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interp.rkt
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interp.rkt
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#lang racket
(require racket/fixnum)
(require "utilities.rkt" (prefix-in runtime-config: "runtime-config.rkt"))
(provide interp-scheme interp-C interp-x86 interp-R0 interp-R1 interp-R2 interp-R3
interp-R4 interp-R6)
(define interp-scheme
(lambda (p)
((send (new interp-R6) interp-scheme '()) p)))
(define interp-C
(lambda (p)
((send (new interp-R6) interp-C '()) p)))
(define interp-x86
(lambda (p)
((send (new interp-R6) interp-x86 '()) p)))
;; This (dynamically scoped) parameter is used for goto
(define program (make-parameter '()))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for S0: integer arithmetic and 'let'
(define interp-R0
(class object%
(super-new)
(field (result (gensym 'result)))
(define/public (primitives)
(set '+ '- 'read))
(define/public (interp-op op)
(match op
['+ fx+]
['- (case-lambda
[(n) (fx- 0 n)]
[(n m) (fx- n m)])]
['read read-fixnum]
[else (error "in interp-op S0, unmatched" op)]))
(define/public (interp-scheme env)
(lambda (ast)
(verbose "R0/interp-scheme" ast)
(match ast
[(? symbol?)
(lookup ast env)]
[(? integer?) ast]
[`(let ([,x ,(app (interp-scheme env) v)]) ,body)
((interp-scheme (cons (cons x v) env)) body)]
[`(program ,e) ((interp-scheme '()) e)]
[`(,op ,(app (interp-scheme env) args) ...)
#:when (set-member? (primitives) op)
(apply (interp-op op) args)]
[else
(error (format "no match in interp-scheme S0 for ~a" ast))]
)))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; C0
;;
;; atomic a ::= n | x
;; expr e ::= a | (op a ...)
;; stmt s ::= (assign x e) | (return a)
;; program p ::= (program (x ...) s ...)
(define/public (seq-C env)
(lambda (ss)
(let loop ([env env] [ss ss])
(cond [(null? ss)
env]
[else
(loop ((interp-C env) (car ss))
(cdr ss))]))))
(define/public (interp-C env)
(lambda (ast)
(vomit "R0/interp-C" ast env)
(match ast
[(? symbol? x) (lookup x env)]
[(? integer? i) i]
[`(assign ,x ,e)
(let ([v ((interp-C env) e)])
(cons (cons x v) env))]
[`(return ,e)
(let ([v ((interp-C env) e)])
(cons (cons result v) env))]
[`(program ,xs ,ss ...)
(define env ((seq-C '()) ss))
(lookup result env)]
[`(,op ,args ...) #:when (set-member? (primitives) op)
(apply (interp-op op) (map (interp-C env) args))]
[else
(error "no match in interp-C0 for " ast)]
)))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; psuedo-x86 and x86
;; s,d ::= (var x) | (int n) | (reg r) | (deref r n)
;; i ::= (movq s d) | (addq s d) | (subq s d) | (imulq s d)
;; | (negq d) | (callq f)
;; psuedo-x86 ::= (program (x ...) i ...)
(define/public (get-name ast)
(match ast
[(or `(var ,x) `(reg ,x)) x]
[`(deref rbp ,n) n]
[else
(error 'interp-R0/get-name "doesn't have a name: ~a" ast)]))
(field [x86-ops (make-immutable-hash
`((addq 2 ,+)
(subq 2 ,(lambda (s d) (- d s)))
(negq 1 ,-)))])
(define/public (interp-x86-op op)
(define (err)
(error 'interp-R0/interp-x86-op "unmatched ~a" op))
(cadr (hash-ref x86-ops op err)))
(define/public (interp-x86-exp env)
(lambda (ast)
(vomit "interp-x86-exp" ast)
(match ast
[(or `(var ,x) `(reg ,x))
(lookup (get-name ast) env)]
[`(deref ,r ,n)
(lookup (get-name ast) env)]
[`(int ,n) n]
[else
(error 'interp-R0/interp-x86-exp "unhandled ~a" ast)])))
(define/public (interp-x86 env)
(lambda (ast)
(when (pair? ast)
(vomit "R0/interp-x86" (car ast) env))
(match ast
['() env]
[`((callq read_int) . ,ss)
((interp-x86 (cons (cons 'rax (read)) env)) ss)]
[`((movq ,s ,d) . ,ss)
(define x (get-name d))
(define v ((interp-x86-exp env) s))
((interp-x86 (cons (cons x v) env)) ss)]
[`(program ,xs ,ss ...)
