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;;;============================================================================
;; TODO
;; - Fix nargs (%cl) + %ecx
;; - Primitives
;;; File: "_t-x86.scm"
;;; Copyright (c) 2011-2012 by Marc Feeley, All Rights Reserved.
;;; Copyright (c) 2012 by Eric Thivierge, All Rights Reserved.
;;; Copyright (c) 2012 by Vincent Foley, All Rights Reserved.
(include "generic.scm")
(include-adt "_envadt.scm")
(include-adt "_gvmadt.scm")
(include-adt "_ptreeadt.scm")
(include-adt "_sourceadt.scm")
(include "_gvm.scm")
(include "_asm#.scm")
(include "_x86#.scm")
(include "_codegen#.scm")
;; Return the architecture of the compiler.
;; x86-32 for Intel 32
;; x86-64 for Intel 64
;; arm for ARM
(define (auto-detect-arch)
(define auto-detect-arch-code '#u8(
;; ARM X86-32 X86-64
;;
#xEB #x0A #xA0 #xE3 ;; mov r0,#962560 jmp x86 jmp x86
#x03 #x00 #xE0 #xE3 ;; mov r0,#-4 ... ...
#x1E #xFF #x2F #xE1 ;; bx lr ... ...
;; x86:
#x48 ;; dec eax xor rax,rax
#x31 #xC0 ;; xor eax,eax
#x48 ;; dec eax inc rax
#xFF #xC0 ;; inc eax
#xC1 #xE0 #x02 ;; shl eax,0x2 shl eax,0x2
#xC3 ;; ret ret
;;
;; returns -4 returns 0 returns 4
))
(define (run-code code #!optional (arg1 0) (arg2 0) (arg3 0))
(let* ((len (u8vector-length code))
(mcb (##make-machine-code-block len)))
(let loop ((i (- len 1)))
(if (>= i 0)
(begin
(##machine-code-block-set! mcb i (u8vector-ref code i))
(loop (- i 1)))))
(##machine-code-block-exec mcb arg1 arg2 arg3)))
(case (run-code auto-detect-arch-code)
((-1) 'arm)
((0) 'x86-32)
((1) 'x86-64)
(else #f)))
(define (u8vector->procedure code fixups)
(machine-code-block->procedure
(u8vector->machine-code-block code fixups)))
(define (u8vector->machine-code-block code fixups)
(let* ((len (u8vector-length code))
(mcb (##make-machine-code-block len)))
(let loop ((i (fx- len 1)))
(if (fx>= i 0)
(begin
(##machine-code-block-set! mcb i (u8vector-ref code i))
(loop (fx- i 1)))
(apply-fixups mcb fixups)))))
;; Add mcb's base address to every label that needs to be fixed up.
;; Currently assumes 32 bit width.
(define (apply-fixups mcb fixups)
(let ((base-addr (##foreign-address mcb)))
(let loop ((fixups fixups))
(if (null? fixups)
mcb
(let* ((pos (asm-label-pos (caar fixups)))
(size (quotient (cdar fixups) 8))
(n (+ base-addr (machine-code-block-extract-number mcb pos size))))
(machine-code-block-insert-number! mcb pos size n)
(loop (cdr fixups)))))))
;; Extract `size` bytes from `mcb` at position `start` and accumulate
;; them into a number. Use little endian.
(define (machine-code-block-extract-number mcb start size)
(let loop ((n 0) (i (- size 1)))
(if (>= i 0)
(loop (+ (* n 256) (##machine-code-block-ref mcb (+ start i)))
(- i 1))
n)))
;; Insert into `mcb` at position `start` the number `n` as `size` bytes.
;; Use little endian.
(define (machine-code-block-insert-number! mcb start size n)
(let loop ((n n) (i 0))
(if (< i size)
(begin
(##machine-code-block-set! mcb (+ start i) (modulo n 256))
(loop (quotient n 256) (+ i 1))))))
(define (machine-code-block->procedure mcb)
(lambda (#!optional (arg1 0) (arg2 0) (arg3 0))
(##machine-code-block-exec mcb arg1 arg2 arg3)))
;; Take a code generation context, assemble it,
;; fix the addresses, and convert the code to
;; a procedure. Optionally display the resulting
;; assembly code.
