (prc-params prc)))
730 (make-stack (length params)
731 (append (map var-id params) '())))
732 (let ((vars (varset->list (non-global-fv prc))))
733 ; (pp (map var-id vars))
734 (map var-id vars)))))
736 ;-----------------------------------------------------------------------------
738 (define gen-instruction
739 (lambda (instr nb-pop nb-push ctx)
745 (stack-discard nb-pop
747 (context-add-instr (context-change-env ctx (env-change-local env stk))
751 (lambda (nparams rest? ctx)
752 (gen-instruction (list 'entry nparams rest?) 0 0 ctx)))
754 (define gen-push-constant
756 (gen-instruction (list 'push-constant val) 0 1 ctx)))
758 (define gen-push-unspecified
760 (gen-push-constant #f ctx)))
762 (define gen-push-local-var
764 ; (pp (list var: var local: (stack-slots (env-local (context-env ctx))) (env-closed (context-env ctx))))
765 (let ((i (find-local-var var (context-env ctx))))
767 (gen-push-stack i ctx)
769 (+ 1 ;; TODO the +1 was added because closures are not really pairs anymore, they only have a cdr
771 (length (stack-slots (env-local (context-env ctx))))) ctx)))))
773 (define gen-push-stack
775 (gen-instruction (list 'push-stack pos) 0 1 ctx)))
777 (define gen-push-global
779 (gen-instruction (list 'push-global var) 0 1 ctx)))
781 (define gen-set-global
783 (gen-instruction (list 'set-global var) 1 0 ctx)))
787 (gen-instruction (list 'call nargs) (+ nargs 1) 1 ctx)))
791 (gen-instruction (list 'jump nargs) (+ nargs 1) 1 ctx)))
793 (define gen-call-toplevel
794 (lambda (nargs id ctx)
795 (gen-instruction (list 'call-toplevel id) nargs 1 ctx)))
797 (define gen-jump-toplevel
798 (lambda (nargs id ctx)
799 (gen-instruction (list 'jump-toplevel id) nargs 1 ctx)))
803 (gen-instruction (list 'goto label) 0 0 ctx)))
805 (define gen-goto-if-false
806 (lambda (label-false label-true ctx)
807 (gen-instruction (list 'goto-if-false label-false label-true) 1 0 ctx)))
810 (lambda (label-entry ctx)
811 (gen-instruction (list 'closure label-entry) 1 1 ctx)))
814 (lambda (id nargs unspec-result? ctx)
818 (if unspec-result? 0 1)
824 (gen-instruction (list 'shift) 1 0 (gen-shift (- n 1) ctx))
829 (gen-instruction (list 'pop) 1 0 ctx)))
833 (let ((ss (stack-size (env-local (context-env ctx)))))
834 (gen-instruction (list 'return) ss 0 ctx))))
836 ;-----------------------------------------------------------------------------
840 (car (node-children node))))
844 (cadr (node-children node))))
848 (caddr (node-children node))))
853 (cond ((or (cst? node)
859 (let ((var (def-var node)))
860 (if (toplevel-prc-with-non-rest-correct-calls? var)
861 (comp-prc (child1 node) #f ctx)
862 (if (var-needed? var)
863 (let ((ctx2 (comp-push (child1 node) ctx)))
864 (gen-set-global (var-id var) ctx2))
865 (comp-none (child1 node) ctx)))))
868 (let ((var (set-var node)))
869 (if (var-needed? var)
870 (let ((ctx2 (comp-push (child1 node) ctx)))
871 (gen-set-global (var-id var) ctx2))
872 (comp-none (child1 node) ctx))))
876 (context-make-label ctx))
878 (context-last-label ctx2))
880 (context-make-label ctx2))
882 (context-last-label ctx3))
884 (context-make-label ctx3))
886 (context-last-label ctx4))
888 (context-make-label ctx4))
890 (context-last-label ctx5))
892 (context-make-label ctx5))
894 (context-last-label ctx6))
896 (comp-test (child1 node) label-then label-else ctx6))
900 (comp-none (child3 node)
902 (context-add-bb ctx7 label-else)
907 (comp-none (child2 node)
909 (context-add-bb ctx8 label-then)
910 (context-env2 ctx7)))))
914 (context-add-bb ctx9 label-else-join)))
918 (context-add-bb ctx10 label-then-join)))
920 (context-add-bb ctx11 label-join)))
924 (comp-call node 'none ctx))
927 (let ((children (node-children node)))
930 (let loop ((lst children)
932 (if (null? (cdr lst))
933 (comp-none (car lst) ctx)
935 (comp-none (car lst) ctx)))))))
938 (compiler-error "unknown expression type" node)))))
943 (cond ((or (cst? node)
950 (gen-return (comp-push node ctx)))
954 (context-make-label ctx))
956 (context-last-label ctx2))
958 (context-make-label ctx2))
960 (context-last-label ctx3))
962 (comp-test (child1 node) label-then label-else ctx3))
964 (comp-tail (child3 node)
966 (context-add-bb ctx4 label-else)
969 (comp-tail (child2 node)
971 (context-add-bb ctx5 label-then)
972 (context-env2 ctx4)))))
976 (comp-call node 'tail ctx))
979 (let ((children (node-children node)))
981 (gen-return (gen-push-unspecified ctx))
982 (let loop ((lst children)
984 (if (null? (cdr lst))
985 (comp-tail (car lst) ctx)
987 (comp-none (car lst) ctx)))))))
990 (compiler-error "unknown expression type" node)))))
996 (display "--------------\n")
997 (pp (node->expr node))
1003 (let ((val (cst-val node)))
1004 (gen-push-constant val ctx)))
1007 (let ((var (ref-var node)))
1008 (if (var-global? var)
1009 (if (null? (var-defs var))
1010 (compiler-error "undefined variable:" (var-id var))
1011 (let ((val (child1 (car (var-defs var)))))
1012 (if (and (not (mutable-var? var))
1013 (cst? val)) ;; immutable global, counted as cst
1014 (gen-push-constant (cst-val val) ctx)
1015 (gen-push-global (var-id var) ctx))))
1016 (gen-push-local-var (var-id var) ctx)))) ;; TODO globals as csts seem to work (but only for constant-values ones, like it probably should)
1020 (gen-push-unspecified (comp-none node ctx)))
1024 (context-make-label ctx))
1026 (context-last-label ctx2))
1028 (context-make-label ctx2))
1030 (context-last-label ctx3))
1032 (context-make-label ctx3))
1034 (context-last-label ctx4))
1036 (context-make-label ctx4))
1038 (context-last-label ctx5))
1040 (context-make-label ctx5))
1042 (context-last-label ctx6))
1044 (comp-test (child1 node) label-then label-else ctx6))
1048 (comp-push (child3 node)
1049 (context-change-env2
1050 (context-add-bb ctx7 label-else)
1055 (comp-push (child2 node)
1057 (context-add-bb ctx8 label-then)
1058 (context-env2 ctx7)))))
1062 (context-add-bb ctx9 label-else-join)))
1066 (context-add-bb ctx10 label-then-join)))
1068 (context-add-bb ctx11 label-join)))
1072 (comp-prc node #t ctx))
1075 (comp-call node 'push ctx))
1078 (let ((children (node-children node)))
1079 (if (null? children)
1080 (gen-push-unspecified ctx)
1081 (let loop ((lst children)
1083 (if (null? (cdr lst))
1084 (comp-push (car lst) ctx)
1086 (comp-none (car lst) ctx)))))))
1089 (compiler-error "unknown expression type" node)))))
1091 (define (build-closure label-entry vars ctx)
1093 (define (build vars ctx)
1095 (gen-push-constant '() ctx)
1100 (gen-push-local-var (car vars) ctx)))))
1103 (gen-closure label-entry
1104 (gen-push-constant '() ctx))
1105 (gen-closure label-entry
1107 ;; TODO the last branch was changed because since pointers are now larger, there is not a pointer-sized free space in each closure, which could make it behave like a pair. now, everything is in the env, and closures only have a cdr