(let ([env ((interp-x86 '()) ss)])
(lookup 'rax env))]
[`((,binary-op ,s ,d) . ,ss)
(let ([s ((interp-x86-exp env) s)]
[d ((interp-x86-exp env) d)]
[x (get-name d)]
[f (interp-x86-op binary-op)])
((interp-x86 (cons (cons x (f d s)) env)) ss))]
[`((,unary-op ,d) . ,ss)
(let ([d ((interp-x86-exp env) d)]
[x (get-name d)]
[f (interp-x86-op unary-op)])
((interp-x86 (cons (cons x (f d)) env)) ss))]
[else (error "no match in interp-x86 S0 for " ast)]
)))
)) ;; class interp-R0
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for S1: Booleans and conditionals
(define interp-R1
(class interp-R0
(super-new)
(inherit seq-C)
(inherit-field x86-ops)
(define/override (primitives)
(set-union (super primitives)
(set 'eq? 'and 'or 'not)))
(define/override (interp-op op)
(match op
['eq? (lambda (v1 v2)
(cond [(and (fixnum? v1) (fixnum? v2)) (eq? v1 v2)]
[(and (boolean? v1) (boolean? v2)) (eq? v1 v2)]))]
['< (lambda (v1 v2)
(cond [(and (fixnum? v1) (fixnum? v2)) (< v1 v2)]))]
['<= (lambda (v1 v2)
(cond [(and (fixnum? v1) (fixnum? v2)) (<= v1 v2)]))]
['> (lambda (v1 v2)
(cond [(and (fixnum? v1) (fixnum? v2)) (> v1 v2)]))]
['>= (lambda (v1 v2)
(cond [(and (fixnum? v1) (fixnum? v2)) (>= v1 v2)]))]
['not (lambda (v) (match v [#t #f] [#f #t]))]
['and (lambda (v1 v2)
(cond [(and (boolean? v1) (boolean? v2))
(and v1 v2)]))]
[else (super interp-op op)]))
(define/override (interp-scheme env)
(lambda (ast)
(verbose "R1/interp-scheme" ast)
(match ast
[`(has-type ,e ,t) ((interp-scheme env) e)]
[#t #t]
[#f #f]
[`(and ,e1 ,e2)
(match ((interp-scheme env) e1)
[#t (match ((interp-scheme env) e2)
[#t #t] [#f #f])]
[#f #f])]
[`(if ,cnd ,thn ,els)
(if ((interp-scheme env) cnd)
((interp-scheme env) thn)
((interp-scheme env) els))]
[`(program (type ,ty) ,e) ((interp-scheme '()) e)]
[else ((super interp-scheme env) ast)]
)))
(define/override (interp-C env)
(lambda (ast)
(vomit "R1/interp-C" ast)
(match ast
[`(has-type ,e ,t) ((interp-C env) e)]
[#t #t]
[#f #f]
[`(if ,cnd ,thn ,els)
(if ((interp-C env) cnd)
((seq-C env) thn)
((seq-C env) els))]
[`(program ,xs (type ,ty) ,ss ...)
((super interp-C env) `(program ,xs ,@ss))]
[else ((super interp-C env) ast)]
)))
(define (goto-label label ss)
(cond [(null? ss)
(error "goto-label, couldn't find label" label)]
[else
(match (car ss)
[`(label ,l) #:when (eq? l label)
(cdr ss)]
[else
(goto-label label (cdr ss))])]))
(define byte2full-reg
(lambda (r)
(match r
['al 'rax]
['bl 'rbx]
['cl 'rcx]
['dl 'rdx]
)))
(define/override (get-name ast)
(match ast
[`(byte-reg ,r)
(super get-name `(reg ,(byte2full-reg r)))]
[else (super get-name ast)]))
;; Extending the set of known operators is essentially the
;; same as overriding the interp-x86-op with new functionallity
(set! x86-ops (hash-set* x86-ops
'notq `(1 ,bitwise-not)
'andq `(2 ,bitwise-and)
'xorq `(2 ,bitwise-xor)))
(define/override (interp-x86-exp env)
(lambda (ast)
(vomit "interp-x86-exp" ast)
(match ast
[`(byte-reg ,r)
((interp-x86-exp env) `(reg ,(byte2full-reg r)))]
