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7ed39e96d0
whalesong/compile.rkt
Danny Yoo 7ed39e96d0 still debugging, but something broke
2011-04-05 17:27:17 -04:00

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#lang typed/racket/base
(require "expression-structs.rkt"
"lexical-structs.rkt"
"il-structs.rkt"
"kernel-primitives.rkt"
racket/bool
racket/list)
(provide (rename-out [-compile compile])
compile-general-procedure-call
append-instruction-sequences
adjust-target-depth)
(: -compile (Expression Target Linkage -> (Listof Statement)))
;; Generates the instruction-sequence stream.
;; Note: the toplevel generates the lambda body streams at the head, and then the
;; rest of the instruction stream.
(define (-compile exp target linkage)
(let ([after-lam-bodies (make-label 'afterLamBodies)]
[before-pop-prompt (make-label 'beforePopPrompt)])
(statements
(append-instruction-sequences
(make-instruction-sequence
`(,(make-GotoStatement (make-Label after-lam-bodies))))
(compile-lambda-bodies (collect-all-lams exp))
after-lam-bodies
(make-instruction-sequence
`(,(make-PushControlFrame/Prompt default-continuation-prompt-tag
before-pop-prompt)))
(compile exp '() target prompt-linkage)
before-pop-prompt))))
(define-struct: lam+cenv ([lam : Lam]
[cenv : CompileTimeEnvironment]))
(: collect-all-lams (Expression -> (Listof lam+cenv)))
;; Finds all the lambdas in the expression.
(define (collect-all-lams exp)
(let: loop : (Listof lam+cenv)
([exp : Expression exp]
[cenv : CompileTimeEnvironment '()])
(cond
[(Top? exp)
(loop (Top-code exp) (cons (Top-prefix exp) cenv))]
[(Constant? exp)
'()]
[(LocalRef? exp)
'()]
[(ToplevelRef? exp)
'()]
[(ToplevelSet? exp)
(loop (ToplevelSet-value exp) cenv)]
[(Branch? exp)
(append (loop (Branch-predicate exp) cenv)
(loop (Branch-consequent exp) cenv)
(loop (Branch-alternative exp) cenv))]
[(Lam? exp)
(cons (make-lam+cenv exp cenv)
(loop (Lam-body exp)
(extract-lambda-cenv exp cenv)))]
[(Seq? exp)
(apply append (map (lambda: ([e : Expression]) (loop e cenv))
(Seq-actions exp)))]
[(Splice? exp)
(apply append (map (lambda: ([e : Expression]) (loop e cenv))
(Splice-actions exp)))]
[(App? exp)
(let ([new-cenv (append (build-list (length (App-operands exp)) (lambda: ([i : Natural]) '?))
cenv)])
(append (loop (App-operator exp) new-cenv)
(apply append (map (lambda: ([e : Expression]) (loop e new-cenv)) (App-operands exp)))))]
[(Let1? exp)
(append (loop (Let1-rhs exp)
(cons '? cenv))
(loop (Let1-body exp)
(cons (extract-static-knowledge (Let1-rhs exp) (cons '? cenv))
cenv)))]
[(LetVoid? exp)
(loop (LetVoid-body exp)
(append (build-list (LetVoid-count exp) (lambda: ([i : Natural]) '?))
cenv))]
[(InstallValue? exp)
(loop (InstallValue-body exp) cenv)]
[(BoxEnv? exp)
(loop (BoxEnv-body exp) cenv)]
[(LetRec? exp)
(let ([new-cenv (append (map (lambda: ([p : Lam])
(extract-static-knowledge
p
(append (build-list (length (LetRec-procs exp))
(lambda: ([i : Natural]) '?))
cenv)))
(reverse (LetRec-procs exp)))
cenv)])
(append (apply append
(map (lambda: ([lam : Lam])
(loop lam new-cenv))
(LetRec-procs exp)))
(loop (LetRec-body exp) new-cenv)))])))
(: extract-lambda-cenv (Lam CompileTimeEnvironment -> CompileTimeEnvironment))
(define (extract-lambda-cenv lam cenv)
(append (map (lambda: ([d : Natural])
(list-ref cenv d))
(Lam-closure-map lam))
(build-list (Lam-num-parameters lam) (lambda: ([i : Natural]) '?))))
(: compile (Expression CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; Compiles an expression into an instruction sequence.
(define (compile exp cenv target linkage)
(cond
[(Top? exp)
(compile-top exp cenv target linkage)]
[(Constant? exp)
(compile-constant exp cenv target linkage)]
[(LocalRef? exp)
(compile-local-reference exp cenv target linkage)]
[(ToplevelRef? exp)
(compile-toplevel-reference exp cenv target linkage)]
[(ToplevelSet? exp)
(compile-toplevel-set exp cenv target linkage)]
[(Branch? exp)
(compile-branch exp cenv target linkage)]
[(Lam? exp)
(compile-lambda exp cenv target linkage)]
[(Seq? exp)
(compile-sequence (Seq-actions exp)
cenv
target
linkage)]
[(Splice? exp)
(compile-splice (Splice-actions exp)
cenv
target
linkage)]
[(App? exp)
(compile-application exp cenv target linkage)]
[(Let1? exp)
(compile-let1 exp cenv target linkage)]
[(LetVoid? exp)
(compile-let-void exp cenv target linkage)]
[(InstallValue? exp)
(compile-install-value exp cenv target linkage)]
[(BoxEnv? exp)
(compile-box-environment-value exp cenv target linkage)]
[(LetRec? exp)
(compile-let-rec exp cenv target linkage)]))
(: compile-top (Top CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-top top cenv target linkage)
(let*: ([names : (Listof (U Symbol ModuleVariable False)) (Prefix-names (Top-prefix top))])
(end-with-linkage
linkage cenv
(append-instruction-sequences
(make-instruction-sequence
`(,(make-PerformStatement (make-ExtendEnvironment/Prefix! names))))
(compile (Top-code top) (cons (Top-prefix top) cenv) target next-linkage)
(make-instruction-sequence
`(,(make-PopEnvironment 1 0)))))))
;; Add linkage for expressions.