1110 (lambda (node closure? ctx)
1112 (context-make-label ctx))
1114 (context-last-label ctx2))
1116 (context-make-label ctx2))
1118 (context-last-label ctx3))
1123 (build-closure label-entry (env-closed body-env) ctx3)
1126 (gen-goto label-continue ctx4))
1128 (gen-entry (length (prc-params node))
1130 (context-add-bb (context-change-env ctx5
1134 (comp-tail (child1 node) ctx6)))
1135 (prc-entry-label-set! node label-entry)
1136 (context-add-bb (context-change-env ctx7 (context-env ctx5))
1140 (lambda (node reason ctx)
1141 (let* ((op (child1 node))
1142 (args (cdr (node-children node)))
1143 (nargs (length args)))
1144 (let loop ((lst args)
1148 (let ((arg (car lst)))
1150 (comp-push arg ctx)))
1152 (cond ((and (ref? op)
1153 (var-primitive (ref-var op)))
1154 (let* ((var (ref-var op))
1156 (primitive (var-primitive var))
1157 (prim-nargs (primitive-nargs primitive)))
1161 (cond ((eq? reason 'tail)
1163 (if (primitive-unspecified-result? primitive)
1164 (gen-push-unspecified ctx2)
1167 (if (primitive-unspecified-result? primitive)
1168 (gen-push-unspecified ctx2)
1171 (if (primitive-unspecified-result? primitive)
1176 (if (primitive-inliner primitive)
1177 ((primitive-inliner primitive) ctx)
1178 (if (not (= nargs prim-nargs))
1179 (compiler-error "primitive called with wrong number of arguments" id)
1183 (primitive-unspecified-result? primitive)
1188 (toplevel-prc-with-non-rest-correct-calls? (ref-var op)))
1191 (cond ((eq? reason 'tail)
1192 (gen-jump-toplevel nargs prc ctx))
1194 (gen-call-toplevel nargs prc ctx))
1196 (gen-pop (gen-call-toplevel nargs prc ctx))))))
1199 (let ((ctx2 (comp-push op ctx)))
1200 (cond ((eq? reason 'tail)
1201 (gen-jump nargs ctx2))
1203 (gen-call nargs ctx2))
1205 (gen-pop (gen-call nargs ctx2))))))))))))
1208 (lambda (node label-true label-false ctx)
1212 (let ((val (cst-val node)))
1217 (context-change-env2 ctx2 (context-env ctx2))))
1226 (comp-push node ctx))
1228 (gen-goto-if-false label-false label-true ctx2)))
1229 (context-change-env2 ctx3 (context-env ctx3))))
1233 (gen-goto label-true ctx)))
1234 (context-change-env2 ctx2 (context-env ctx2))))
1237 (compiler-error "unknown expression type" node)))))
1239 ;-----------------------------------------------------------------------------
1241 (define toplevel-prc?
1243 (and (not (mutable-var? var))
1244 (let ((d (var-defs var)))
1247 (let ((val (child1 (car d))))
1251 (define toplevel-prc-with-non-rest-correct-calls?
1253 (let ((prc (toplevel-prc? var)))
1255 (not (prc-rest? prc))
1257 (let ((parent (node-parent r)))
1259 (eq? (child1 parent) r)
1260 (= (length (prc-params prc))
1261 (- (length (node-children parent)) 1)))))
1265 (define mutable-var?
1267 (not (null? (var-sets var)))))
1273 (varset->list (fv node))))))
1275 (define non-global-fv
1278 (keep (lambda (x) (not (var-global? x)))
1279 (varset->list (fv node))))))
1286 (let ((var (ref-var node)))
1287 (varset-singleton var)))
1289 (let ((var (def-var node))
1290 (val (child1 node)))
1292 (varset-singleton var)
1295 (let ((var (set-var node))
1296 (val (child1 node)))
1298 (varset-singleton var)
1301 (let ((a (list-ref (node-children node) 0))
1302 (b (list-ref (node-children node) 1))
1303 (c (list-ref (node-children node) 2)))
1304 (varset-union-multi (list (fv a) (fv b) (fv c)))))
1306 (let ((body (list-ref (node-children node) 0)))
1309 (build-params-varset (prc-params node)))))
1311 (varset-union-multi (map fv (node-children node))))
1313 (varset-union-multi (map fv (node-children node))))
1315 (compiler-error "unknown expression type" node)))))
1317 (define build-params-varset
1319 (list->varset params)))
1321 (define mark-needed-global-vars!
1322 (lambda (global-env node)
1325 (env-lookup global-env '#%readyq))
1329 (if (and (var-global? var)
1330 (not (var-needed? var))
1331 ;; globals that obey the following conditions are considered
1333 (not (and (not (mutable-var? var))
1334 (> (length (var-defs var)) 0) ;; TODO to catch errors for primitives
1335 (cst? (child1 (car (var-defs var)))))))
1337 (var-needed?-set! var #t)
1340 (let ((val (child1 def)))
1341 (if (side-effect-less? val)
1344 (if (eq? var readyq)
1347 (env-lookup global-env '#%start-first-process))
1349 (env-lookup global-env '#%exit))))))))
1351 (define side-effect-less?
1361 (let ((var (ref-var node)))
1364 (let ((var (def-var node))
1365 (val (child1 node)))
1366 (if (not (side-effect-less? val))
1369 (let ((var (set-var node))
1370 (val (child1 node)))
1373 (let ((a (list-ref (node-children node) 0))
1374 (b (list-ref (node-children node) 1))
1375 (c (list-ref (node-children node) 2)))
1380 (let ((body (list-ref (node-children node) 0)))
1383 (for-each mark! (node-children node)))
1385 (for-each mark! (node-children node)))
1387 (compiler-error "unknown expression type" node)))))
1392 ;-----------------------------------------------------------------------------
1396 (define (varset-empty) ; return the empty set
1399 (define (varset-singleton x) ; create a set containing only 'x'
1402 (define (list->varset lst) ; convert list to set
1405 (define (varset->list set) ; convert set to list
1408 (define (varset-size set) ; return cardinality of set
1411 (define (varset-empty? set) ; is 'x' the empty set?
1414 (define (varset-member? x set) ; is 'x' a member of the 'set'?
1415 (and (not (null? set))
1416 (or (eq? x (car set))
1417 (varset-member? x (cdr set)))))
1419 (define (varset-adjoin set x) ; add the element 'x' to the 'set'
1420 (if (varset-member? x set) set (cons x set)))
1422 (define (varset-remove set x) ; remove the element 'x' from 'set'
1428 (cons (car set) (varset-remove (cdr set) x)))))
1430 (define (varset-equal? s1 s2) ; are 's1' and 's2' equal sets?
1431 (and (varset-subset? s1 s2)
1432 (varset-subset? s2 s1)))
1434 (define (varset-subset? s1 s2) ; is 's1' a subset of 's2'?
1437 ((varset-member? (car s1) s2)
1438 (varset-subset? (cdr s1) s2))
1442 (define (varset-difference set1 set2) ; return difference of sets
1445 ((varset-member? (car set1) set2)
1446 (varset-difference (cdr set1) set2))
1448 (cons (car set1) (varset-difference (cdr set1) set2)))))
1450 (define (varset-union set1 set2) ; return union of sets
1451 (define (union s1 s2)
1454 ((varset-member? (car s1) s2)
1455 (union (cdr s1) s2))
1457 (cons (car s1) (union (cdr s1) s2)))))
1458 (if (varset-smaller? set1 set2)
1462 (define (varset-intersection set1 set2) ; return intersection of sets
1463 (define (intersection s1 s2)
1466 ((varset-member? (car s1) s2)
1467 (cons (car s1) (intersection (cdr s1) s2)))
1469 (intersection (cdr s1) s2))))
1470 (if (varset-smaller? set1 set2)
1471 (intersection set1 set2)
1472 (intersection set2 set1)))
1474 (define (varset-intersects? set1 set2) ; do sets 'set1' and 'set2' intersect?