[#t 1]
[#f 0]
[`(eq? ,e1 ,e2)
(if (eq? ((interp-x86-exp env) e1)
((interp-x86-exp env) e2))
1 0)]
[`(< ,e1 ,e2)
(if (< ((interp-x86-exp env) e1)
((interp-x86-exp env) e2))
1 0)]
[`(<= ,e1 ,e2)
(if (<= ((interp-x86-exp env) e1)
((interp-x86-exp env) e2))
1 0)]
[`(> ,e1 ,e2)
(if (> ((interp-x86-exp env) e1)
((interp-x86-exp env) e2))
1 0)]
[`(>= ,e1 ,e2)
(if (>= ((interp-x86-exp env) e1)
((interp-x86-exp env) e2))
1 0)]
[else ((super interp-x86-exp env) ast)]
)))
(define (eflags-status env cc)
(match cc
['e
(define eflags ((interp-x86-exp env) '(reg __flag)))
(arithmetic-shift (bitwise-and eflags #b1000000) -6)]
['l
;; Get the value of the lt flag which doesn't actually exist
;; the lt flag is simulated by overflow == sign for x86
(define eflags ((interp-x86-exp env) '(reg __flag)))
(define overflow (bitwise-and eflags #b100000000000))
(define sign (bitwise-and eflags #b000010000000))
(if (= overflow sign) 1 0)]
['le
(or (eflags-status env 'e) (eflags-status env 'l))]
['g
(not (eflags-status env 'le))]
['ge
(not (eflags-status env 'l))]))
(define/override (interp-x86 env)
(lambda (ast)
(when (pair? ast)
(vomit "R1/interp-x86" (car ast) env))
(match ast
[`((set ,cc ,d) . ,ss)
(define name (get-name d))
(define val (eflags-status env cc))
((interp-x86 (cons (cons name val) env)) ss)]
;; if's are present before patch-instructions
[(or `((if ,cnd ,thn ,els) . ,ss)
`((if ,cnd ,thn ,_ ,els ,_) . ,ss))
(if (not (eq? 0 ((interp-x86-exp env) cnd)))
((interp-x86 env) (append thn ss))
((interp-x86 env) (append els ss)))]
[`((label ,l) . ,ss)
((interp-x86 env) ss)]
[`((cmpq ,s1 ,s2) . ,ss)
(let* ([v1 ((interp-x86-exp env) s1)]
[v2 ((interp-x86-exp env) s2)]
[zero (arithmetic-shift (b2i (eq? v1 v2)) 6)]
[eflags (bitwise-ior zero)])
((interp-x86 (cons (cons '__flag eflags) env)) ss))]
[`((movzbq ,s ,d) . ,ss)
(define x (get-name d))
(define v ((interp-x86-exp env) s))
((interp-x86 (cons (cons x v) env)) ss)]
[`((jmp ,label) . ,ss)
((interp-x86 env) (goto-label label (program)))]
[`((jmp-if e ,label) . ,ss)
(let* ([eflags (lookup '__flag env)]
[zero (bitwise-and #b1000000 eflags)]
[zero? (i2b (arithmetic-shift zero -6))])
(cond [zero?
((interp-x86 env) (goto-label label (program)))]
[else ((interp-x86 env) ss)]))]
[`(program ,xs (type ,ty) ,ss ...)
(display-by-type ty ((interp-x86 env) `(program ,xs ,@ss)) env)]
[`(program ,xs ,ss ...)
(parameterize ([program ss])
((super interp-x86 '()) ast))]
[else ((super interp-x86 env) ast)]
)))
(define/public (display-by-type ty val env)
(match ty
['Boolean (if val #t #f)]
['Integer val]
['Void (void)]
['Any `(tagged ,(arithmetic-shift val -2) Integer)]
[else (error (format "don't know how to display type ~a" ty))]))
));; class interp-R1
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for S2: Vectors
(define interp-R2
(class interp-R1
(super-new)
(inherit get-name seq-C interp-x86-op)
(inherit-field x86-ops)
(define/override (display-by-type ty val env)
(match ty
[`(Vector ,tys ...)