(: end-with-linkage (Linkage CompileTimeEnvironment InstructionSequence -> InstructionSequence))
(define (end-with-linkage linkage cenv instruction-sequence)
(append-instruction-sequences instruction-sequence
(compile-linkage cenv linkage)))
(: compile-linkage (CompileTimeEnvironment Linkage -> InstructionSequence))
(define (compile-linkage cenv linkage)
(cond
[(ReturnLinkage? linkage)
(make-instruction-sequence `(,(make-AssignPrimOpStatement 'proc (make-GetControlStackLabel))
,(make-PopEnvironment (length cenv) 0)
,(make-PopControlFrame)
,(make-GotoStatement (make-Reg 'proc))))]
[(PromptLinkage? linkage)
(make-instruction-sequence `(,(make-AssignPrimOpStatement 'proc (make-GetControlStackLabel))
,(make-PopControlFrame/Prompt)
,(make-GotoStatement (make-Reg 'proc))))]
[(NextLinkage? linkage)
empty-instruction-sequence]
[(LabelLinkage? linkage)
(make-instruction-sequence `(,(make-GotoStatement (make-Label (LabelLinkage-label linkage)))))]))
(: compile-constant (Constant CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-constant exp cenv target linkage)
(end-with-linkage linkage
cenv
(make-instruction-sequence
`(,(make-AssignImmediateStatement target (make-Const (Constant-v exp)))))))
(: compile-local-reference (LocalRef CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-local-reference exp cenv target linkage)
(end-with-linkage linkage
cenv
(make-instruction-sequence
`(,(make-AssignImmediateStatement
target
(make-EnvLexicalReference (LocalRef-depth exp)
(LocalRef-unbox? exp)))))))
(: compile-toplevel-reference (ToplevelRef CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-toplevel-reference exp cenv target linkage)
(end-with-linkage linkage
cenv
(make-instruction-sequence
`(,(make-PerformStatement (make-CheckToplevelBound!
(ToplevelRef-depth exp)
(ToplevelRef-pos exp)))
,(make-AssignImmediateStatement
target
(make-EnvPrefixReference (ToplevelRef-depth exp)
(ToplevelRef-pos exp)))))))
(: compile-toplevel-set (ToplevelSet CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-toplevel-set exp cenv target linkage)
(let* ([var (ToplevelSet-name exp)]
[lexical-pos (make-EnvPrefixReference (ToplevelSet-depth exp)
(ToplevelSet-pos exp))])
(let ([get-value-code
(compile (ToplevelSet-value exp) cenv lexical-pos
next-linkage)])
(end-with-linkage
linkage
cenv
(append-instruction-sequences
get-value-code
(make-instruction-sequence `(,(make-AssignImmediateStatement target (make-Const (void))))))))))
(: compile-branch (Branch CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-branch exp cenv target linkage)
(let: ([t-branch : LabelLinkage (make-LabelLinkage (make-label 'trueBranch))]
[f-branch : LabelLinkage (make-LabelLinkage (make-label 'falseBranch))]
[after-if : LabelLinkage (make-LabelLinkage (make-label 'afterIf))])
(let ([consequent-linkage
(if (eq? linkage next-linkage)
after-if
linkage)])
(let ([p-code (compile (Branch-predicate exp) cenv 'val next-linkage)]
[c-code (compile (Branch-consequent exp) cenv target consequent-linkage)]
[a-code (compile (Branch-alternative exp) cenv target linkage)])
(append-instruction-sequences p-code
(append-instruction-sequences
(make-instruction-sequence
`(,(make-TestAndBranchStatement 'false?
'val
(LabelLinkage-label f-branch))))
(append-instruction-sequences
(append-instruction-sequences (LabelLinkage-label t-branch) c-code)
(append-instruction-sequences (LabelLinkage-label f-branch) a-code))
(LabelLinkage-label after-if)))))))
(: compile-sequence ((Listof Expression) CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-sequence seq cenv target linkage)
;; All but the last will use next-linkage linkage.
(if (last-exp? seq)
(compile (first-exp seq) cenv target linkage)
(append-instruction-sequences (compile (first-exp seq) cenv target next-linkage)
(compile-sequence (rest-exps seq) cenv target linkage))))
(: compile-splice ((Listof Expression) CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; Wrap a continuation prompt around each of the expressions.
(define (compile-splice seq cenv target linkage)
(cond [(last-exp? seq)
(let ([before-pop-prompt (make-label 'beforePromptPop)])
(end-with-linkage
linkage
cenv
(append-instruction-sequences
(make-instruction-sequence `(,(make-PushControlFrame/Prompt
default-continuation-prompt-tag
before-pop-prompt)))
(compile (first-exp seq) cenv target prompt-linkage)
before-pop-prompt)))]
[else
(let ([before-pop-prompt (make-label 'beforePromptPop)])
(append-instruction-sequences
(make-instruction-sequence `(,(make-PushControlFrame/Prompt
(make-DefaultContinuationPromptTag)
before-pop-prompt)))
(compile (first-exp seq) cenv target prompt-linkage)
before-pop-prompt
(compile-splice (rest-exps seq) cenv target linkage)))]))
(: compile-lambda (Lam CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; Write out code for lambda expressions.