1475 (not (varset-empty? (varset-intersection set1 set2))))
1477 (define (varset-smaller? set1 set2)
1482 (varset-smaller? (cdr set1) (cdr set2)))))
1484 (define (varset-union-multi sets)
1487 (n-ary varset-union (car sets) (cdr sets))))
1489 (define (n-ary function first rest)
1492 (n-ary function (function first (car rest)) (cdr rest))))
1494 ;------------------------------------------------------------------------------
1496 (define code->vector
1498 (let ((v (make-vector (+ (code-last-label code) 1))))
1501 (vector-set! v (bb-label bb) bb))
1502 (code-rev-bbs code))
1505 (define bbs->ref-counts
1507 (let ((ref-counts (make-vector (vector-length bbs) 0)))
1511 (let ((ref-count (vector-ref ref-counts label)))
1512 (vector-set! ref-counts label (+ ref-count 1))
1514 (let* ((bb (vector-ref bbs label))
1515 (rev-instrs (bb-rev-instrs bb)))
1518 (let ((opcode (car instr)))
1519 (cond ((eq? opcode 'goto)
1520 (visit (cadr instr)))
1521 ((eq? opcode 'goto-if-false)
1522 (visit (cadr instr))
1523 (visit (caddr instr)))
1524 ((or (eq? opcode 'closure)
1525 (eq? opcode 'call-toplevel)
1526 (eq? opcode 'jump-toplevel))
1527 (visit (cadr instr))))))
1534 (define resolve-toplevel-labels!
1537 (if (< i (vector-length bbs))
1538 (let* ((bb (vector-ref bbs i))
1539 (rev-instrs (bb-rev-instrs bb)))
1542 (map (lambda (instr)
1543 (let ((opcode (car instr)))
1544 (cond ((eq? opcode 'call-toplevel)
1546 (prc-entry-label (cadr instr))))
1547 ((eq? opcode 'jump-toplevel)
1549 (prc-entry-label (cadr instr))))
1555 (define tighten-jump-cascades!
1557 (let ((ref-counts (bbs->ref-counts bbs)))
1561 (let* ((bb (vector-ref bbs label))
1562 (rev-instrs (bb-rev-instrs bb)))
1563 (and (or (null? (cdr rev-instrs))
1564 (= (vector-ref ref-counts label) 1))
1570 (if (< i (vector-length bbs))
1571 (if (> (vector-ref ref-counts i) 0)
1572 (let* ((bb (vector-ref bbs i))
1573 (rev-instrs (bb-rev-instrs bb))
1574 (jump (car rev-instrs))
1575 (opcode (car jump)))
1576 (cond ((eq? opcode 'goto)
1577 (let* ((label (cadr jump))
1578 (jump-replacement (resolve label)))
1579 (if jump-replacement
1584 (make-bb (bb-label bb)
1585 (append jump-replacement
1591 ((eq? opcode 'goto-if-false)
1592 (let* ((label-then (cadr jump))
1593 (label-else (caddr jump))
1594 (jump-then-replacement (resolve label-then))
1595 (jump-else-replacement (resolve label-else)))
1596 (if (and jump-then-replacement
1597 (null? (cdr jump-then-replacement))
1598 jump-else-replacement
1599 (null? (cdr jump-else-replacement))
1600 (or (eq? (caar jump-then-replacement) 'goto)
1601 (eq? (caar jump-else-replacement) 'goto)))
1606 (make-bb (bb-label bb)
1607 (cons (list 'goto-if-false
1608 (if (eq? (caar jump-then-replacement) 'goto)
1609 (cadar jump-then-replacement)
1611 (if (eq? (caar jump-else-replacement) 'goto)
1612 (cadar jump-else-replacement)
1627 (define remove-useless-bbs!
1629 (let ((ref-counts (bbs->ref-counts bbs)))
1630 (let loop1 ((label 0) (new-label 0))
1631 (if (< label (vector-length bbs))
1632 (if (> (vector-ref ref-counts label) 0)
1633 (let ((bb (vector-ref bbs label)))
1637 (make-bb new-label (bb-rev-instrs bb)))
1638 (loop1 (+ label 1) (+ new-label 1)))
1639 (loop1 (+ label 1) new-label))
1640 (renumber-labels bbs ref-counts new-label))))))
1642 (define renumber-labels
1643 (lambda (bbs ref-counts n)
1644 (let ((new-bbs (make-vector n)))
1645 (let loop2 ((label 0))
1646 (if (< label (vector-length bbs))
1647 (if (> (vector-ref ref-counts label) 0)
1648 (let* ((bb (vector-ref bbs label))
1649 (new-label (bb-label bb))
1650 (rev-instrs (bb-rev-instrs bb)))
1657 (bb-label (vector-ref bbs label))))
1659 (let ((opcode (car instr)))
1660 (cond ((eq? opcode 'closure)
1662 (new-label (cadr instr))))
1663 ((eq? opcode 'call-toplevel)
1664 (list 'call-toplevel
1665 (new-label (cadr instr))))
1666 ((eq? opcode 'jump-toplevel)
1667 (list 'jump-toplevel
1668 (new-label (cadr instr))))
1671 (new-label (cadr instr))))
1672 ((eq? opcode 'goto-if-false)
1673 (list 'goto-if-false
1674 (new-label (cadr instr))
1675 (new-label (caddr instr))))
1682 (make-bb new-label (map fix rev-instrs)))
1683 (loop2 (+ label 1)))
1684 (loop2 (+ label 1)))
1689 (let* ((done (make-vector (vector-length bbs) #f)))
1691 (define unscheduled?