(list->vector (map (lambda (ty index) (display-by-type ty ((memory-read) (+ val 8 (* 8 index))) env)) tys (range (length tys))))]
[else (super display-by-type ty val env)]))
;; The simulated global state of the program
;; define produces private fields
(define memory (box '()))
(define uninitialized 'uninitialized-value-from-memory)
(define free_ptr (box uninitialized))
(define fromspace_begin (box uninitialized))
(define fromspace_end (box uninitialized))
(define rootstack_begin (box uninitialized))
(define rootstack_end (box uninitialized))
;; field is like define but public
(field [stack-size (runtime-config:rootstack-size)]
[heap-size (runtime-config:heap-size)]
[global-label-table
(make-immutable-hash
`((free_ptr . ,free_ptr)
(fromspace_begin . ,fromspace_begin)
(fromspace_end . ,fromspace_end)
(rootstack_begin . ,rootstack_begin)
(rootstack_end . ,rootstack_end)))])
(define/public (memory-read)
(lambda (addr)
(let-values ([(start stop name vect) (fetch-page addr)])
(let ([value (vector-ref vect (arithmetic-shift (- addr start) -3))])
(when (equal? value uninitialized)
(error 'interp-R2/memory-read
"read uninitialized memory at address ~s"
addr))
value))))
(define/public (memory-write!)
(lambda (addr value)
(let-values ([(start stop name vect) (fetch-page addr)])
(vector-set! vect (arithmetic-shift (- addr start) -3) value))))
(define/public (collect!)
(lambda (rootset bytes-requested)
;; after a call to collect we must guarantee there is enough
;; memory to allocate the requested block of memory
(let double-heap ([hs heap-size])
(if (< hs bytes-requested)
(double-heap (* 2 hs))
(let ((h-begin (allocate! 'fromspace hs)))
;; I am only advancing the end of the heap because we
;; are not reclaiming memory
(set-box! fromspace_end (+ h-begin hs))
(set-box! free_ptr h-begin))))))
(define/public (initialize!)
(lambda (stack-length heap_length)
(set-box! memory '())
(let* ([s-begin (allocate! 'rootstack stack-size)]
[h-begin (allocate! 'fromspace heap-size)])
(set-box! rootstack_begin s-begin)
(set-box! rootstack_end (+ s-begin stack-size))
(set-box! fromspace_begin h-begin)
(set-box! fromspace_end (+ h-begin heap-size))
(set-box! free_ptr h-begin))))
(define (allocate! name size)
(unless (and (fixnum? size)
(positive? size)
(= 0 (modulo size 8)))
(error 'allocate! "expected non-negative fixnum in ~a" size))
;; Find the last address
(define max-addr
(for/fold ([next 8])
([page (in-list (unbox memory))])
(match-let ([`(page ,_ ,stop ,_ ,_) page])
(max next stop))))
;; Allocate with a small pad 100 words so that it isn't likely to
;; accidentally use another region.
;; The randomness is to dispell any reliance on interp always allocating the
;; same way. -Andre
(define start-addr (+ max-addr 800))
;; The range is of valid addresses in memory are [start, stop)
(define stop-addr (+ start-addr size))
(define vect (make-vector (arithmetic-shift size -3) uninitialized))
(set-box! memory (cons `(page ,start-addr ,stop-addr ,name ,vect)
(unbox memory)))
start-addr)
(define (free! addr)
(set-box! memory
(let loop ([memory (unbox memory)])
(match memory
[`() (error 'free "address ~a isn't currently allocated")]
[`(,(and page `(page ,ptr ,_ ,_ ,_)) . ,pages)
(if (= addr ptr)
pages
(cons page (loop pages)))]))))
(define (fetch-page addr)
;; Create a string containing
(define (fmt-err addr memory)
(apply
string-append
(cons (format "address ~a out of bounds\n\tcurrent memory regions:\n"
addr)
(for/list ([page (in-list (unbox memory))])
(match-let ([`(page ,start ,stop ,name ,_) page])
(format "\t\t~a\t\t[~a,~a)\n" name start stop))))))
(unless (and (fixnum? addr)
(positive? addr))
(error 'fetch-page "expected non-negative fixnum in ~a" addr))
(unless (= 0 (modulo addr 8))
(error 'fetch-page "expected quadword alligned address in ~a" addr))
(let search ([m (unbox memory)])
(match m
[`() (error 'fetch-page (fmt-err addr memory))]
[`((page ,min ,max ,name ,vect) . ,rest-memory)
(vomit "R2/fetch page" addr min max name vect)
(if (and (<= min addr) (< addr max))
(values min max name vect)
(search rest-memory))]
[other (error 'fetch-page "unmatched ~a" m)])))
(define/override (primitives)
(set-union (super primitives)
(set 'vector 'vector-ref 'vector-set!)))
(define/override (interp-op op)
(match op
['eq? (lambda (v1 v2)
(cond [(or (and (fixnum? v1) (fixnum? v2))
(and (boolean? v1) (boolean? v2))
(and (vector? v1) (vector? v2)))
(eq? v1 v2)]))]
['vector vector]
['vector-ref vector-ref]
['vector-set! vector-set!]