;; The lambda will close over the free variables.
;; Assumption: all of the lambda bodies have already been written out at the top, in -compile.
(define (compile-lambda exp cenv target linkage)
(end-with-linkage
linkage
cenv
(make-instruction-sequence
`(,(make-AssignPrimOpStatement
target
(make-MakeCompiledProcedure (Lam-entry-label exp)
(Lam-num-parameters exp)
(Lam-closure-map exp)
(Lam-name exp)))))))
(: compile-lambda-shell (Lam CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; Write out code for lambda expressions, minus the closure map.
;; Assumption: all of the lambda bodies have already been written out at the top, in -compile.
(define (compile-lambda-shell exp cenv target linkage)
(end-with-linkage
linkage
cenv
(make-instruction-sequence
`(,(make-AssignPrimOpStatement
target
(make-MakeCompiledProcedureShell (Lam-entry-label exp)
(Lam-num-parameters exp)
(Lam-name exp)))))))
(: compile-lambda-body (Lam CompileTimeEnvironment -> InstructionSequence))
;; Compiles the body of the lambda in the appropriate environment.
(define (compile-lambda-body exp cenv)
(append-instruction-sequences
(make-instruction-sequence
`(,(Lam-entry-label exp)))
(if (not (empty? (Lam-closure-map exp)))
(make-instruction-sequence `(,(make-PerformStatement (make-InstallClosureValues!))))
empty-instruction-sequence)
(compile (Lam-body exp)
(append (map (lambda: ([d : Natural])
(list-ref cenv d))
(Lam-closure-map exp))
;; fixme: We need to capture the cenv so we can maintain static knowledge
(build-list (Lam-num-parameters exp) (lambda: ([i : Natural]) '?)))
'val
return-linkage)))
(: compile-lambda-bodies ((Listof lam+cenv) -> InstructionSequence))
;; Compile several lambda bodies, back to back.
(define (compile-lambda-bodies exps)
(cond
[(empty? exps)
(make-instruction-sequence '())]
[else
(append-instruction-sequences (compile-lambda-body (lam+cenv-lam (first exps))
(lam+cenv-cenv (first exps)))
(compile-lambda-bodies (rest exps)))]))
(: extend-compile-time-environment/scratch-space (CompileTimeEnvironment Natural -> CompileTimeEnvironment))
(define (extend-compile-time-environment/scratch-space cenv n)
(append (build-list n (lambda: ([i : Natural])
'?))
cenv))
(: compile-application (App CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; Compiles procedure application
;; Special cases: if we know something about the operator, the compiler will special case.
;; This includes:
;; Known closure
;; Known kernel primitive
;; In the general case, we do general procedure application.
(define (compile-application exp cenv target linkage)
(let ([extended-cenv
(extend-compile-time-environment/scratch-space
cenv
(length (App-operands exp)))])
(define (default)
(compile-general-application exp cenv target linkage))
(let: ([op-knowledge : CompileTimeEnvironmentEntry
(extract-static-knowledge (App-operator exp)
extended-cenv)])
(cond
[(eq? op-knowledge '?)
(default)]
[(ModuleVariable? op-knowledge)
(cond
[(symbol=? (ModuleVariable-module-path op-knowledge) '#%kernel)
(let ([op (ModuleVariable-name op-knowledge)])
(cond [(KernelPrimitiveName? op)
(compile-kernel-primitive-application
op
exp cenv target linkage)]
[else
(default)]))]
[else
(default)])]
[(StaticallyKnownLam? op-knowledge)
(compile-statically-known-lam-application op-knowledge exp cenv target linkage)]
[(Prefix? op-knowledge)
(error 'impossible)]
[(Const? op-knowledge)
(error 'application "Can't apply constant ~s as a function" (Const-const op-knowledge))]))))
(: compile-general-application (App CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-general-application exp cenv target linkage)
(let* ([extended-cenv
(extend-compile-time-environment/scratch-space
cenv
(length (App-operands exp)))]
[proc-code (compile (App-operator exp)
extended-cenv
(if (empty? (App-operands exp))
'proc
(make-EnvLexicalReference
(ensure-natural (sub1 (length (App-operands exp))))
#f))
next-linkage)]
[operand-codes (map (lambda: ([operand : Expression]
[target : Target])
(compile operand extended-cenv target next-linkage))
(App-operands exp)
(build-list (length (App-operands exp))
(lambda: ([i : Natural])
(if (< i (sub1 (length (App-operands exp))))
(make-EnvLexicalReference i #f)
'val))))])
(append-instruction-sequences
(if (not (empty? (App-operands exp)))
(make-instruction-sequence `(,(make-PushEnvironment (length (App-operands exp)) #f)))
empty-instruction-sequence)
proc-code
(juggle-operands operand-codes)
(compile-general-procedure-call cenv
extended-cenv
(length (App-operands exp))
target
linkage))))
(: compile-kernel-primitive-application
(KernelPrimitiveName App CompileTimeEnvironment Target Linkage -> InstructionSequence))
;; This is a special case of application, where the operator is statically
;; known to be in the set of hardcoded primitives.
;;
;; There's a special case optimization we can perform: we can avoid touching
;; the stack for constant arguments; rather than allocate (length (App-operands exp))
;; stack slots, we can do less than that.
;;
;; We have to be sensitive to mutation.