1693 (not (vector-ref done label))))
1696 (lambda (instrs todo)
1698 (let* ((instr (car instrs))
1699 (opcode (car instr)))
1700 (cond ((or (eq? opcode 'closure)
1701 (eq? opcode 'call-toplevel)
1702 (eq? opcode 'jump-toplevel))
1703 (label-refs (cdr instrs) (cons (cadr instr) todo)))
1705 (label-refs (cdr instrs) todo))))
1708 (define schedule-here
1709 (lambda (label new-label todo cont)
1710 (let* ((bb (vector-ref bbs label))
1711 (rev-instrs (bb-rev-instrs bb))
1712 (jump (car rev-instrs))
1714 (new-todo (label-refs rev-instrs todo)))
1715 (vector-set! bbs label (make-bb new-label rev-instrs))
1716 (vector-set! done label #t)
1717 (cond ((eq? opcode 'goto)
1718 (let ((label (cadr jump)))
1719 (if (unscheduled? label)
1720 (schedule-here label
1724 (cont (+ new-label 1)
1726 ((eq? opcode 'goto-if-false)
1727 (let ((label-then (cadr jump))
1728 (label-else (caddr jump)))
1729 (cond ((unscheduled? label-else)
1730 (schedule-here label-else
1732 (cons label-then new-todo)
1734 ((unscheduled? label-then)
1735 (schedule-here label-then
1740 (cont (+ new-label 1)
1743 (cont (+ new-label 1)
1746 (define schedule-somewhere
1747 (lambda (label new-label todo cont)
1748 (schedule-here label new-label todo cont)))
1750 (define schedule-todo
1751 (lambda (new-label todo)
1753 (let ((label (car todo)))
1754 (if (unscheduled? label)
1755 (schedule-somewhere label
1759 (schedule-todo new-label
1763 (schedule-here 0 0 '() schedule-todo)
1765 (renumber-labels bbs
1766 (make-vector (vector-length bbs) 1)
1767 (vector-length bbs)))))
1771 (let loop ((label (- (vector-length bbs) 1))
1774 (let* ((bb (vector-ref bbs label))
1775 (rev-instrs (bb-rev-instrs bb))
1776 (jump (car rev-instrs))
1777 (opcode (car jump)))
1782 (cond ((eq? opcode 'goto)
1783 (if (= (cadr jump) (+ label 1))
1786 ((eq? opcode 'goto-if-false)
1787 (cond ((= (caddr jump) (+ label 1))
1788 (cons (list 'goto-if-false (cadr jump))
1790 ((= (cadr jump) (+ label 1))
1791 (cons (list 'goto-if-not-false (caddr jump))
1794 (cons (list 'goto (caddr jump))
1795 (cons (list 'goto-if-false (cadr jump))
1796 (cdr rev-instrs))))))
1802 (define optimize-code
1804 (let ((bbs (code->vector code)))
1805 (resolve-toplevel-labels! bbs)
1806 (tighten-jump-cascades! bbs)
1807 (let ((bbs (remove-useless-bbs! bbs)))
1811 (define expand-loads
1814 (if (eq? (car e) 'load)
1816 (expand-loads (with-input-from-file (cadr e) read-all)))
1823 (with-input-from-file "library.scm" read-all))
1825 (expand-loads (append library
1826 (with-input-from-file filename read-all))))
1830 (parse-top (cons 'begin toplevel-exprs) global-env)))
1834 (mark-needed-global-vars! global-env node))
1839 (lambda (defs after-defs)
1841 (define make-seq-preparsed
1843 (let ((r (make-seq #f exprs)))
1844 (for-each (lambda (x) (node-parent-set! x r)) exprs)
1847 (define make-call-preparsed
1849 (let ((r (make-call #f exprs)))
1850 (for-each (lambda (x) (node-parent-set! x r)) exprs)
1854 (env-lookup global-env '#%readyq))
1856 (list (make-seq-preparsed defs)
1857 (make-call-preparsed
1858 (list (parse 'value '#%start-first-process global-env)
1862 (extract-ids pattern))
1864 (make-prc #f '() #f (has-rest-param? pattern) #f))
1866 (env-extend global-env ids r))
1868 (make-seq-preparsed after-defs)))
1871 (map (lambda (id) (env-lookup new-env id))
1873 (node-children-set! r (list body))
1874 (node-parent-set! body r)
1884 global-env))))))))))
1886 (define extract-parts
1889 (not (def? (car lst))))
1894 (cont (cons (car lst) d) ad))))))
1896 ;------------------------------------------------------------------------------
1898 ;;(include "asm.scm")
1902 ;;; This module implements the generic assembler.
1904 ;;(##declare (standard-bindings) (fixnum) (block))
1906 (define compiler-internal-error error)
1908 ;; (asm-begin! start-pos big-endian?) initializes the assembler and
1909 ;; starts a new empty code stream at address "start-pos". It must be
1910 ;; called every time a new code stream is to be built. The argument
1911 ;; "big-endian?" indicates the byte ordering to use for 16, 32 and 64
1912 ;; bit values. After a call to "asm-begin!" the code stream is built
1913 ;; by calling the following procedures:
1915 ;; asm-8 to add an 8 bit integer to the code stream
1916 ;; asm-16 to add a 16 bit integer to the code stream
1917 ;; asm-32 to add a 32 bit integer to the code stream
1918 ;; asm-64 to add a 64 bit integer to the code stream
1919 ;; asm-float64 to add a 64 bit IEEE float to the code stream
1920 ;; asm-string to add a null terminated string to the code stream
1921 ;; asm-label to set a label to the current position in the code stream
1922 ;; asm-align to add enough zero bytes to force alignment
1923 ;; asm-origin to add enough zero bytes to move to a particular address
1924 ;; asm-at-assembly to defer code production to assembly time
1925 ;; asm-listing to add textual information to the listing
1927 (define (asm-begin! start-pos big-endian?)
1928 (set! asm-start-pos start-pos)
1929 (set! asm-big-endian? big-endian?)
1930 (set! asm-code-stream (asm-make-stream))
1933 ;; (asm-end!) must be called to finalize the assembler.
1936 (set! asm-code-stream #f)
1939 ;; (asm-8 n) adds an 8 bit signed or unsigned integer to the code stream.
1942 (asm-code-extend (asm-bits-0-to-7 n)))
1944 ;; (asm-16 n) adds a 16 bit signed or unsigned integer to the code stream.
1948 (begin (asm-8 (asm-bits-8-and-up n)) (asm-8 n))
1949 (begin (asm-8 n) (asm-8 (asm-bits-8-and-up n)))))
1951 ;; (asm-32 n) adds a 32 bit signed or unsigned integer to the code stream.
1955 (begin (asm-16 (asm-bits-16-and-up n)) (asm-16 n))
1956 (begin (asm-16 n) (asm-16 (asm-bits-16-and-up n)))))
1958 ;; (asm-64 n) adds a 64 bit signed or unsigned integer to the code stream.
1962 (begin (asm-32 (asm-bits-32-and-up n)) (asm-32 n))
1963 (begin (asm-32 n) (asm-32 (asm-bits-32-and-up n)))))
1965 ;; (asm-float64 n) adds a 64 bit IEEE floating point number to the code stream.
1967 (define (asm-float64 n)
1968 (asm-64 (asm-float->bits n)))
1970 ;; (asm-string str) adds a null terminated string to the code stream.
1972 (define (asm-string str)
1973 (let ((len (string-length str)))
1977 (asm-8 (char->integer (string-ref str i)))
1981 ;; (asm-make-label id) creates a new label object. A label can
1982 ;; be queried with "asm-label-pos" to obtain the label's position
1983 ;; relative to the start of the code stream (i.e. "start-pos").
1984 ;; The argument "id" gives a name to the label (not necessarily
1985 ;; unique) and is only needed for debugging purposes.
1987 (define (asm-make-label id)
1988 (vector 'LABEL #f id))
1990 ;; (asm-label label-obj) sets the label to the current position in the
1993 (define (asm-label label-obj)
1994 (if (vector-ref label-obj 1)
1995 (compiler-internal-error
1996 "asm-label, label multiply defined" (asm-label-id label-obj))
1998 (vector-set! label-obj 1 0)
1999 (asm-code-extend label-obj))))
2001 ;; (asm-label-id label-obj) returns the identifier of the label object.
2003 (define (asm-label-id label-obj)
2004 (vector-ref label-obj 2))
2006 ;; (asm-label-pos label-obj) returns the position of the label
2007 ;; relative to the start of the code stream (i.e. "start-pos").
2008 ;; This procedure can only be called at assembly time (i.e.
2009 ;; within the call to "asm-assemble") or after assembly time
2010 ;; for labels declared prior to assembly time with "asm-label".
2011 ;; A label declared at assembly time can only be queried after
2012 ;; assembly time. Moreover, at assembly time the position of a
2013 ;; label may vary from one call to the next due to the actions
2014 ;; of the assembler.
2016 (define (asm-label-pos label-obj)
2017 (let ((pos (vector-ref label-obj 1)))
2020 (compiler-internal-error
2021 "asm-label-pos, undefined label" (asm-label-id label-obj)))))
2023 ;; (asm-align multiple offset) adds enough zero bytes to the code
2024 ;; stream to force alignment to the next address congruent to
2025 ;; "offset" modulo "multiple".
2027 (define (asm-align multiple offset)
2030 (modulo (- multiple (- self offset)) multiple))
2032 (let loop ((n (modulo (- multiple (- self offset)) multiple)))
2036 (loop (- n 1))))))))
2038 ;; (asm-origin address) adds enough zero bytes to the code stream to move
2039 ;; to the address "address".