[else (super interp-op op)]))
(define/override (interp-scheme env)
(lambda (ast)
(verbose "R2/interp-scheme" ast)
(match ast
[`(void) (void)]
[else ((super interp-scheme env) ast)]
)))
(define (mem-error message expr)
(lambda (who fmt . args)
(error who "~a in ~a raise error:\n~a"
message expr
(apply format (cons fmt args)))))
(define (global-value-err ast)
(lambda ()
(error 'interp-R2 "global label is unknown in ~a" ast)))
(define/public (fetch-global label)
(let* ([err (global-value-err label)]
[ref (hash-ref global-label-table label err)]
[value (unbox ref)])
(when (equal? value uninitialized)
(debug "fetch" global-label-table)
(error 'interp-R2/fetch-global
"global value, ~a, used before initialization"
label))
value))
(define/override (interp-C env)
(lambda (ast)
(vomit "R2/interp-C" ast)
(match ast
[`(void) (void)]
;; I should do better than make these noops - andre
[`(initialize ,s ,h)
(unless (and (exact-nonnegative-integer? s)
(exact-nonnegative-integer? h))
(error "intialize must be called with literals"))
((initialize!) s h)
env]
;; Determine if a collection is needed.
;; Which it isn't because vectors stored in the environment
;; is the representation of the heap in the C language,
;; but collection is a no-op so we should check to see if
;; everything is well formed anyhow.
[`(collection-needed? ,size)
(when (or (eq? (unbox free_ptr) uninitialized)
(eq? (unbox fromspace_end) uninitialized))
(error 'interp-C "uninitialized state in ~a" ast))
#t]
;; Collection isn't needed or possible in this representation
[`(collect ,size)
(unless (exact-nonnegative-integer? ((interp-C env) size))
(error 'interp-C "invalid argument to collect in ~a" ast))
env]
[`(collect ,rs ,size)
(unless (and (exact-nonnegative-integer? ((interp-C env) rs))
(exact-nonnegative-integer? ((interp-C env) size)))
(error 'interp-C "invalid argument(s) to collect in ~a" ast))
env]
;; allocate a vector of length l and type t that is initialized.
[`(allocate ,l) (build-vector l (lambda a uninitialized))]
;; Analysis information making introduce rootstack easier
[`(call-live-roots (,xs ...) ,ss ...)
(for ([x (in-list xs)])
(unless (vector? (lookup x env))
(error 'interp-C
"call-live-roots stores non-root ~a in ~a" x ast)))
((seq-C env) ss)]
[otherwise ((super interp-C env) ast)])))
(define/override (interp-x86-exp env)
(lambda (ast)
(vomit "interp-x86-exp" ast)
(match ast
[`(global-value ,label) (fetch-global label)]
[`(deref ,r ,i) #:when (not (eq? r 'rbp))
(define base ((interp-x86-exp env) `(reg ,r)))
(define addr (+ base i))
((memory-read) addr)]
[else ((super interp-x86-exp env) ast)])))
(define/public (interp-x86-store env)
(lambda (ast value)
(vomit "interp-x86-store" ast value)
(match ast
[`(global-value ,label)
(define loc (hash-ref global-label-table label (global-value-err ast)))
(set-box! loc value)
env]
[`(deref ,r ,i) #:when (not (eq? r 'rbp))
(define base ((interp-x86-exp env) `(reg ,r)))
(define addr (+ base i))
((memory-write!) addr value)
env]
[dest
(define name (get-name dest))
(cons (cons name value) env)])))
(define (x86-binary-op? x)
(let ([val (hash-ref x86-ops x #f)])
(and val (= (car val) 2))))
(define (x86-unary-op? x)
(let ([val (hash-ref x86-ops x #f)])
(and val (= (car val) 1))))
#;(interp-x86 : (env -> (R2-stmt -> env)))
(define/override (interp-x86 env)
(lambda (ast)
(when (pair? ast)
(vomit "R2/interp-x86" (car ast) env))
(match ast
;; cmpq performs a subq operation and examimines the state
;; of the result, this is done without overiting the second
;; register. -andre
;; Notice that the syntax is very confusing
;; (cmpq ,s2 ,s1) (jl then) (jmp else) ...
