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flow.rkt
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#lang racket
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Polymorphic Flow Analysis
(require "library.rkt"
"data.rkt"
"env.rkt"
"free.rkt"
"intset.rkt"
"unparse.rkt"
"used-before.rkt"
"abstract.rkt"
"contour.rkt"
"callmap.rkt"
"flags.rkt"
"mutrec.rkt")
(provide analyse)
;; Statistics Collection
(set-running-time! 0)
(set-starting-time! 0)
(define init-statistics!
(lambda ()
(set-running-time! 0)
(set-starting-time! (current-inexact-milliseconds))))
(define finish-statistics!
(lambda ()
(set-running-time! (- (current-inexact-milliseconds) starting-time))
(printf "Analyzing took ~a ms~%" running-time)
running-time))
(define analyse
(lambda ()
(set! memo-propagate (memo-rec propagate propagate-compare))
(set! memo-make-read-result (memo make-read-result))
(set! memo-make-recursive-list (memo make-recursive-list))
(set! memo-make-ap-get-args (memo make-ap-get-args))
;; Label the tree and initialize global data structures.
(let ([initial-contour (make-initial-contour)])
(prepare initial-contour)
(init-abstract!)
(init-call-map!)
(init-statistics!)
(init-abstract-statistics!)
;; Here we go!
(propagate tree (make-context initial-contour aenv-empty) aenv-empty)
(propagate-across-edges!)
;; Return the analysis time.
(finish-statistics!))))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Labels
(define read-like-procedures (list %read %eval %get %expand-once))
;; Add labels to expressions.
(define prepare
(lambda (initial-contour)
(define (note-variable! x)
(unless (or (Name-primitive? x) (memq x variables))
(set-variables! (cons x variables))))
(define labels '())
(define fresh-label
(let ([label-counter (generate-counter 0)])
(lambda (e)
(begin0 (label-counter)
(set! labels (cons e labels))))))
(define read-labels (list initial-contour (fresh-label #f) (fresh-label #f)))
(define (prepare e recursive)
;; recursive is a list of names whose recursive definitions we are currently inside
(let ([prep (lambda (e) (prepare e recursive))])
(match e
[(Define x e1)
(note-variable! x)
(prepare e1 (append (or (Name-component x) '()) recursive))]
[(? Defstruct?) #f]
[(? Defmacro?) #f]
[(E: (? Const?))
(set-E-labels! e (list (fresh-label e)))]
[(E: (Var x))
(note-variable! x)
(define l (fresh-label e))
(define ls
(cond [(Name-primitive? x)
;; Most primitives need one "result" label.
(cond [(memq x read-like-procedures)
read-labels]
[(or (Selector? (Name-primop x))
(eq? x %internal-apply))
'()]
[(eq? x %Qmerge-list)
(list (fresh-label #f) (fresh-label #f))]
[else
(list (fresh-label #f))])]
[else
;; For non-primitives, the second "label"
;; marks whether this occurrence is recursive.
;; This should be determined by the parser.
(list (and (Name-let-bound? x)
(not (Name-mutated? x))
(memq x recursive)))]))
(set-E-labels! e (cons l ls))]
[(E: (Lam: x e1))
(prep e1)
(for ([id (in-list x)]) (note-variable! id))
(set-E-labels! e (list (fresh-label e)))]
[(E: (Vlam: x rest e1))
(prep e1)
(for ([id (in-list (cons rest x))]) (note-variable! id))
(set-E-labels! e (list (fresh-label e)))]
[(E: (App e0 args))
(prep e0)
(for ([arg (in-list args)]) (prep arg))
(define l (fresh-label e))
(define ls
(for/list ([_ (in-list (list* #f #f args))])
(fresh-label #f)))
(set-E-labels! e (cons l ls))]
[(E: (Let b e2))
(for ([cl (in-list b)]) (prep cl))
(prep e2)
(set-E-labels! e (list (labelof e2)))]
[(E: (Letr b e2))
(mark-used-before-defined! b)
(for ([cl (in-list b)]) (prep cl))
(prep e2)
(set-E-labels! e (list (labelof e2)))]
[(E: (Begin exps))
(for ([e (in-list exps)]) (prep e))
(set-E-labels! e (list (labelof (rac exps))))]
[(E: (or (And exps) (Or exps)))
(for ([e (in-list exps)]) (prep e))
(set-E-labels! e (list (fresh-label e)))]
[(E: (If test then els))
(prep test)
(prep then)
(prep els)
(set-E-labels! e (list (fresh-label e) (fresh-label #f) (fresh-label #f)))]
[(E: (Set! x body))
(note-variable! x)
(prep body)
(set-E-labels! e (list (fresh-label e)))]
[(E: (Letcc x e1))
(note-variable! x)
(prep e1)
(set-E-labels! e (list (fresh-label e)))]
[_ (error 'prep "Bad ~a" e)])))
(set-variables! '())
(prepare tree '())
(define v (list->vector (reverse labels)))
(set-label->node! (lambda (l) (vector-ref v l)))
(set-n-labels! (vector-length v))))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Abstract Evaluation.