(define (compile-kernel-primitive-application kernel-op exp cenv target linkage)
(cond
;; If all the arguments are primitive enough (all constants, localrefs, or toplevelrefs),
;; then application requires no stack space at all, and application is especially simple.
[(andmap (lambda (op)
;; TODO: as long as the operand contains no applications?
(or (Constant? op)
(ToplevelRef? op)
(LocalRef? op)))
(App-operands exp))
(let* ([n (length (App-operands exp))]
[operand-knowledge
(map (lambda: ([arg : Expression])
(extract-static-knowledge
arg
(extend-compile-time-environment/scratch-space
cenv n)))
(App-operands exp))]
[typechecks?
(map (lambda: ([dom : OperandDomain]
[known : CompileTimeEnvironmentEntry])
(not (redundant-check? dom known)))
(kernel-primitive-expected-operand-types kernel-op n)
operand-knowledge)]
[expected-operand-types
(kernel-primitive-expected-operand-types kernel-op n)]
[operand-poss
(simple-operands->opargs (map (lambda: ([op : Expression])
(adjust-expression-depth op n n))
(App-operands exp)))])
(end-with-linkage
linkage cenv
(make-instruction-sequence
`(,(make-AssignPrimOpStatement
target
(make-CallKernelPrimitiveProcedure
kernel-op
operand-poss
expected-operand-types
typechecks?))))))]
[else
;; Otherwise, we can split the operands into two categories: constants, and the rest.
(let*-values ([(n)
(length (App-operands exp))]
[(expected-operand-types)
(kernel-primitive-expected-operand-types kernel-op n)]
[(constant-operands rest-operands)
(split-operands-by-constants
(App-operands exp))]
;; here, we rewrite the stack references so they assume no scratch space
;; used by the constant operands.
[(extended-cenv constant-operands rest-operands)
(values (extend-compile-time-environment/scratch-space
cenv
(length rest-operands))
(map (lambda: ([constant-operand : Expression])
(ensure-simple-expression
(adjust-expression-depth constant-operand
(length constant-operands)
n)))
constant-operands)
(map (lambda: ([rest-operand : Expression])
(adjust-expression-depth rest-operand
(length constant-operands)
n))
rest-operands))]
[(operand-knowledge)
(append (map (lambda: ([arg : Expression])
(extract-static-knowledge arg extended-cenv))
constant-operands)
(map (lambda: ([arg : Expression])
(extract-static-knowledge arg extended-cenv))
rest-operands))]
[(typechecks?)
(map (lambda: ([dom : OperandDomain]
[known : CompileTimeEnvironmentEntry])
(not (redundant-check? dom known)))
(kernel-primitive-expected-operand-types kernel-op n)
operand-knowledge)]
[(stack-pushing-code)
(if (empty? rest-operands)
empty-instruction-sequence
(make-instruction-sequence `(,(make-PushEnvironment
(length rest-operands)
#f))))]
[(stack-popping-code)
(if (empty? rest-operands)
empty-instruction-sequence
(make-instruction-sequence `(,(make-PopEnvironment
(length rest-operands)
0))))]
[(constant-operand-poss)
(simple-operands->opargs constant-operands)]
[(rest-operand-poss)
(build-list (length rest-operands)
(lambda: ([i : Natural])
(make-EnvLexicalReference i #f)))]
[(rest-operand-code)
(apply append-instruction-sequences
(map (lambda: ([operand : Expression]
[target : Target])
(compile operand extended-cenv target next-linkage))
rest-operands
rest-operand-poss))])
(end-with-linkage
linkage cenv
(append-instruction-sequences
stack-pushing-code
rest-operand-code
(make-instruction-sequence
`(,(make-AssignPrimOpStatement
(adjust-target-depth target (length rest-operands))
(make-CallKernelPrimitiveProcedure
kernel-op
(append constant-operand-poss rest-operand-poss)
expected-operand-types
typechecks?))))
stack-popping-code)))]))
(: ensure-simple-expression (Expression -> (U Constant ToplevelRef LocalRef)))
(define (ensure-simple-expression e)
(if (or (Constant? e)
(LocalRef? e)
(ToplevelRef? e))
e
(error 'ensure-simple-expression)))
(: simple-operands->opargs ((Listof Expression) -> (Listof OpArg)))
;; Produces a list of OpArgs if all the operands are particularly simple, and false therwise.
(define (simple-operands->opargs rands)
(map (lambda: ([e : Expression])
(cond
[(Constant? e)
(make-Const (Constant-v e))]
[(LocalRef? e)
(make-EnvLexicalReference (LocalRef-depth e)
(LocalRef-unbox? e))]
[(ToplevelRef? e)
(make-EnvPrefixReference (ToplevelRef-depth e)
(ToplevelRef-pos e))]
[else
(error 'all-operands-are-constant "Impossible")]))
rands))
(: redundant-check? (OperandDomain CompileTimeEnvironmentEntry -> Boolean))
;; Produces true if we know the knowledge implies the domain-type.
(define (redundant-check? domain-type knowledge)
(cond
[(eq? domain-type 'any)
#t]
[else
(cond [(Const? knowledge)
(case domain-type
[(number)
(number? (Const-const knowledge))]
[(string)
(string? (Const-const knowledge))]
[(box)
(box? (Const-const knowledge))]
[(list)
(list? (Const-const knowledge))]
[(pair)
(pair? (Const-const knowledge))])]
[else
#f])]))
(: split-operands-by-constants
((Listof Expression) ->
(values (Listof (U Constant LocalRef ToplevelRef))
(Listof Expression))))
;; Splits off the list of operations into two: a prefix of constant
;; or simple expressions, and the remainder.