;; (if (< s1 s2) then else)
[`((cmpq ,s2 ,s1) . ,ss)
(let* ([v1 ((interp-x86-exp env) s1)]
[v2 ((interp-x86-exp env) s2)]
[v3 (- v2 v1)]
[zero (arithmetic-shift (b2i (eq? v3 0)) 6)]
[sign (arithmetic-shift (b2i (< v3 0)) 7)]
;; Our numbers do not overflow so this bit is always 0
[overflow (arithmetic-shift 0 11)]
[eflags (bitwise-ior overflow sign zero)])
((interp-x86 (cons (cons '__flag eflags) env)) ss))]
;; Initialize the state of the "runtime"
[`((callq initialize) . ,ss)
(define stack-size ((interp-x86-exp env) '(reg rdi)))
(define heap-size ((interp-x86-exp env) '(reg rsi)))
((initialize!) stack-size heap-size)
((interp-x86 env) ss)]
[`((callq malloc) . ,ss)
(define num-bytes ((interp-x86-exp env) '(reg rdi)))
((interp-x86 `((rax . ,(allocate! 'malloc num-bytes)) . ,env)) ss)]
[`((callq alloc) . ,ss)
(define num-bytes ((interp-x86-exp env) '(reg rdi)))
((interp-x86 `((rax . ,(allocate! 'alloc num-bytes)) . ,env)) ss)]
[`((callq collect) . ,ss)
(define rootstack ((interp-x86-exp env) '(reg rdi)))
(define bytes-requested ((interp-x86-exp env) '(reg rsi)))
((collect!) rootstack bytes-requested)
((interp-x86 env) ss)]
[`((movq ,s ,d) . ,ss)
(define value ((interp-x86-exp env) s))
(define new-env ((interp-x86-store env) d value))
((interp-x86 new-env) ss)]
[`((,(? x86-binary-op? binop) ,s ,d) . ,ss)
(define src ((interp-x86-exp env) s))
(define dst ((interp-x86-exp env) d))
(define op (interp-x86-op binop))
(define new-env ((interp-x86-store env) d (op src dst)))
((interp-x86 new-env) ss)]
[`((,(? x86-unary-op? unary-op) ,d) . ,ss)
(define dst ((interp-x86-exp env) d))
(define op (interp-x86-op unary-op))
(define new-env ((interp-x86-store env) d (op dst)))
((interp-x86 new-env) ss)]
[else ((super interp-x86 env) ast)])))
));; interp-R2
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for S3: functions
(define interp-R3
(class interp-R2
(super-new)
(inherit primitives seq-C display-by-type interp-op)
(inherit-field result)
(define/public (non-apply-ast)
(set-union (primitives)
(set 'if 'let 'define 'program 'has-type 'void)))
(define/override (interp-scheme env)
(lambda (ast)
(verbose "R3/interp-scheme" ast)
(match ast
[`(define (,f [,xs : ,ps] ...) : ,rt ,body)
(cons f `(lambda ,xs ,body))]
[`(program (type ,ty) ,ds ... ,body)
((interp-scheme env) `(program ,@ds ,body))]
[`(program ,ds ... ,body)
(let ([top-level (map (interp-scheme '()) ds)])
((interp-scheme top-level) body))]
[`(,fun ,args ...) #:when (not (set-member? (non-apply-ast) fun))
(define new-args (map (interp-scheme env) args))
(define fun-val ((interp-scheme env) fun))
(match fun-val
[`(lambda (,xs ...) ,body)
(define new-env (append (map cons xs new-args) env))
((interp-scheme new-env) body)]
[else (error "interp-scheme, expected function, not" fun-val)])]
[else ((super interp-scheme env) ast)]
)))
(define/public (interp-F env)
(lambda (ast)
(verbose "R3/interp-F" ast)
(define result
(match ast
;; For R4
[`(define (,f [,xs : ,ps] ...) : ,rt ,body)
(cons f `(lambda ,xs ,body))]
[`(function-ref ,f)
(lookup f env)]
[`(app ,fun ,args ...)
(define arg-vals (map (interp-F env) args))
(define fun-val ((interp-F env) fun))
(match fun-val
[`(lambda (,xs ...) ,body)
(define new-env (append (map cons xs arg-vals) env))
((interp-F new-env) body)]
[else (error "interp-F, expected function, not" fun-val)])]
[`(program (type ,ty) ,ds ... ,body)
((interp-F env) `(program ,@ds ,body))]
[`(program ,ds ... ,body)
(let ([top-level (map (interp-F '()) ds)])
((interp-F top-level) body))]
;; For R3
[`(void) (void)]
;; For R2
[`(has-type ,e ,t) ((interp-F env) e)]
[#t #t]
[#f #f]
[`(and ,e1 ,e2)
(match ((interp-F env) e1)
[#t (match ((interp-F env) e2)
[#t #t] [#f #f])]
[#f #f])]
[`(if ,cnd ,thn ,els)
(if ((interp-F env) cnd)
((interp-F env) thn)
((interp-F env) els))]
;; For R1
[(? symbol?)