;; Compute abstract values.
(define memo-propagate #f)
(define propagate-compare
(lambda (a b)
(and (= (labelof (car a)) (labelof (car b)))
(equal? (cadr a) (cadr b))
(andmap (lambda (c d)
(and (eq? (car c) (car d))
(equal? (cdr c) (cdr d))))
(env->list (caddr a))
(env->list (caddr b))))))
(define noisy-propagate
(lambda (e k aenv)
(printf "Propagate ~a ~a ~a~%" (labelof e) k (map (lambda (b) (list (pname (car b)) (cdr b))) (env->list aenv)))
(propagate e k aenv)))
;; exp x context x env -> point
(define propagate
(lambda (e k aenv)
(define l (labelof e))
(match e
[(E: (Const c))
(define p (index-result-map l k))
(p+aval p
(match c
[(? symbol?) (aval 'sym l)]
[#t (aval 'true l)]
[#f (aval 'false l)]
['() (aval 'nil l)]
[(? number?) (aval 'num l)]
[(? char?) (aval 'char l)]
[(? string?) (aval 'str l)]
[(? void?) (aval 'void l)]))
p]
[(E: (or (? Lam?) (? Vlam?)))
(define p (index-result-map l k))
(define frees (free-in-exp e))
(define aenv* (aenv-restrict aenv frees))
(p+aval p (aval 'closure l (make-closure-contour k) aenv*))
p]
[(E: (Var x))
(cond [(Name-primitive? x)
(define p (index-result-map l k))
(p+aval p (aval 'prim l))
p]
[(Name-unbound? x)
(define p (index-result-map l k))
(p+aval p (aval 'unbound 0))
p]
[(and (Name-let-bound? x) (not (Name-mutated? x)))
(define let-label (labelof (Name-binding x)))
(define recursive? (recursive-var? e))
(define component (or (Name-component x) (list x)))
(var-split x aenv l k let-label recursive? component)]
[else
(result-map= l k (index-var-map x (aenv-lookup aenv x)))
(index-result-map l k)])]
[(E: (App e0 args))
(let loop ([a* args])
(if (pair? a*)
(p->1 (propagate (car a*) k aenv)
(lambda () (loop (cdr a*))))
;; call e0 functions with args' labels
(p-> (propagate e0 k aenv)
(make-ap-action
l
k
(make-ap-get-args args k (cdr (extra-labels e)))))))
(index-result-map l k)]
[(E: (or (Let b e2) (Letr b e2)))
(define new-aenv
(for/fold ([env aenv])
([cl (in-list b)]
#:when (Define? cl))
(aenv-extend env (Define-name cl) k)))
(define (make-new-k eb)
(make-context
(let-binding-contour (context->contour k) (labelof eb))
new-aenv))
(let loop ([b b])
(match b
[(cons (Define x eb) rest)
(when (Name-used-before-defined? x)
(p+aval (index-var-map x k) (aval 'unspecified 0)))
(let ([p (index-var-map x k)])
(p->p (propagate eb (make-new-k eb) new-aenv) p)
(p->1 p (lambda () (loop rest))))]
[(cons (? E? eb) rest)
(p->1 (propagate eb (make-new-k eb) new-aenv)
(lambda () (loop rest)))]
[(cons _ rest)
(loop rest)]
['()
(propagate e2 k new-aenv)]
[_ (error 'flow "Bad clause in let ~a" b)]))