2041 (define (asm-origin address)
2046 (let ((len (- address self)))
2048 (compiler-internal-error "asm-origin, can't move back")
2053 (loop (- n 1))))))))))
2055 ;; (asm-at-assembly . procs) makes it possible to defer code
2056 ;; production to assembly time. A useful application is to generate
2057 ;; position dependent and span dependent code sequences. This
2058 ;; procedure must be passed an even number of procedures. All odd
2059 ;; indexed procedures (including the first procedure) are called "check"
2060 ;; procedures. The even indexed procedures are the "production"
2061 ;; procedures which, when called, produce a particular code sequence.
2062 ;; A check procedure decides if, given the current state of assembly
2063 ;; (in particular the current positioning of the labels), the code
2064 ;; produced by the corresponding production procedure is valid.
2065 ;; If the code is not valid, the check procedure must return #f.
2066 ;; If the code is valid, the check procedure must return the length
2067 ;; of the code sequence in bytes. The assembler will try each check
2068 ;; procedure in order until it finds one that does not return #f
2069 ;; (the last check procedure must never return #f). For convenience,
2070 ;; the current position in the code sequence is passed as the single
2071 ;; argument of check and production procedures.
2073 ;; Here is a sample call of "asm-at-assembly" to produce the
2074 ;; shortest branch instruction to branch to label "x" for a
2075 ;; hypothetical processor:
2079 ;; (lambda (self) ; first check procedure
2080 ;; (let ((dist (- (asm-label-pos x) self)))
2081 ;; (if (and (>= dist -128) (<= dist 127)) ; short branch possible?
2085 ;; (lambda (self) ; first production procedure
2086 ;; (asm-8 #x34) ; branch opcode for 8 bit displacement
2087 ;; (asm-8 (- (asm-label-pos x) self)))
2089 ;; (lambda (self) 5) ; second check procedure
2091 ;; (lambda (self) ; second production procedure
2092 ;; (asm-8 #x35) ; branch opcode for 32 bit displacement
2093 ;; (asm-32 (- (asm-label-pos x) self))))
2095 (define (asm-at-assembly . procs)
2096 (asm-code-extend (vector 'DEFERRED procs)))
2098 ;; (asm-listing text) adds text to the right side of the listing.
2099 ;; The atoms in "text" will be output using "display" (lists are
2100 ;; traversed recursively). The listing is generated by calling
2101 ;; "asm-display-listing".
2103 (define (asm-listing text)
2104 (asm-code-extend (vector 'LISTING text)))
2106 ;; (asm-assemble) assembles the code stream. After assembly, the
2107 ;; label objects will be set to their final position and the
2108 ;; alignment bytes and the deferred code will have been produced. It
2109 ;; is possible to extend the code stream after assembly. However, if
2110 ;; any of the procedures "asm-label", "asm-align", and
2111 ;; "asm-at-assembly" are called, the code stream will have to be
2112 ;; assembled once more.
2114 (define (asm-assemble)
2115 (let ((fixup-lst (asm-pass1)))
2118 (let loop2 ((lst fixup-lst)
2120 (pos asm-start-pos))
2122 (if changed? (loop1))
2123 (let* ((fixup (car lst))
2124 (pos (+ pos (car fixup)))
2127 (if (eq? (vector-ref x 0) 'LABEL)
2129 (if (= (vector-ref x 1) pos)
2130 (loop2 (cdr lst) changed? pos)
2132 (vector-set! x 1 pos)
2133 (loop2 (cdr lst) #t pos)))
2136 (let ((n ((car (vector-ref x 1)) pos)))
2138 (loop2 (cdr lst) changed? (+ pos n))
2140 (vector-set! x 1 (cddr (vector-ref x 1)))
2143 (let loop4 ((prev asm-code-stream)
2144 (curr (cdr asm-code-stream))
2145 (pos asm-start-pos))
2147 (set-car! asm-code-stream prev)
2148 (let ((x (car curr))
2151 (let ((kind (vector-ref x 0)))
2152 (cond ((eq? kind 'LABEL)
2153 (let ((final-pos (vector-ref x 1)))
2155 (if (not (= pos final-pos))
2156 (compiler-internal-error
2157 "asm-assemble, inconsistency detected"))
2158 (vector-set! x 1 pos))
2159 (set-cdr! prev next)
2160 (loop4 prev next pos)))
2161 ((eq? kind 'DEFERRED)
2162 (let ((temp asm-code-stream))
2163 (set! asm-code-stream (asm-make-stream))
2164 ((cadr (vector-ref x 1)) pos)
2165 (let ((tail (car asm-code-stream)))
2166 (set-cdr! tail next)
2167 (let ((head (cdr asm-code-stream)))
2168 (set-cdr! prev head)
2169 (set! asm-code-stream temp)
2170 (loop4 prev head pos)))))
2172 (loop4 curr next pos))))
2173 (loop4 curr next (+ pos 1))))))))
2175 ;; (asm-display-listing port) produces a listing of the code stream
2176 ;; on the given output port. The bytes generated are shown in
2177 ;; hexadecimal on the left side of the listing and the right side
2178 ;; of the listing contains the text inserted by "asm-listing".
2180 (define (asm-display-listing port)
2182 (define text-col 24)
2183 (define pos-width 6)
2184 (define byte-width 2)
2186 (define (output text)
2187 (cond ((null? text))
2190 (output (cdr text)))
2192 (display text port))))
2194 (define (print-hex n)
2195 (display (string-ref "0123456789ABCDEF" n) port))
2197 (define (print-byte n)
2198 (print-hex (quotient n 16))
2199 (print-hex (modulo n 16)))
2201 (define (print-pos n)
2205 (print-byte (quotient n #x10000))
2206 (print-byte (modulo (quotient n #x100) #x100))
2207 (print-byte (modulo n #x100)))))
2209 (let loop1 ((lst (cdr asm-code-stream)) (pos asm-start-pos) (col 0))
2213 (let ((x (car lst)))
2215 (let ((kind (vector-ref x 0)))
2216 (cond ((eq? kind 'LISTING)
2217 (let loop2 ((col col))
2218 (if (< col text-col)
2220 (display (integer->char 9) port)
2221 (loop2 (* 8 (+ (quotient col 8) 1))))))
2222 (output (vector-ref x 1))
2224 (loop1 (cdr lst) pos 0))
2226 (compiler-internal-error
2227 "asm-display-listing, code stream not assembled"))))
2228 (if (or (= col 0) (>= col (- text-col byte-width)))
2230 (if (not (= col 0)) (newline port))
2234 (loop1 (cdr lst) (+ pos 1) (+ (+ pos-width 1) byte-width)))
2237 (loop1 (cdr lst) (+ pos 1) (+ col byte-width)))))))))
2239 ;; (asm-write-code filename) outputs the code stream (i.e. the sequence
2240 ;; of bytes produced) on the named file.