;; TODO: if we can statically determine what arguments are immutable, regardless of
;; side effects, we can do a much better job here...
(define (split-operands-by-constants rands)
(let: loop : (values (Listof (U Constant LocalRef ToplevelRef)) (Listof Expression))
([rands : (Listof Expression) rands]
[constants : (Listof (U Constant LocalRef ToplevelRef))
empty])
(cond [(empty? rands)
(values (reverse constants) empty)]
[else (let ([e (first rands)])
(if (or (Constant? e)
;; These two are commented out because it's not sound otherwise.
#;(and (LocalRef? e) (not (LocalRef-unbox? e)))
#;(and (ToplevelRef? e)
(let ([prefix (ensure-prefix
(list-ref cenv (ToplevelRef-depth e)))])
(ModuleVariable?
(list-ref prefix (ToplevelRef-pos e))))))
(loop (rest rands) (cons e constants))
(values (reverse constants) rands)))])))
(: compile-statically-known-lam-application
(StaticallyKnownLam App CompileTimeEnvironment Target Linkage
-> InstructionSequence))
(define (compile-statically-known-lam-application static-knowledge exp cenv target linkage)
(unless (= (length (App-operands exp))
(StaticallyKnownLam-arity static-knowledge))
(error 'arity-mismatch "~s expected ~s arguments, but received ~s"
(StaticallyKnownLam-name static-knowledge)
(StaticallyKnownLam-arity static-knowledge)
(length (App-operands exp))))
(let* ([extended-cenv
(extend-compile-time-environment/scratch-space
cenv
(length (App-operands exp)))]
[proc-code (compile (App-operator exp)
extended-cenv
(if (empty? (App-operands exp))
'proc
(make-EnvLexicalReference
(ensure-natural (sub1 (length (App-operands exp))))
#f))
next-linkage)]
[operand-codes (map (lambda: ([operand : Expression]
[target : Target])
(compile operand extended-cenv target next-linkage))
(App-operands exp)
(build-list (length (App-operands exp))
(lambda: ([i : Natural])
(if (< i (sub1 (length (App-operands exp))))
(make-EnvLexicalReference i #f)
'val))))])
(append-instruction-sequences
(if (not (empty? (App-operands exp)))
(make-instruction-sequence `(,(make-PushEnvironment (length (App-operands exp)) #f)))
empty-instruction-sequence)
proc-code
(juggle-operands operand-codes)
(compile-procedure-call/statically-known-lam static-knowledge
cenv
extended-cenv
(length (App-operands exp))
target
linkage))))
(: juggle-operands ((Listof InstructionSequence) -> InstructionSequence))
;; Installs the operators. At the end of this,
;; the procedure lives in 'proc, and the operands on the environment stack.
(define (juggle-operands operand-codes)
(let: loop : InstructionSequence ([ops : (Listof InstructionSequence) operand-codes])
(cond
;; If there are no operands, no need to juggle.
[(null? ops)
(make-instruction-sequence empty)]
[(null? (rest ops))
(let: ([n : Natural (ensure-natural (sub1 (length operand-codes)))])
;; The last operand needs to be handled specially: it currently lives in
;; val. We move the procedure at env[n] over to proc, and move the
;; last operand at 'val into env[n].
(append-instruction-sequences
(car ops)
(make-instruction-sequence
`(,(make-AssignImmediateStatement 'proc
(make-EnvLexicalReference n #f))
,(make-AssignImmediateStatement (make-EnvLexicalReference n #f)
(make-Reg 'val))))))]
[else
;; Otherwise, add instructions to juggle the operator and operands in the stack.
(append-instruction-sequences (car ops)
(loop (rest ops)))])))
(: compile-general-procedure-call (CompileTimeEnvironment CompileTimeEnvironment
Natural Target Linkage
->
InstructionSequence))
;; Assumes the procedure value has been loaded into the proc register.
;; n is the number of arguments passed in.
;; cenv is the compile-time enviroment before arguments have been shifted in.
;; extended-cenv is the compile-time environment after arguments have been shifted in.
(define (compile-general-procedure-call cenv extended-cenv n target linkage)
(let-values ([(after-call-multiple after-call-single)
(make-paired-labels 'afterCallMultiple 'afterCallSingle)])
(let: ([primitive-branch : LabelLinkage (make-LabelLinkage (make-label 'primitiveBranch))]
[compiled-branch : LabelLinkage (make-LabelLinkage (make-label 'compiledBranch))])
(let: ([compiled-linkage : Linkage
(if (ReturnLinkage? linkage)
linkage
(make-LabelLinkage (PairedLabel-label after-call-single)))])
(append-instruction-sequences
(make-instruction-sequence
`(,(make-TestAndBranchStatement 'primitive-procedure?
'proc
(LabelLinkage-label primitive-branch))))
;; Compiled branch
(LabelLinkage-label compiled-branch)
(make-instruction-sequence
`(,(make-PerformStatement (make-CheckClosureArity! n))))
(compile-proc-appl extended-cenv
(make-Reg 'val)
n
target
compiled-linkage)
(LabelLinkage-label primitive-branch)
(end-with-linkage
linkage
cenv
(append-instruction-sequences
(make-instruction-sequence
`(,(make-AssignPrimOpStatement
;; Optimization: we put the result directly in the registers, or in
;; the appropriate spot on the stack. This takes into account the popenviroment
;; that happens right afterwards.