(index-result-map l k)]
[(E: (Begin exps))
(let eloop ([exps exps])
(when (pair? exps)
(p->1 (propagate (car exps) k aenv)
(lambda () (eloop (cdr exps))))))
(index-result-map l k)]
[(E: (If test then els))
(match-let* ([tst (propagate test k aenv)]
[(list then-lbl else-lbl) (extra-labels e)]
[(cons then-env else-env)
(if If-split
(split-if test k aenv aenv then-lbl else-lbl)
(cons aenv aenv))]
[p (index-result-map l k)])
(p-> tst
(let ([first #t])
(lambda (new)
(when (and first (except-in-avals? '(false) new))
(set! first #f)
(p->p (propagate then k then-env) p)))))
(p-> tst
(let ([first #t])
(lambda (new)
(when (and first (in-avals? '(unspecified unbound false) new))
(set! first #f)
(p->p (propagate els k else-env) p)))))
p)]
[(E: (Set! x body))
(let ([p1 (propagate body k aenv)])
(unless (Name-unbound? x)
(p->p p1 (index-var-map x (aenv-lookup aenv x)))))
(let* ([p (index-result-map l k)])
(p+aval p (aval 'void l))
p)]
[(E: (And exps))
(let* ([p (index-result-map l k)])
(if (null? exps)
(p+aval p (aval 'true l))
(let loop ([exps exps])
(if (pair? (cdr exps))
(p-> (propagate (car exps) k aenv)
(let ([first #t])
(lambda (new)
(when (and first (except-in-avals? '(false) new))
(set! first #f)
(loop (cdr exps)))
(p+avals p (filter-avals '(false unspecified unbound) new)))))
(p->p (propagate (car exps) k aenv) p))))
p)]
[(E: (Or exps))
(let* ([p (index-result-map l k)])
(if (null? exps)
(p+aval p (aval 'false l))
(let loop ([exps exps])
(if (pair? (cdr exps))
(p-> (propagate (car exps) k aenv)
(let ([first #t])
(lambda (new)
(when (and first (in-avals? '(false unspecified unbound) new))
(set! first #f)
(loop (cdr exps)))
(p+avals p (except-avals '(false) new)))))
(p->p (propagate (car exps) k aenv) p))))
p)]
[(E: (Letcc x e1))
(let* ([p (index-result-map l k)]
[aenv (aenv-extend aenv x k)])
(p+aval (index-var-map x k) (aval 'cont l k))
(p->p (propagate e1 k aenv) p)
p)])))
;; Make an edge that filters based on type
(define typed-p->
(lambda (type p1 p2)
(p-> p1
(lambda (new)
(p+avals
p2
(intset-filter (lambda (v) (equal? (aval-type v) type)) new))))))
;; Build arg successor for type-based contours.
(define make-typed-arg-successor
(lambda (contour-maps formals args current-contour eval-body)
(lambda (from contour-map)
(p-> from
(lambda (new)
(intset-for-each
(lambda (v)
(define type (aval-type v))
(unless (assoc type (unbox contour-map))
;; For a new type of arg, compute new contours,
;; record them, evaluate function body in new
;; contours, and add typed edges for all args
;; and all appropriate types to formals.