2242 (define (asm-write-code filename)
2243 (with-output-to-file filename
2245 (let loop ((lst (cdr asm-code-stream)))
2246 (if (not (null? lst))
2247 (let ((x (car lst)))
2249 (let ((kind (vector-ref x 0)))
2250 (if (not (eq? kind 'LISTING))
2251 (compiler-internal-error
2252 "asm-write-code, code stream not assembled"))
2255 (write-char (integer->char x))
2256 (loop (cdr lst))))))))))
2258 (define (asm-write-hex-file filename)
2259 (with-output-to-file filename
2262 (define (print-hex n)
2263 (display (string-ref "0123456789ABCDEF" n)))
2265 (define (print-byte n)
2266 (print-hex (quotient n 16))
2267 (print-hex (modulo n 16)))
2269 (define (print-line type addr bytes)
2270 (let ((n (length bytes))
2271 (addr-hi (quotient addr 256))
2272 (addr-lo (modulo addr 256)))
2275 (print-byte addr-hi)
2276 (print-byte addr-lo)
2278 (for-each print-byte bytes)
2280 (modulo (- (apply + n addr-hi addr-lo type bytes)) 256)))
2284 (let loop ((lst (cdr asm-code-stream))
2287 (if (not (null? lst))
2288 (let ((x (car lst)))
2290 (let ((kind (vector-ref x 0)))
2291 (if (not (eq? kind 'LISTING))
2292 (compiler-internal-error
2293 "asm-write-hex-file, code stream not assembled"))
2301 (if (= (modulo pos 16) 0)
2304 (- pos (length rev-bytes))
2305 (reverse rev-bytes))
2312 (if (not (null? rev-bytes))
2314 (- pos (length rev-bytes))
2315 (reverse rev-bytes)))
2316 (print-line 1 0 '())
2319 (display (- pos asm-start-pos) ##stderr-port)
2320 (display " bytes\n" ##stderr-port)))))))))
2324 (define asm-start-pos #f) ; start position of the code stream
2325 (define asm-big-endian? #f) ; endianness to use
2326 (define asm-code-stream #f) ; current code stream
2328 (define (asm-make-stream) ; create an empty stream
2329 (let ((x (cons '() '())))
2333 (define (asm-code-extend item) ; add an item at the end of current code stream
2334 (let* ((stream asm-code-stream)
2336 (cell (cons item '())))
2337 (set-cdr! tail cell)
2338 (set-car! stream cell)))
2340 (define (asm-pass1) ; construct fixup list and make first label assignment
2341 (let loop ((curr (cdr asm-code-stream))
2344 (pos asm-start-pos))
2347 (let ((x (car curr)))
2349 (let ((kind (vector-ref x 0)))
2350 (cond ((eq? kind 'LABEL)
2351 (vector-set! x 1 pos) ; first approximation of position
2352 (loop (cdr curr) (cons (cons span curr) fixup-lst) 0 pos))
2353 ((eq? kind 'DEFERRED)
2354 (loop (cdr curr) (cons (cons span curr) fixup-lst) 0 pos))
2356 (loop (cdr curr) fixup-lst span pos))))
2357 (loop (cdr curr) fixup-lst (+ span 1) (+ pos 1)))))))
2359 ;(##declare (generic))
2361 (define (asm-bits-0-to-7 n) ; return bits 0 to 7 of a signed integer
2364 (define (asm-bits-8-and-up n) ; return bits 8 and up of a signed integer
2367 (- (quotient (+ n 1) #x100) 1)))
2369 (define (asm-bits-16-and-up n) ; return bits 16 and up of a signed integer
2371 (quotient n #x10000)
2372 (- (quotient (+ n 1) #x10000) 1)))
2374 (define (asm-bits-32-and-up n) ; return bits 32 and up of a signed integer
2376 (quotient n #x100000000)
2377 (- (quotient (+ n 1) #x100000000) 1)))
2379 ; The following procedures convert floating point numbers into their
2380 ; machine representation. They perform bignum and flonum arithmetic.
2382 (define (asm-float->inexact-exponential-format x)
2384 (define (exp-form-pos x y i)
2385 (let ((i*2 (+ i i)))
2386 (let ((z (if (and (not (< asm-ieee-e-bias i*2))
2388 (exp-form-pos x (* y y) i*2)
2390 (let ((a (car z)) (b (cdr z)))
2391 (let ((i+b (+ i b)))
2392 (if (and (not (< asm-ieee-e-bias i+b))
2395 (set-car! z (/ a y))
2399 (define (exp-form-neg x y i)
2400 (let ((i*2 (+ i i)))
2401 (let ((z (if (and (< i*2 asm-ieee-e-bias-minus-1)
2403 (exp-form-neg x (* y y) i*2)
2405 (let ((a (car z)) (b (cdr z)))
2406 (let ((i+b (+ i b)))
2407 (if (and (< i+b asm-ieee-e-bias-minus-1)
2410 (set-car! z (/ a y))
2414 (define (exp-form x)
2415 (if (< x asm-inexact-+1)
2416 (let ((z (exp-form-neg x asm-inexact-+1/2 1)))
2417 (set-car! z (* asm-inexact-+2 (car z)))
2418 (set-cdr! z (- -1 (cdr z)))
2420 (exp-form-pos x asm-inexact-+2 1)))
2423 (let ((z (exp-form (- asm-inexact-0 x))))
2424 (set-car! z (- asm-inexact-0 (car z)))
2428 (define (asm-float->exact-exponential-format x)
2429 (let ((z (asm-float->inexact-exponential-format x)))
2431 (cond ((not (< y asm-inexact-+2))
2432 (set-car! z asm-ieee-+m-min)
2433 (set-cdr! z asm-ieee-e-bias-plus-1))
2434 ((not (< asm-inexact--2 y))
2435 (set-car! z asm-ieee--m-min)
2436 (set-cdr! z asm-ieee-e-bias-plus-1))
2439 (truncate (inexact->exact (* (car z) asm-inexact-m-min))))))
2440 (set-cdr! z (- (cdr z) asm-ieee-m-bits))
2443 (define (asm-float->bits x) ; returns the 64 bit integer encoding the float "x"
2446 (if (< a asm-ieee-+m-min)
2448 (+ (- a asm-ieee-+m-min)
2449 (* (+ (+ b asm-ieee-m-bits) asm-ieee-e-bias)
2452 (let ((z (asm-float->exact-exponential-format x)))
2453 (let ((a (car z)) (b (cdr z)))
2455 (+ asm-ieee-sign-bit (bits (- 0 a) b))
2458 ; Parameters for ANSI-IEEE Std 754-1985 representation of
2459 ; doubles (i.e. 64 bit floating point numbers):
2461 (define asm-ieee-m-bits 52)
2462 (define asm-ieee-e-bits 11)
2463 (define asm-ieee-+m-min 4503599627370496) ; (expt 2 asm-ieee-m-bits)
2464 (define asm-ieee--m-min -4503599627370496) ; (- asm-ieee-+m-min)
2465 (define asm-ieee-sign-bit #x8000000000000000); (expt 2 (+ asm-ieee-e-bits asm-ieee-m-bits))
2467 (define asm-ieee-e-bias 1023) ; (- (expt 2 (- asm-ieee-e-bits 1)) 1)
2468 (define asm-ieee-e-bias-plus-1 1024) ; (+ asm-ieee-e-bias 1)
2469 (define asm-ieee-e-bias-minus-1 1022) ; (- asm-ieee-e-bias 1)
2471 (define asm-inexact-m-min (exact->inexact asm-ieee-+m-min))
2472 (define asm-inexact-+2 (exact->inexact 2))
2473 (define asm-inexact--2 (exact->inexact -2))
2474 (define asm-inexact-+1 (exact->inexact 1))
2475 (define asm-inexact-+1/2 (exact->inexact (/ 1 2)))
2476 (define asm-inexact-0 (exact->inexact 0))
2478 ;------------------------------------------------------------------------------
2480 (define min-fixnum-encoding 3)
2481 (define min-fixnum 0)
2482 (define max-fixnum 255)
2483 (define min-rom-encoding (+ min-fixnum-encoding (- max-fixnum min-fixnum) 1))
2484 (define min-ram-encoding 512)
2485 (define max-ram-encoding 4095)
2486 (define min-vec-encoding 4096)
2487 (define max-vec-encoding 8191)
2489 (define code-start #x5000)
2491 (define (predef-constants) (list))
2493 (define (predef-globals) (list))
2495 (define (encode-direct obj)
2502 ((and (integer? obj)
2505 (<= obj max-fixnum))
2506 (+ obj (- min-fixnum-encoding min-fixnum)))
2510 (define (translate-constant obj)
2515 (define (encode-constant obj constants)
2516 (let ((o (translate-constant obj)))
2517 (let ((e (encode-direct o)))
2520 (let ((x (assoc o constants))) ;; TODO was assq
2522 (vector-ref (cdr x) 0)
2523 (compiler-error "unknown object" obj)))))))
2525 (define (add-constant obj constants from-code? cont)
2526 (let ((o (translate-constant obj)))
2527 (let ((e (encode-direct o)))
2530 (let ((x (assoc o constants))) ;; TODO was assq
2534 (vector-set! (cdr x) 2 (+ (vector-ref (cdr x) 2) 1)))
2538 (asm-make-label 'constant)
2542 (cons (cons o descr)
2544 (cond ((pair? o) ;; TODO what to do in the case of a pair of, for example, fixnums, where only one object is actually used ?