(adjust-target-depth target n)
(make-ApplyPrimitiveProcedure n))))
(if (not (= n 0))
(make-instruction-sequence
`(,(make-PopEnvironment n 0)))
empty-instruction-sequence)
(make-instruction-sequence
`(,(make-GotoStatement (make-Label (PairedLabel-label after-call-single)))))
(make-instruction-sequence
`(,after-call-multiple
,after-call-single)))))))))
(: compile-procedure-call/statically-known-lam
(StaticallyKnownLam CompileTimeEnvironment CompileTimeEnvironment Natural Target Linkage -> InstructionSequence))
(define (compile-procedure-call/statically-known-lam static-knowledge cenv extended-cenv n target linkage)
(let-values ([(after-call-multiple
after-call-single)
(make-paired-labels 'afterCallMultiple 'afterCallSingle)])
(let*: ([compiled-linkage : Linkage
(if (ReturnLinkage? linkage)
linkage
(make-LabelLinkage (PairedLabel-label after-call-single)))])
(append-instruction-sequences
(compile-proc-appl extended-cenv
(make-Label (StaticallyKnownLam-entry-point static-knowledge))
n
target
compiled-linkage)
(end-with-linkage
linkage
cenv
(make-instruction-sequence
`(,after-call-multiple
,after-call-single)))))))
(: compile-proc-appl (CompileTimeEnvironment (U Label Reg) Natural Target Linkage -> InstructionSequence))
;; Three fundamental cases for general compiled-procedure application.
;; 1. Tail calls.
;; 2. Non-tail calls (next/label linkage) that write to val
;; 3. Calls in argument position (next/label linkage) that write to the stack.
(define (compile-proc-appl cenv-with-args entry-point n target linkage)
(cond [(ReturnLinkage? linkage)
(cond
[(eq? target 'val)
;; This case happens when we're in tail position.
;; We clean up the stack right before the jump, and do not add
;; to the control stack.
(let: ([num-slots-to-delete : Natural (ensure-natural (- (length cenv-with-args) n))])
(append-instruction-sequences
(make-instruction-sequence
`(,(make-AssignPrimOpStatement 'val
(make-GetCompiledProcedureEntry))))
(if (> num-slots-to-delete 0)
(make-instruction-sequence `(,(make-PopEnvironment num-slots-to-delete n)))
empty-instruction-sequence)
(make-instruction-sequence
`(,(make-GotoStatement entry-point)))))]
[else
;; This case should be impossible: return linkage should only
;; occur when we're in tail position, and we should be in tail position
;; only when the target is the val register.
(error 'compile "return linkage, target not val: ~s" target)])]
[(PromptLinkage? linkage)
(cond [(eq? target 'val)
;; This case happens for a function call that isn't in
;; tail position.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return)))]
[else
;; This case happens for evaluating arguments, since the
;; arguments are being installed into the scratch space.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return
,(make-AssignImmediateStatement target (make-Reg 'val)))))])]
[(NextLinkage? linkage)
(cond [(eq? target 'val)
;; This case happens for a function call that isn't in
;; tail position.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return)))]
[else
;; This case happens for evaluating arguments, since the
;; arguments are being installed into the scratch space.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return
,(make-AssignImmediateStatement target (make-Reg 'val)))))])]
[(LabelLinkage? linkage)
(cond [(eq? target 'val)
;; This case happens for a function call that isn't in
;; tail position.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return
,(make-GotoStatement (make-Label (LabelLinkage-label linkage))))))]
[else
;; This case happens for evaluating arguments, since the
;; arguments are being installed into the scratch space.
(let ([proc-return (make-label 'procReturn)])
(make-instruction-sequence
`(,(make-PushControlFrame proc-return)
,(make-AssignPrimOpStatement 'val (make-GetCompiledProcedureEntry))
,(make-GotoStatement entry-point)
,proc-return
,(make-AssignImmediateStatement target (make-Reg 'val))
,(make-GotoStatement (make-Label (LabelLinkage-label linkage))))))])]))
(: extract-static-knowledge (Expression CompileTimeEnvironment ->
CompileTimeEnvironmentEntry))
;; Statically determines what we know about exp, given the compile time environment.
(define (extract-static-knowledge exp cenv)
(cond
[(Lam? exp)
(make-StaticallyKnownLam (Lam-name exp)
(Lam-entry-label exp)
(Lam-num-parameters exp))]
[(and (LocalRef? exp)
(not (LocalRef-unbox? exp)))
(let ([entry (list-ref cenv (LocalRef-depth exp))])
entry)]
[(ToplevelRef? exp)
(let: ([name : (U Symbol False ModuleVariable)
(list-ref (Prefix-names (ensure-prefix (list-ref cenv (ToplevelRef-depth exp))))
(ToplevelRef-pos exp))])
(cond
[(ModuleVariable? name)
name]
[else
'?]))]
[(Constant? exp)
(make-Const (Constant-v exp))]
[else
'?]))