(define arg-types
(for/list ([z (in-list contour-maps)])
(if (eq? z contour-map)
(list type)
(map car (unbox z)))))
(define new-contours
(make-type-based-contours
arg-types
current-contour))
(set-box! contour-map
(cons (cons type new-contours) (unbox contour-map)))
(for ([c (in-list new-contours)])
(eval-body c)
(for ([formal (in-list formals)]
[arg (in-list args)]
[types (in-list arg-types)])
(typed-p-> type arg (index-var-map formal c))))))
new))))))
(define make-ap-action
(lambda (l k get-args)
(define p (index-result-map l k))
(lambda (fns)
(intset-for-each
(lambda (new)
(define l-closure (aval-label new))
(case (aval-kind new)
[(closure)
(extend-call-map! l-closure l)
(define aenv2 (aval-env new))
(define c (call-site-contour l k (aval-contour new)))
(define (action x arg* eval-body)
(cond
[(and Type (< (contour-length c) Type))
(cond [(null? x) (eval-body c)]
[else
(define contour-maps (map (lambda (_) (box '())) x))
(define arg-successor
(make-typed-arg-successor
contour-maps
x
arg*
c
eval-body))
(for ([arg (in-list arg*)]
[contour (in-list contour-maps)])
(arg-successor arg contour))])]
[else
(for ([arg (in-list arg*)]
[contour (in-list x)])
(p->p arg (index-var-map contour c)))
(eval-body c)]))
(define node (label->node l-closure))
(match node
[(E: (Lam: x e2))
(match (get-args (length x) #f #f)
[#f #f]
[(cons arg* _)
(define (eval-body c)
(define new-aenv
(aenv-extend* aenv2 x (map (lambda (_) c) x)))
(define new-context (make-context c aenv2))
(memo-propagate e2 new-context new-aenv)
(p->p (index-result-map (labelof e2) new-context) p))
(action x arg* eval-body)])]
[(E: (Vlam: x rest e2))
(match (get-args (length x) #f #t)
[#f #f]
[(cons arg* arg-rest)
(define (eval-body c)
(p->p arg-rest (index-var-map rest c))
(let* ([vars (cons rest x)]
[new-aenv (aenv-extend* aenv2 vars (map (lambda (_) c) vars))]
[new-context (make-context c aenv2)])
(memo-propagate e2 new-context new-aenv)
(p->p (index-result-map (labelof e2) new-context) p)))
(action x arg* eval-body)])])]
[(unbound)
(p+aval p (aval 'unbound 0))]
[(cont)
(extend-call-map! l-closure l)
(let ([k2 (aval-contour new)])
(match (label->node l-closure)
[(and e2 (E: (? Letcc?)))
(match (get-args 1 #f #f)
[#f #f]
[`((,arg) . ,_)
(p->p arg (index-result-map (labelof e2) k2))])]))]
[(prim)
(extend-call-map! l-closure l)
(match (label->node l-closure)
[(and e2 (E: (Var x)))
(for-each
(lambda (arity)
(match (if (negative? arity)
(get-args (- (- arity) 1) #t #f)
(get-args arity #f #f))
[#f #f]
[`(,arg* . ,arg-rest)
(cond
[(eq? %internal-apply x)
(let* ([f (car arg*)]
[args-list (cadr arg*)]
[get-args (make-apply-get-args args-list)])
(p-> f (make-ap-action l k get-args)))]
[(or (eq? %vector x) (eq? %Qvector x))
(let* ([l-result (car (extra-labels e2))]
[p-result (index-result-map l-result k)])
(for-each
(lambda (arg) (p->p arg p-result))
arg*)
(when arg-rest
(p->p arg-rest p-result))
(when (zero? (length arg*))
(p+aval p (aval 'vec0 l-result)))
(p+aval p (aval 'vec l-result k p-result)))]
[(eq? %make-vector x)
(let* ([l-result (car (extra-labels e2))]
[p-result (index-result-map l-result k)])
(if (= 2 arity)
(p->p (cadr arg*) p-result)
(p+aval p-result (aval 'unspecified 0)))
(p+aval p (aval 'vec0 l-result))
(p+aval p (aval 'vec l-result k p-result)))]
[(memq x read-like-procedures)
(match (extra-labels e2)
[(list k l3 l4)
(p->p (memo-make-read-result k l3 l4) p)])]
[(eq? %Qlist x)
(let ([l3 (car (extra-labels e2))])
(p->p (memo-make-recursive-list l3 k arg*) p))]
[(eq? %Qmerge-list x)
(let* ([l-result (car (extra-labels e2))]
[lm (cadr (extra-labels e2))]
[pm (index-result-map lm k)])
(for-each
(lambda (arg) (p->p arg pm))
arg*)
(p->p (memo-make-recursive-list l-result k (list pm)) p))]
[else
(match (Name-primop x)
[(Constructor tag)
(let ([l3 (car (extra-labels e2))])