(define (create-procedure cgc #!optional (show-listing? #f))
(let ((targ (codegen-context-target cgc)))
(let* ((code (asm-assemble-to-u8vector cgc))
(fixups (codegen-context-fixup-list cgc)))
(if show-listing?
(asm-display-listing cgc (current-error-port) #t))
(u8vector->procedure code fixups))))
(define (nat-target-info-port x) (vector-ref x 16))
(define (nat-target-info-port-set! x y) (vector-set! x 16 y))
(define (nat-target-arch x) (vector-ref x 17))
(define (nat-target-arch-set! x y) (vector-set! x 17 y))
(define (nat-target-word-width x) (vector-ref x 18))
(define (nat-target-word-width-set! x y) (vector-set! x 18 y))
(define (nat-target-nb-arg-regs x) (vector-ref x 19))
(define (nat-target-nb-arg-regs-set! x y) (vector-set! x 19 y))
(define (nat-target-gvm-reg-map x) (vector-ref x 20))
(define (nat-target-gvm-reg-map-set! x y) (vector-set! x 20 y))
(define (nat-target-pstate-ptr-reg x) (vector-ref x 21))
(define (nat-target-pstate-ptr-reg-set! x y) (vector-set! x 21 y))
(define (nat-target-heap-ptr-reg x) (vector-ref x 22))
(define (nat-target-heap-ptr-reg-set! x y) (vector-set! x 22 y))
(define (nat-target-stack-ptr-reg x) (vector-ref x 23))
(define (nat-target-stack-ptr-reg-set! x y) (vector-set! x 23 y))
(define (nat-target-prim-proc-table x) (vector-ref x 24))
(define (nat-target-prim-proc-table-set! x y) (vector-set! x 24 y))
(define (nat-target-prc-objs x) (vector-ref x 25))
(define (nat-target-prc-objs-set! x y) (vector-set! x 25 y))
(define (nat-target-prc-objs-seen x) (vector-ref x 26))
(define (nat-target-prc-objs-seen-set! x y) (vector-set! x 26 y))
(define (nat-target-prc-objs-to-scan x) (vector-ref x 27))
(define (nat-target-prc-objs-to-scan-set! x y) (vector-set! x 27 y))
(define (nat-target-nb-arg-gvm-reg x) (vector-ref x 28))
(define (nat-target-nb-arg-gvm-reg-set! x y) (vector-set! x 28 y))
;; Initialization/finalization of back-end.
(define (x86-setup target-language arch file-extension)
(let ((targ (make-target 9 target-language 13))) ; We need 13 extra fields (see above).
(define (begin! info-port)
(target-dump-set!
targ
(lambda (procs output c-intf script-line options)
(x86-dump targ procs output c-intf script-line options)))
(target-nb-regs-set! targ x86-nb-gvm-regs)
(target-prim-info-set!
targ
(lambda (name)
(x86-prim-info targ name)))
(target-label-info-set!
targ
(lambda (nb-parms closed?)
(x86-label-info targ nb-parms closed?)))
(target-jump-info-set!
targ
(lambda (nb-args)
(x86-jump-info targ nb-args)))
(target-frame-constraints-set!
targ
(make-frame-constraints x86-frame-reserve x86-frame-alignment))
(target-proc-result-set!
targ
(make-reg 1))
(target-task-return-set!
targ
(make-reg 0))
(target-switch-testable?-set!
targ
(lambda (obj)
(x86-switch-testable? targ obj)))
(target-eq-testable?-set!
targ
(lambda (obj)
(x86-eq-testable? targ obj)))
(target-object-type-set!
targ
(lambda (obj)
(x86-object-type targ obj)))
(target-file-extension-set!