(: compile-let1 (Let1 CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-let1 exp cenv target linkage)
(let*: ([rhs-code : InstructionSequence
(compile (Let1-rhs exp)
(cons '? cenv)
(make-EnvLexicalReference 0 #f)
next-linkage)]
[after-let1 : Symbol (make-label 'afterLetOne)]
[after-body-code : LabelLinkage (make-LabelLinkage (make-label 'afterLetBody))]
[extended-cenv : CompileTimeEnvironment (cons (extract-static-knowledge (Let1-rhs exp)
(cons '? cenv))
cenv)]
[let-linkage : Linkage
(cond
[(NextLinkage? linkage)
linkage]
[(ReturnLinkage? linkage)
linkage]
[(PromptLinkage? linkage)
after-body-code]
[(LabelLinkage? linkage)
after-body-code])]
[body-target : Target (adjust-target-depth target 1)]
[body-code : InstructionSequence
(compile (Let1-body exp) extended-cenv body-target let-linkage)])
(end-with-linkage
linkage
extended-cenv
(append-instruction-sequences
(make-instruction-sequence `(,(make-PushEnvironment 1 #f)))
rhs-code
body-code
(LabelLinkage-label after-body-code)
(make-instruction-sequence `(,(make-PopEnvironment 1 0)))
after-let1))))
(: compile-let-void (LetVoid CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-let-void exp cenv target linkage)
(let*: ([n : Natural (LetVoid-count exp)]
[after-let : Symbol (make-label 'afterLet)]
[after-body-code : LabelLinkage (make-LabelLinkage (make-label 'afterLetBody))]
[extended-cenv : CompileTimeEnvironment (append (build-list (LetVoid-count exp)
(lambda: ([i : Natural]) '?))
cenv)]
[let-linkage : Linkage
(cond
[(NextLinkage? linkage)
linkage]
[(ReturnLinkage? linkage)
linkage]
[(PromptLinkage? linkage)
after-body-code]
[(LabelLinkage? linkage)
after-body-code])]
[body-target : Target (adjust-target-depth target n)]
[body-code : InstructionSequence
(compile (LetVoid-body exp) extended-cenv body-target let-linkage)])
(end-with-linkage
linkage
extended-cenv
(append-instruction-sequences
(if (> n 0)
(make-instruction-sequence `(,(make-PushEnvironment n (LetVoid-boxes? exp))))
empty-instruction-sequence)
body-code
(LabelLinkage-label after-body-code)
(if (> n 0)
(make-instruction-sequence `(,(make-PopEnvironment n 0)))
empty-instruction-sequence)
after-let))))
(: compile-let-rec (LetRec CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-let-rec exp cenv target linkage)
(let*: ([extended-cenv : CompileTimeEnvironment
(append (map (lambda: ([p : Lam])
(extract-static-knowledge
p
(append (build-list (length (LetRec-procs exp))
(lambda: ([i : Natural])
'?))
cenv)))
(reverse (LetRec-procs exp)))
cenv)]
[n : Natural (length (LetRec-procs exp))]
[after-body-code : LabelLinkage (make-LabelLinkage (make-label 'afterBodyCode))]
[letrec-linkage : Linkage (cond
[(NextLinkage? linkage)
linkage]
[(ReturnLinkage? linkage)
linkage]
[(PromptLinkage? linkage)
after-body-code]
[(LabelLinkage? linkage)
after-body-code])])
(end-with-linkage
linkage
extended-cenv
(append-instruction-sequences
(if (> n 0)
(make-instruction-sequence `(,(make-PushEnvironment n #f)))
empty-instruction-sequence)
;; Install each of the closure shells
(apply append-instruction-sequences
(map (lambda: ([lam : Lam]
[i : Natural])
(compile-lambda-shell lam
extended-cenv
(make-EnvLexicalReference i #f)
next-linkage))
(LetRec-procs exp)
(build-list n (lambda: ([i : Natural]) (ensure-natural (- n 1 i))))))
;; Fix the closure maps of each
(apply append-instruction-sequences
(map (lambda: ([lam : Lam]
[i : Natural])
(make-instruction-sequence
`(,(make-PerformStatement
(make-FixClosureShellMap! i (Lam-closure-map lam))))))
(LetRec-procs exp)
(build-list n (lambda: ([i : Natural]) (ensure-natural (- n 1 i))))))
;; Compile the body
(compile (LetRec-body exp) extended-cenv (adjust-target-depth target n) letrec-linkage)
(LabelLinkage-label after-body-code)
(if (> n 0)
(make-instruction-sequence `(,(make-PopEnvironment n 0)))
empty-instruction-sequence)))))
(: compile-install-value (InstallValue CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-install-value exp cenv target linkage)
(compile (InstallValue-body exp)
cenv
(make-EnvLexicalReference (InstallValue-depth exp) (InstallValue-box? exp))
linkage))
(: compile-box-environment-value (BoxEnv CompileTimeEnvironment Target Linkage -> InstructionSequence))
(define (compile-box-environment-value exp cenv target linkage)
(append-instruction-sequences
(make-instruction-sequence
`(,(make-AssignPrimOpStatement (make-EnvLexicalReference (BoxEnv-depth exp) #f)
(make-MakeBoxedEnvironmentValue (BoxEnv-depth exp)))))
(compile (BoxEnv-body exp) cenv target linkage)))
(: append-instruction-sequences (InstructionSequence * -> InstructionSequence))
(define (append-instruction-sequences . seqs)
(append-seq-list seqs))
(: append-2-sequences (InstructionSequence InstructionSequence -> InstructionSequence))
(define (append-2-sequences seq1 seq2)
(make-instruction-sequence
(append (statements seq1) (statements seq2))))
(: append-seq-list ((Listof InstructionSequence) -> InstructionSequence))
(define (append-seq-list seqs)
(if (null? seqs)
empty-instruction-sequence
(append-2-sequences (car seqs)
(append-seq-list (cdr seqs)))))
(: ensure-natural (Integer -> Natural))
(define (ensure-natural n)
(if (>= n 0)
n
(error 'ensure-natural "Not a natural: ~s\n" n)))
(: ensure-prefix (CompileTimeEnvironmentEntry -> Prefix))
(define (ensure-prefix x)
(if (Prefix? x)
x
(error 'ensure-prefix "Not a prefix: ~s" x)))
(: ensure-lam (Any -> Lam))
(define (ensure-lam x)
(if (Lam? x)
x
(error 'ensure-lam "Not a Lam: ~s" x)))
(: adjust-target-depth (Target Natural -> Target))
(define (adjust-target-depth target n)
(cond
[(eq? target 'val)
target]
[(eq? target 'proc)
target]
[(EnvLexicalReference? target)
(make-EnvLexicalReference (+ n (EnvLexicalReference-depth target))
(EnvLexicalReference-unbox? target))]
[(EnvPrefixReference? target)
(make-EnvPrefixReference (+ n (EnvPrefixReference-depth target))
(EnvPrefixReference-pos target))]
[(PrimitivesReference? target)
target]))
(: adjust-oparg-depth (OpArg Integer -> OpArg))
(define (adjust-oparg-depth arg n)
(cond
[(Const? arg)
arg]
[(Reg? arg)
arg]
[(Label? arg)
arg]
[(EnvLexicalReference? arg)
(make-EnvLexicalReference (ensure-natural (+ n (EnvLexicalReference-depth arg)))
(EnvLexicalReference-unbox? arg))]
[(EnvPrefixReference? arg)
(make-EnvPrefixReference (ensure-natural (+ n (EnvPrefixReference-depth arg)))
(EnvPrefixReference-pos arg))]
[(EnvWholePrefixReference? arg)
(make-EnvWholePrefixReference (ensure-natural (+ n (EnvWholePrefixReference-depth arg))))]))
(: adjust-expression-depth (Expression Natural Natural -> Expression))
;; Redirects references to the stack to route around a region of size n.