(p+aval p
(apply aval
tag
l ;;; TEMP l3 -> l
k
arg*)))]
[(Selector tag idx)
(p-> (car arg*)
(lambda (new)
(intset-for-each
(lambda (v)
(when (eq? tag (aval-kind v))
(p->p (list-ref (aval-fields v) idx)
p)))
new)))]
[(Mutator tag idx val)
(let ([l3 (car (extra-labels e2))])
(p-> (car arg*)
(lambda (new)
(intset-for-each
(lambda (v)
(when (eq? tag (aval-kind v))
(p->p (list-ref arg* val)
(list-ref (aval-fields v) idx))))
new)))
(p+aval p (aval 'void l3)))]
[(Predicate tags)
(let ([l3 (car (extra-labels e2))])
(p-> (car arg*)
(lambda (new)
(intset-for-each
(lambda (v)
(when (memq (aval-kind v)
`(unspecified unbound ,@tags))
(p+aval p (aval 'true l3)))
(unless (memq (aval-kind v) tags)
(p+aval p (aval 'false l3))))
new))))]
[_
(let ([l3 (car (extra-labels e2))])
(p+avals
p
(list->avals
(map (lambda (c) (aval c l)) ;;; TEMP l3 -> l
(Primitive-result-type (Name-binder x))))))])])]))
(Primitive-arity (Name-binder x)))])]))
fns))))
;; Build a get-args closure for an ordinary application. A get-args
;; closure takes three args: n, or-more?, and rest?. n is the
;; minimum number of args required. or-more? is true if an arbitrary
;; number of args can be accepted. rest? is true if an arbitrary
;; number of args can be accepted and they are to be returned as
;; a list (for a Vlam). Only one of or-more? and rest? may be true.
;; A get-args closure returns
;; #f if the args request cannot be satisfied;
;; a pair of (list of length n) and #f if both or-more? and rest? are false
;; a pair of (list of length >= n) and a rest point if or-more? is true
;; a pair of (list of length n) and a rest point if rest? is true.
(define memo-make-ap-get-args #f) ; not used
(define make-ap-get-args
(lambda (args k labels)
(let ([nargs (length args)]
[largs (map labelof args)])
(lambda (n or-more? rest?)
(if (cond (or-more? (< nargs n))
(rest? (< nargs n))
(else (not (= n nargs))))
#f
(let ([points (map (lambda (l) (index-result-map l k))
(if or-more? largs (sublist largs n)))])
(cons points
(cond [rest? (make-varargs-list
(list-tail largs n)
k
(list-tail labels n))]
[or-more? (if (null? points) #f (car points))]
[else #f]))))))))
;; This function assumes that p includes a single recursive cons
;; whose cdr refers to a program point equivalent to p.
;; This program point is expected to be the result of list-copy.
(define make-apply-get-args
(lambda (p)
(let* ([pairs (intset->list (filter-avals '(cons) (point-elements p)))]
[v (if (= 1 (length pairs))
(car pairs)
(error 'internal-apply "args not correctly formed"))]
[arg-k (aval-contour v)]
[arg-car (car (aval-fields v))])
(lambda (n or-more? rest?)
(cons (iota n arg-car)
(cond (rest? p)
(or-more? arg-car)
(else #f)))))))
(define make-varargs-list
(lambda (largs k labels)
(let ([p (index-result-map (car labels) k)])
(if (null? largs)
(p+aval p (aval 'nil (car labels)))
(begin
(p+aval p (aval 'cons (car labels) k
(index-result-map (car largs) k)
(index-result-map (cadr labels) k)))
(make-varargs-list (cdr largs) k (cdr labels))))
p)))
(define memo-make-read-result #f)
(define make-read-result
(lambda (k l1 l2)
(define p (index-result-map l1 k))
(define p2 (index-result-map l2 k))
(define vals (list
(aval 'nil l1)
(aval 'sym l1)
(aval 'true l1)
(aval 'false l1)
(aval 'num l1)
(aval 'char l1)
(aval 'str l1)
(aval 'cons l1 k p2 p2)
(aval 'vec0 l1)
(aval 'vec l1 k p2)))
(p+avals p2 (list->avals vals))
(p+avals p (list->avals (cons (aval 'eof l1) vals)))
p))
(define memo-make-recursive-list #f)
(define make-recursive-list
(lambda (l k elts)
(let* ([p (index-result-map l k)]
[vals (cons (aval 'nil l)
(map (lambda (elt) (aval 'cons l k elt p))
elts))])
(p+avals p (list->avals vals))
p)))
;; Split variables in the test of an if-expression if we can
;; determine that they have a certain shape in the then and/or else branches.