targ
file-extension)
(nat-target-arch-set! targ arch)
(case arch
((x86-32)
(begin
(nat-target-word-width-set! targ 4)
(nat-target-gvm-reg-map-set! targ (vector (x86-esi)
(x86-eax)
(x86-ebx)
(x86-edi)
(x86-edx)))
(nat-target-nb-arg-gvm-reg-set! targ (x86-cl))
(nat-target-pstate-ptr-reg-set! targ (x86-ecx))
(nat-target-heap-ptr-reg-set! targ (x86-esp))
(nat-target-stack-ptr-reg-set! targ (x86-ebp))))
((x86-64)
(begin
(nat-target-word-width-set! targ 8)
(nat-target-gvm-reg-map-set! targ (vector (x86-rsi)
(x86-rax)
(x86-rbx)
(x86-rdi)
(x86-rdx)))
(nat-target-nb-arg-gvm-reg-set! targ (x86-cl))
(nat-target-pstate-ptr-reg-set! targ (x86-rcx))
(nat-target-heap-ptr-reg-set! targ (x86-rsp))
(nat-target-stack-ptr-reg-set! targ (x86-rbp)))))
#f)
(define (end!)
#f)
(target-begin!-set! targ begin!)
(target-end!-set! targ end!)
(target-add targ)))
;; Install the backend.
(x86-setup 'nat (auto-detect-arch) ".s")
;;;----------------------------------------------------------------------------
;; ***** PROCEDURE CALLING CONVENTION
(define x86-nb-gvm-regs 5)
(define x86-nb-arg-regs 3)
(define (x86-label-info targ nb-parms closed?)
;; After a GVM "entry-point" or "closure-entry-point" label, the following
;; is true:
;;
;; * return address is in GVM register 0
;;
;; * if nb-parms <= nb-arg-regs
;;
;; then parameter N is in GVM register N
;;
;; else parameter N is in
;; GVM register N-F, if N > F
;; GVM stack slot N, if N <= F
;; where F = nb-parms - nb-arg-regs
;;
;; * for a "closure-entry-point" GVM register nb-arg-regs+1 contains
;; a pointer to the closure object
;;
;; * other GVM registers contain an unspecified value
(let ((nb-stacked (max 0 (- nb-parms x86-nb-arg-regs))))
(define (location-of-parms i)
(if (> i nb-parms)
'()
(cons (cons i
(if (> i nb-stacked)
(make-reg (- i nb-stacked))
(make-stk i)))
(location-of-parms (+ i 1)))))
(let ((x (cons (cons 'return 0) (location-of-parms 1))))
(make-pcontext nb-stacked
(if closed?
(cons (cons 'closure-env
(make-reg (+ x86-nb-arg-regs 1)))
x)
x)))))
(define (x86-jump-info targ nb-args)
;; After a GVM "jump" instruction with argument count, the following
;; is true:
;;
;; * the return address is in GVM register 0
;;
;; * if nb-args <= nb-arg-regs
;;
;; then argument N is in GVM register N
;;
;; else argument N is in
;; GVM register N-F, if N > F
;; GVM stack slot N, if N <= F
;; where F = nb-args - nb-arg-regs
;;
;; * GVM register nb-arg-regs+1 contains a pointer to the closure object
;; if a closure is being jumped to
;;
;; * other GVM registers contain an unspecified value
(let ((nb-stacked (max 0 (- nb-args x86-nb-arg-regs))))
(define (location-of-args i)
(if (> i nb-args)
'()
(cons (cons i
(if (> i nb-stacked)
(make-reg (- i nb-stacked))
(make-stk i)))
(location-of-args (+ i 1)))))
(make-pcontext nb-stacked
(cons (cons 'return (make-reg 0))
(location-of-args 1)))))
;; The frame constraints are defined by the parameters
;; x86-frame-reserve and x86-frame-alignment.