(lookup ast env)]
[(? integer?) ast]
[`(let ([,x ,e]) ,body)
(let ([v ((interp-F env) e)])
((interp-F (cons (cons x v) env)) body))]
[`(program ,e) ((interp-F '()) e)]
[`(,op ,args ...) #:when (set-member? (primitives) op)
(apply (interp-op op) (map (interp-F env) args))]
))
(verbose "R3/interp-F" ast result)
result
))
(define/override (interp-C env)
(lambda (ast)
(verbose "R3/interp-C" ast)
(match ast
[`(define (,f [,xs : ,ps] ...) : ,rt ,locals ,ss ...)
(cons f `(lambda ,xs ,@ss))]
[`(function-ref ,f)
(lookup f env)]
[`(app ,f ,args ...)
(define arg-vals (map (interp-C env) args))
(define f-val ((interp-C env) f))
(match f-val
[`(lambda (,xs ...) ,ss ...)
(define new-env (append (map cons xs arg-vals) env))
(define result-env ((seq-C new-env) ss))
(lookup result result-env)]
[else (error "interp-C, expected a funnction, not" f-val)])]
[`(program ,locals (type ,ty) (defines ,ds ...) ,ss ...)
((interp-C env) `(program ,locals (defines ,@ds) ,@ss))]
[`(program ,locals (defines ,ds ...) ,ss ...)
(define new-env (map (interp-C '()) ds))
(define result-env ((seq-C new-env) ss))
(lookup result result-env)]
[else ((super interp-C env) ast)])))
(define (stack-arg-name n)
(string->symbol (string-append "rsp_" (number->string n))))
(define/public (builtin-funs)
(set 'malloc 'alloc 'collect 'initialize 'read_int))
(define/override (get-name ast)
(match ast
[`(stack-arg ,n) (stack-arg-name n)]
[else (super get-name ast)]))
(define (call-function f-val ss env)
(match f-val
[`(lambda ,n ,body-ss ...)
;; copy some register and stack locations over to new-env
(define passing-regs
(filter (lambda (p) p)
(for/list ([r arg-registers])
(assq r env))))
(define passing-stack
(for/list ([i (in-range
0 (max 0 (- n (vector-length
arg-registers))))])
(define name (stack-arg-name (* i 8)))
(define val (lookup name env))
(define index (+ 16 (* i 8)))
(cons index val)))
(define new-env (append passing-regs passing-stack env))
(define result-env
(parameterize ([program body-ss])
((interp-x86 new-env) body-ss)))
(define res (lookup 'rax result-env))
((interp-x86 (cons (cons 'rax res) env)) ss)]
[else (error "interp-x86, expected a function, not" f-val)]))
(define/override (interp-x86-exp env)
(lambda (ast)
(match ast
[`(stack-arg ,n)
(define x (stack-arg-name n))
(lookup x env)]
[`(function-ref ,f)
(lookup f env)]
[else ((super interp-x86-exp env) ast)])))
(define/override (interp-x86 env)
(lambda (ast)
(when (pair? ast)
(verbose "R3/interp-x86" (car ast) env))
(match ast
[`(define (,f) ,n ,extra ,ss ...)
(cons f `(lambda ,n ,@ss))]
;; Treat lea like mov -Jeremy
[`((leaq ,s ,d) . ,ss)
(define x (get-name d))
(define v ((interp-x86-exp env) s))
((interp-x86 (cons (cons x v) env)) ss)]
[`((indirect-callq ,f) . ,ss)
(define f-val ((interp-x86-exp env) f))
(call-function f-val ss env)]
[`((callq ,f) . ,ss) #:when (not (set-member? (builtin-funs) f))
(call-function (lookup f env) ss env)]
[`(program ,extra (type ,ty) (defines ,ds ...) ,ss ...)
(display-by-type ty ((interp-x86 env)
`(program ,extra (defines ,@ds) ,@ss)) env)]
[`(program ,extra (defines ,ds ...) ,ss ...)