(define split-if
(lambda (exp k then-env else-env then-label else-label)
(letrec ([split-variable
(lambda (sense tags x-label x)
(let* ([xpoint (index-result-map x-label k)]
[then-contour (if-contour
(aenv-lookup then-env x)
then-label)]
[x-then-point (index-var-map x then-contour)]
[then-env (aenv-extend then-env x then-contour)]
[else-contour (if-contour
(aenv-lookup else-env x)
else-label)]
[x-else-point (index-var-map x else-contour)]
[else-env (aenv-extend else-env x else-contour)]
[f (case sense
[(both)
(lambda (new)
(let ([filtered (filter-avals tags new)])
(p+avals x-then-point filtered)
(p+avals x-else-point filtered)))]
[(#t)
(lambda (new)
(p+avals x-then-point (filter-avals tags new))
(p+avals x-else-point (except-avals tags new)))]
[(#f)
(lambda (new)
(p+avals x-then-point (except-avals tags new))
(p+avals x-else-point (filter-avals tags new)))])])
(p-> xpoint f)
(cons then-env else-env)))]
[find-var-to-split
(lambda (exp then-env else-env)
(match exp
[(E: (App (E: (Var p-or-s)) (list (and (E: (Var x)) expr))))
(define xl (labelof expr))
(cond [(or (Name-mutated? x)
(Name-primitive? x)
(Name-unbound? x)
(not (Name-primitive? p-or-s))
(and (not (Predicate? (Name-primop p-or-s)))
(not (Selector? (Name-primop p-or-s)))))
(cons then-env else-env)]
[(Predicate? (Name-primop p-or-s))
(split-variable #t (Predicate-tag (Name-primop p-or-s)) xl x)]
[else ; Selector
(split-variable 'both (list (Selector-tag (Name-primop p-or-s))) xl x)])]
[(E: (Var x))
(cond [(or (Name-mutated? x) (Name-unbound? x))
(cons then-env else-env)]
[else
(split-variable #f (list 'false) (labelof exp) x)])]
[(E: (App (E: (Var p-or-s)) (list arg)))
(if (and (Name-primitive? p-or-s)
(or (Predicate? (Name-primop p-or-s))
(Selector? (Name-primop p-or-s))))
(find-var-to-split arg then-env else-env)
(cons then-env else-env))]
[(E: (And (list exp)))
(find-var-to-split exp then-env else-env)]
[(E: (And exps))
(let loop ([exps exps] [then-env then-env])
(if (null? exps)
(cons then-env else-env)
(match-let ([`(,then-env . ,_)
(find-var-to-split (car exps) then-env else-env)])
(loop (cdr exps) then-env))))]
[_ (cons then-env else-env)]))])
(find-var-to-split exp then-env else-env))))
(define warn-unused-vars
(lambda ()
(for-each
(lambda (x)
(when (intset-empty? (values-at-var x))
(printf "; Note: ~a never gets a value~%" (pname* x))))
variables)))
(define not-called?
(lambda (v)
(null? (index-call-map (aval-label v)))))
(define warn-uncalled
(lambda ()
(match tree
[(E: (Letr b _))
(for-each
(match-lambda
[(Define x e)
(when (intset-exists?
not-called?
(filter-avals '(closure prim) (values-at-label (labelof e))))
(printf "; Note: ~a is never called~%" (pname* x)))]
[_ #f])
b)])))