2545 (add-constants (list (car o) (cdr o))
2549 (cont new-constants))
2551 (let ((chars (map char->integer (string->list o))))
2552 (vector-set! descr 3 chars)
2558 (let ((elems (vector->list o)))
2559 (vector-set! descr 3 elems)
2564 ((u8vector? o) ;; NEW, for now they are lists
2565 (let ((elems (u8vector->list o)))
2566 (vector-set! descr 3 elems)
2572 (cont new-constants))))))))))
2574 (define (add-constants objs constants cont)
2577 (add-constant (car objs)
2580 (lambda (new-constants)
2581 (add-constants (cdr objs)
2585 (define (add-global var globals cont)
2586 (let ((x (assq var globals)))
2590 (cons (cons var (length globals))
2592 (cont new-globals)))))
2594 (define (sort-constants constants)
2596 (sort-list constants
2598 (> (vector-ref (cdr x) 2)
2599 (vector-ref (cdr y) 2))))))
2600 (let loop ((i min-rom-encoding)
2603 (if (> i min-ram-encoding)
2604 (compiler-error "too many constants")
2607 (vector-set! (cdr (car lst)) 0 i)
2612 (lambda (code hex-filename)
2613 (let loop1 ((lst code)
2614 (constants (predef-constants))
2615 (globals (predef-globals))
2619 (let ((instr (car lst)))
2620 (cond ((number? instr)
2624 (cons (cons instr (asm-make-label 'label))
2626 ((eq? (car instr) 'push-constant)
2627 (add-constant (cadr instr)
2630 (lambda (new-constants)
2635 ((memq (car instr) '(push-global set-global))
2636 (add-global (cadr instr)
2638 (lambda (new-globals)
2649 (let ((constants (sort-constants constants)))
2651 (define (label-instr label opcode)
2656 (let ((pos (- (asm-label-pos label) code-start)))
2658 (asm-8 (quotient pos 256))
2659 (asm-8 (modulo pos 256))))))
2661 (define (push-constant n)
2666 (asm-8 (quotient n 256)) ;; BREGG this is a test, the compiler cannot know about anything over 256 (as long as no rom goes higher, which might change, watch out for this), so no need for 13 bits OOPS, actually, 8 is not enough for fixnums and rom, revert to 12 and use some of the free instrs ?
2667 (asm-8 (modulo n 256))))) ;; TODO with 13-bit objects, we need 2 bytes, maybe limit to 12, so we could use a byte and a half, but we'd need to use an opcode with only 4 bits, maybe the call/jump stuff can be combined ? FOOBAR
2669 (define (push-stack n)
2671 (compiler-error "stack is too deep")
2672 (asm-8 (+ #x20 n))))
2674 (define (push-global n)
2675 (asm-8 (+ #x40 n)) ;; TODO maybe do the same as for csts, have a push-long-global to have more ?
2677 ;; (compiler-error "too many global variables")
2678 ;; (asm-8 (+ #x40 n)))
2679 ) ;; TODO actually inline most, or put as csts
2681 (define (set-global n)
2683 ;; (if (> n 15) ;; ADDED prevented the stack from compiling
2684 ;; (compiler-error "too many global variables")
2685 ;; (asm-8 (+ #x50 n)))
2690 (compiler-error "call has too many arguments")
2691 (asm-8 (+ #x60 n))))
2695 (compiler-error "call has too many arguments")
2696 (asm-8 (+ #x70 n))))
2698 (define (call-toplevel label)
2699 (label-instr label #x80))
2701 (define (jump-toplevel label)
2702 (label-instr label #x81))
2704 (define (goto label)
2705 (label-instr label #x82))
2707 (define (goto-if-false label)
2708 (label-instr label #x83))
2710 (define (closure label)
2711 (label-instr label #x84))
2716 (define (prim.number?) (prim 0))
2717 (define (prim.+) (prim 1))
2718 (define (prim.-) (prim 2))
2719 (define (prim.*) (prim 3))
2720 (define (prim.quotient) (prim 4))
2721 (define (prim.remainder) (prim 5))
2722 (define (prim.neg) (prim 6))
2723 (define (prim.=) (prim 7))
2724 (define (prim.<) (prim 8))
2725 (define (prim.ior) (prim 9))
2726 (define (prim.>) (prim 10))
2727 (define (prim.xor) (prim 11))
2728 (define (prim.pair?) (prim 12))
2729 (define (prim.cons) (prim 13))
2730 (define (prim.car) (prim 14))
2731 (define (prim.cdr) (prim 15))
2732 (define (prim.set-car!) (prim 16))
2733 (define (prim.set-cdr!) (prim 17))
2734 (define (prim.null?) (prim 18))
2735 (define (prim.eq?) (prim 19))
2736 (define (prim.not) (prim 20))
2737 (define (prim.get-cont) (prim 21))
2738 (define (prim.graft-to-cont) (prim 22))
2739 (define (prim.return-to-cont) (prim 23))
2740 (define (prim.halt) (prim 24))
2741 (define (prim.symbol?) (prim 25))
2742 (define (prim.string?) (prim 26))
2743 (define (prim.string->list) (prim 27))
2744 (define (prim.list->string) (prim 28))
2746 (define (prim.make-u8vector) (prim 29))
2747 (define (prim.u8vector-ref) (prim 30))
2748 (define (prim.u8vector-set!) (prim 31))
2750 (define (prim.print) (prim 32))
2751 (define (prim.clock) (prim 33))
2752 (define (prim.motor) (prim 34))
2753 (define (prim.led) (prim 35))
2754 (define (prim.led2-color) (prim 36))
2755 (define (prim.getchar-wait) (prim 37))
2756 (define (prim.putchar) (prim 38))
2757 (define (prim.beep) (prim 39))
2758 (define (prim.adc) (prim 40))
2759 (define (prim.u8vector?) (prim 41)) ;; TODO was dac
2760 (define (prim.sernum) (prim 42)) ;; TODO necessary ?