;; The region begins at offset skip into the environment.
(define (adjust-expression-depth exp n skip)
(cond
[(Top? exp)
(make-Top (Top-prefix exp)
(adjust-expression-depth (Top-code exp) n (add1 skip)))]
[(Constant? exp)
exp]
[(ToplevelRef? exp)
(if (< (ToplevelRef-depth exp) skip)
exp
(make-ToplevelRef (ensure-natural (- (ToplevelRef-depth exp) n))
(ToplevelRef-pos exp)))]
[(LocalRef? exp)
(if (< (LocalRef-depth exp) skip)
exp
(make-LocalRef (ensure-natural (- (LocalRef-depth exp) n))
(LocalRef-unbox? exp)))]
[(ToplevelSet? exp)
(if (< (ToplevelSet-depth exp) skip)
(make-ToplevelSet (ToplevelSet-depth exp)
(ToplevelSet-pos exp)
(ToplevelSet-name exp)
(adjust-expression-depth (ToplevelSet-value exp) n skip))
(make-ToplevelSet (ensure-natural (- (ToplevelSet-depth exp) n))
(ToplevelSet-pos exp)
(ToplevelSet-name exp)
(adjust-expression-depth (ToplevelSet-value exp) n skip)))]
[(Branch? exp)
(make-Branch (adjust-expression-depth (Branch-predicate exp) n skip)
(adjust-expression-depth (Branch-consequent exp) n skip)
(adjust-expression-depth (Branch-alternative exp) n skip))]
[(Lam? exp)
(make-Lam (Lam-name exp)
(Lam-num-parameters exp)
(Lam-body exp)
(map (lambda: ([d : Natural])
(if (< d skip)
d
(ensure-natural (- d n))))
(Lam-closure-map exp))
(Lam-entry-label exp))]
[(Seq? exp)
(make-Seq (map (lambda: ([action : Expression])
(adjust-expression-depth action n skip))
(Seq-actions exp)))]
[(Splice? exp)
(make-Splice (map (lambda: ([action : Expression])
(adjust-expression-depth action n skip))
(Splice-actions exp)))]
[(App? exp)
(make-App (adjust-expression-depth (App-operator exp) n
(+ skip (length (App-operands exp))))
(map (lambda: ([operand : Expression])
(adjust-expression-depth
operand n (+ skip (length (App-operands exp)))))
(App-operands exp)))]
[(Let1? exp)
(make-Let1 (adjust-expression-depth (Let1-rhs exp) n (add1 skip))
(adjust-expression-depth (Let1-body exp) n (add1 skip)))]
[(LetVoid? exp)
(make-LetVoid (LetVoid-count exp)
(adjust-expression-depth (LetVoid-body exp)
n
(+ skip (LetVoid-count exp)))
(LetVoid-boxes? exp))]
[(LetRec? exp)
(make-LetRec (let: loop : (Listof Lam) ([procs : (Listof Lam) (LetRec-procs exp)])
(cond
[(empty? procs)
'()]
[else
(cons (ensure-lam (adjust-expression-depth
(first procs)
n
(+ skip (length (LetRec-procs exp)))))
(loop (rest procs)))]))
(adjust-expression-depth (LetRec-body exp) n
(+ skip (length (LetRec-procs exp)))))]
[(InstallValue? exp)
(if (< (InstallValue-depth exp) skip)
(make-InstallValue (InstallValue-depth exp)
(adjust-expression-depth (InstallValue-body exp)
n
skip)
(InstallValue-box? exp))
(make-InstallValue (ensure-natural (- (InstallValue-depth exp) n))
(adjust-expression-depth (InstallValue-body exp)
n
skip)
(InstallValue-box? exp)))]
[(BoxEnv? exp)
(if (< (BoxEnv-depth exp) skip)
(make-BoxEnv (BoxEnv-depth exp)
(adjust-expression-depth (BoxEnv-body exp) n skip))
(make-BoxEnv (ensure-natural (- (BoxEnv-depth exp) n))
(adjust-expression-depth (BoxEnv-body exp) n skip)))]))
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