(parameterize ([program ss])
(define env (map (interp-x86 '()) ds))
(define result-env ((interp-x86 env) ss))
(lookup 'rax result-env))]
[else ((super interp-x86 env) ast)])))
)) ;; end interp-R3
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for S4: lambda
(define interp-R4
(class interp-R3
(super-new)
(inherit non-apply-ast)
(inherit-field result)
(define/override (interp-scheme env)
(lambda (ast)
(verbose "R4/interp-scheme" ast)
(match ast
[`(lambda: ([,xs : ,Ts] ...) : ,rT ,body)
`(lambda ,xs ,body ,env)]
[`(define (,f [,xs : ,ps] ...) : ,rt ,body)
(mcons f `(lambda ,xs ,body))]
[`(program (type ,ty) ,ds ... ,body)
((interp-scheme env) `(program ,@ds ,body))]
[`(program ,ds ... ,body)
(let ([top-level (map (interp-scheme '()) ds)])
;; Use set-cdr! on define lambda's for mutual recursion
(for/list ([b top-level])
(set-mcdr! b (match (mcdr b)
[`(lambda ,xs ,body)
`(lambda ,xs ,body ,top-level)])))
((interp-scheme top-level) body))]
[`(,fun ,args ...) #:when (not (set-member? (non-apply-ast) fun))
(define arg-vals (map (interp-scheme env) args))
(define fun-val ((interp-scheme env) fun))
(match fun-val
[`(lambda (,xs ...) ,body ,lam-env)
(define new-env (append (map cons xs arg-vals) lam-env))
((interp-scheme new-env) body)]
[else (error "interp-scheme, expected function, not" fun-val)])]
[else ((super interp-scheme env) ast)]
)))
(define/override (interp-F env)
(lambda (ast)
(verbose "R4/interp-F" ast)
(match ast
[`(lambda: ([,xs : ,Ts] ...) : ,rT ,body)
`(lambda ,xs ,body ,env)]
[`(define (,f [,xs : ,ps] ...) : ,rt ,body)
(mcons f `(lambda ,xs ,body))]
[`(program (type ,ty) ,ds ... ,body)
((interp-F env) `(program ,@ds ,body))]
[`(program ,ds ... ,body)
(let ([top-level (map (interp-F '()) ds)])
;; Use set-cdr! on define lambda's for mutual recursion
(for/list ([b top-level])
(set-mcdr! b (match (mcdr b)
[`(lambda ,xs ,body)
`(lambda ,xs ,body ,top-level)])))
((interp-F top-level) body))]
[`(app ,fun ,args ...)
(define arg-vals (map (interp-F env) args))
(define fun-val ((interp-F env) fun))
(match fun-val
[`(lambda (,xs ...) ,body ,lam-env)
(define new-env (append (map cons xs arg-vals) lam-env))
((interp-F new-env) body)]
[else (error "interp-F, expected function, not" fun-val)])]
[else ((super interp-F env) ast)]
)))
)) ;; end interp-R4
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Interpreters for R6: type Any and inject/project
(define interp-R6
(class interp-R4
(super-new)
(inherit-field result)
(define/override (primitives)
(set-union (super primitives)
(set 'boolean? 'integer? 'vector? 'procedure?)))
(define/override (interp-op op)
(match op
['boolean? (lambda (v)
(match v
[`(tagged ,v1 Boolean) #t]
[else #f]))]
['integer? (lambda (v)
(match v
[`(tagged ,v1 Integer) #t]
[else #f]))]
['vector? (lambda (v)
(match v
[`(tagged ,v1 (Vector ,ts ...)) #t]
[else #f]))]
['procedure? (lambda (v)
(match v
[`(tagged ,v1 (,ts ... -> ,rt)) #t]
[else #f]))]
[else (super interp-op op)]
))
(define/public (tyeq? t1 t2)
;; (display t1) (display " ") (display t2) (newline) (flush-output)
(match `(,t1 ,t2)
[`((Vectorof ,t1) (Vector ,t2s ...))
(foldr (lambda (x y) (and x y)) #t (map (lambda (x) (tyeq? t1 x)) t2s))] ;; wtf racket, why cant i just pass and?
[`((Vector ,t1s ...) (Vectorof ,t2))
(foldr (lambda (x y) (and x y)) #t (map (lambda (x) (tyeq? t2 x)) t1s))]
[else (equal? t1 t2)]))
(define/override (interp-scheme env)
(lambda (ast)
(verbose "R6/interp-scheme" ast)
(define recur (interp-scheme env))
(match ast
[`(inject ,(app recur v) ,t)
`(tagged ,v ,t)]
[`(project ,(app recur v) ,t2)
(match v
[`(tagged ,v1 ,t1)
(cond [(tyeq? t1 t2) v1]