2761 (define (prim.u8vector-length) (prim 43))
2763 (define (prim.shift) (prim 45))
2764 (define (prim.pop) (prim 46))
2765 (define (prim.return) (prim 47))
2767 (define big-endian? #f)
2769 (asm-begin! code-start #f)
2773 (asm-8 (length constants))
2776 (pp (list constants: constants globals: globals)) ;; TODO debug
2780 (let* ((descr (cdr x))
2781 (label (vector-ref descr 1))
2784 ;; see the vm source for a description of encodings
2785 (cond ((and (integer? obj) (exact? obj))
2787 (asm-8 (bitwise-and (arithmetic-shift obj -16) 255))
2788 (asm-8 (bitwise-and (arithmetic-shift obj -8) 255))
2789 (asm-8 (bitwise-and obj 255)))
2791 (let ((obj-car (encode-constant (car obj) constants))
2792 (obj-cdr (encode-constant (cdr obj) constants)))
2793 (asm-8 (+ #x80 (arithmetic-shift obj-car -8)))
2794 (asm-8 (bitwise-and obj-car #xff))
2795 (asm-8 (+ 0 (arithmetic-shift obj-cdr -8)))
2796 (asm-8 (bitwise-and obj-cdr #xff))))
2803 (let ((obj-enc (encode-constant (vector-ref descr 3)
2805 (asm-8 (+ #x80 (arithmetic-shift obj-enc -8)))
2806 (asm-8 (bitwise-and obj-enc #xff))
2809 ((vector? obj) ;; BREGG change this, we have no ordinary vectors
2810 ;; TODO this is the OLD representation, NOT GOOD (but not used) BREGG
2811 (let ((obj-enc (encode-constant (vector-ref descr 3)
2813 (asm-8 (+ #x80 (arithmetic-shift obj-enc -8)))
2814 (asm-8 (bitwise-and obj-enc #xff))
2817 ((u8vector? obj) ;; NEW, lists for now (internal representation same as ordinary vectors, who don't actually exist)
2818 (let ((obj-enc (encode-constant (vector-ref descr 3)
2820 (l (length (vector-ref descr 3))))
2821 (asm-8 (+ #x80 (arithmetic-shift l -8)))
2822 (asm-8 (bitwise-and l #xff))
2823 (asm-8 (+ #x60 (arithmetic-shift obj-enc -8)))
2824 (asm-8 (bitwise-and obj-enc #xff))))
2826 (compiler-error "unknown object type" obj)))))
2829 (let loop2 ((lst code))
2831 (let ((instr (car lst)))
2833 (cond ((number? instr)
2834 (let ((label (cdr (assq instr labels))))
2837 ((eq? (car instr) 'entry)
2838 (let ((np (cadr instr))
2839 (rest? (caddr instr)))
2840 (asm-8 (if rest? (- np) np))))
2842 ((eq? (car instr) 'push-constant) ;; TODO FOOBAR 12 bits for constants now (actually, I don't think it matters here)
2843 (let ((n (encode-constant (cadr instr) constants)))
2846 ((eq? (car instr) 'push-stack)
2847 (push-stack (cadr instr)))
2849 ((eq? (car instr) 'push-global)
2850 (push-global (cdr (assq (cadr instr) globals))))
2852 ((eq? (car instr) 'set-global)
2853 (set-global (cdr (assq (cadr instr) globals))))
2855 ((eq? (car instr) 'call)
2856 (call (cadr instr)))
2858 ((eq? (car instr) 'jump)
2859 (jump (cadr instr)))
2861 ((eq? (car instr) 'call-toplevel)
2862 (let ((label (cdr (assq (cadr instr) labels))))
2863 (call-toplevel label)))
2865 ((eq? (car instr) 'jump-toplevel)
2866 (let ((label (cdr (assq (cadr instr) labels))))
2867 (jump-toplevel label)))
2869 ((eq? (car instr) 'goto)
2870 (let ((label (cdr (assq (cadr instr) labels))))
2873 ((eq? (car instr) 'goto-if-false)
2874 (let ((label (cdr (assq (cadr instr) labels))))
2875 (goto-if-false label)))
2877 ((eq? (car instr) 'closure)
2878 (let ((label (cdr (assq (cadr instr) labels))))
2881 ((eq? (car instr) 'prim)
2883 ((#%number?) (prim.number?))
2887 ((#%quotient) (prim.quotient))
2888 ((#%remainder) (prim.remainder))
2889 ((#%neg) (prim.neg))
2892 ((#%ior) (prim.ior))
2894 ((#%xor) (prim.xor))
2895 ((#%pair?) (prim.pair?))
2896 ((#%cons) (prim.cons))
2897 ((#%car) (prim.car))
2898 ((#%cdr) (prim.cdr))
2899 ((#%set-car!) (prim.set-car!))
2900 ((#%set-cdr!) (prim.set-cdr!))
2901 ((#%null?) (prim.null?))
2902 ((#%eq?) (prim.eq?))
2903 ((#%not) (prim.not))
2904 ((#%get-cont) (prim.get-cont))
2905 ((#%graft-to-cont) (prim.graft-to-cont))
2906 ((#%return-to-cont) (prim.return-to-cont))
2907 ((#%halt) (prim.halt))
2908 ((#%symbol?) (prim.symbol?))
2909 ((#%string?) (prim.string?))
2910 ((#%string->list) (prim.string->list))
2911 ((#%list->string) (prim.list->string))
2912 ((#%make-u8vector) (prim.make-u8vector))
2913 ((#%u8vector-ref) (prim.u8vector-ref))
2914 ((#%u8vector-set!) (prim.u8vector-set!))
2916 ((#%print) (prim.print))
2917 ((#%clock) (prim.clock))
2918 ((#%motor) (prim.motor))
2919 ((#%led) (prim.led))
2920 ((#%led2-color) (prim.led2-color))
2921 ((#%getchar-wait ) (prim.getchar-wait))
2922 ((#%putchar) (prim.putchar))
2923 ((#%beep) (prim.beep))
2924 ((#%adc) (prim.adc))
2925 ((#%u8vector?) (prim.u8vector?)) ;; TODO was dac
2926 ((#%sernum) (prim.sernum))
2927 ((#%u8vector-length) (prim.u8vector-length))
2929 (compiler-error "unknown primitive" (cadr instr)))))
2931 ((eq? (car instr) 'return)
2934 ((eq? (car instr) 'pop)
2937 ((eq? (car instr) 'shift)
2941 (compiler-error "unknown instruction" instr)))
2943 (loop2 (cdr lst)))))
2947 (asm-write-hex-file hex-filename)
2952 (lambda (hex-filename)
2956 (shell-command "gcc -o picobit-vm picobit-vm.c")
2957 (shell-command (string-append "./picobit-vm " hex-filename)))
2958 (shell-command (string-append "./robot . 1 " hex-filename)))))
2960 (define (sort-list l <?)
2962 (define (mergesort l)
2964 (define (merge l1 l2)
2965 (cond ((null? l1) l2)
2968 (let ((e1 (car l1)) (e2 (car l2)))
2970 (cons e1 (merge (cdr l1) l2))
2971 (cons e2 (merge l1 (cdr l2))))))))
2974 (if (or (null? l) (null? (cdr l)))
2976 (cons (car l) (split (cddr l)))))
2978 (if (or (null? l) (null? (cdr l)))
2980 (let* ((l1 (mergesort (split l)))
2981 (l2 (mergesort (split (cdr l)))))
2986 ;------------------------------------------------------------------------------
2990 (let* ((node (parse-file filename))
2993 (path-strip-extension filename)
2996 ; (pp (node->expr node))
2998 (let ((ctx (comp-none node (make-init-context))))
2999 (let ((prog (linearize (optimize-code (context-code ctx)))))
3000 ; (pp (list code: prog env: (context-env ctx)))
3001 (assemble prog hex-filename)
3002 (execute hex-filename))))))
3007 (compile filename)))
3009 ;------------------------------------------------------------------------------
3012 (define (asm-write-hex-file filename)
3013 (with-output-to-file filename
3016 (define (print-hex n)
3017 (display (string-ref "0123456789ABCDEF" n)))
3019 (define (print-byte n)
3021 (print-hex (quotient n 16))
3022 (print-hex (modulo n 16)))
3024 (define (print-line type addr bytes)
3025 (let ((n (length bytes))
3026 (addr-hi (quotient addr 256))
3027 (addr-lo (modulo addr 256)))
3030 ; (print-byte addr-hi)
3031 ; (print-byte addr-lo)
3033 (for-each print-byte bytes)
3035 (modulo (- (apply + n addr-hi addr-lo type bytes)) 256)))
3039 (let loop ((lst (cdr asm-code-stream))
3042 (if (not (null? lst))
3043 (let ((x (car lst)))
3045 (let ((kind (vector-ref x 0)))
3046 (if (not (eq? kind 'LISTING))
3047 (compiler-internal-error
3048 "asm-write-hex-file, code stream not assembled"))
3056 (if (= (modulo pos 8) 0)
3059 (- pos (length rev-bytes))
3060 (reverse rev-bytes))
3067 (if (not (null? rev-bytes))
3069 (- pos (length rev-bytes))
3070 (reverse rev-bytes)))
3071 (print-line 1 0 '())))))))