(define x86-frame-reserve 0) ;; no extra slots reserved
(define x86-frame-alignment 1) ;; no alignment constraint
;; ***** PRIMITIVE PROCEDURE DATABASE
(define (x86-prim-info targ name)
(x86-prim-info* name))
(define (x86-prim-info* name)
(table-ref x86-prim-proc-table name #f))
(define x86-prim-proc-table (make-table))
(define (x86-prim-proc-add! x)
(let ((name (string->canonical-symbol (car x))))
(table-set! x86-prim-proc-table
name
(apply make-proc-obj (car x) #f #t #f (cdr x)))))
(for-each x86-prim-proc-add! prim-procs)
(define (x86-switch-testable? targ obj)
; (pretty-print (list 'x86-switch-testable? 'targ obj))
#f);;;;;;;;;;;;;;;;;;;;;;;;;;;;
(define (x86-eq-testable? targ obj)
; (pretty-print (list 'x86-eq-testable? 'targ obj))
#f);;;;;;;;;;;;;;;;;;;;;;;;;;;
(define (x86-object-type targ obj)
; (pretty-print (list 'x86-object-type 'targ obj))
'bignum);;;;;;;;;;;;;;;;;;;;;;;;;
;;;; ***** DUMPING OF A COMPILATION MODULE
;; Table from symbol to asm-labels.
(define nat-labels (make-table test: eq?))
;; nat-label-ref: finds the label associated with a symbol. Creates it if
;; it doesn't exist.
(define (nat-label-ref cgc label-name)
(let ((x (table-ref nat-labels label-name #f)))
(if x
x
(let ((l (asm-make-label cgc label-name)))
(table-set! nat-labels label-name l)
l))))
;; nat-label-set!: insert or update a symbol/label association in the table.
(define (nat-label-set! cgc label-name val)
(table-set! nat-labels label-name val))
;; Table from symbol to pstate offset.
(define nat-globals (make-table test: eq?))
;; Get the memory address of a symbol. If the symbol doesn't exist,
;; add it to the table.
(define nat-global-ref
(let ((current -1))
(lambda (cgc symbol)
(let* ((targ (codegen-context-target cgc))
(x (table-ref nat-globals symbol #f))
(offset (if x
x
(begin
(set! current (+ current 1))
(table-set! nat-globals symbol current)
current))))
(x86-mem (- (* (nat-target-word-width targ)
(+ nat-globals-slot
offset))
(codegen-context-nargs cgc))
(nat-target-pstate-ptr-reg targ))))))
;; Queue containing the procs we've seen so far. (Could we use a set instead?)
(define procs-seen (queue-empty))
;; Queue containing the procs that have been seen, but not yet generated.
(define procs-not-visited (queue-empty))
;; Add obj to the procs-seen and procs-visited queues if it's
;; a procedure object and has not been seen before.
(define (scan-obj obj)
(if (and (proc-obj? obj)
(proc-obj-code obj)
(not (memq obj (queue->list procs-seen))))
(begin
(queue-put! procs-seen obj)
(queue-put! procs-not-visited obj))))
;; Scan an operand only if it is an object or a closure.
(define (scan-opnd opnd)
(cond ((not opnd))
((obj? opnd) (scan-obj (obj-val opnd)))
((clo? opnd) (scan-obj (clo-base opnd)))))
;; Create a new codegen context for the specified architecture and
;; endianness. The style of the resulting listing can also be
;; specified, and defaults to GNU (AT&T).
(define (make-cgc arch endianness #!optional (style 'gnu))
(let ((cgc (make-codegen-context)))
(asm-init-code-block cgc 0 endianness)
(codegen-context-listing-format-set! cgc style)
(x86-arch-set! cgc arch)
cgc))
(define (x86-dump targ procs output c-intf script-line options)
;; Allows gsc to fall into the REPL when there's an error.
(set! throw-to-exception-handler
(lambda (val) (error val)))
(for-each (lambda (p) (scan-opnd (make-obj p))) procs)
(let* ((cgc (make-cgc (nat-target-arch targ) 'le))
(main-lbl (nat-label-ref cgc 'main))
(println-lbl (nat-label-ref cgc 'println)))
(codegen-context-target-set! cgc targ)
(x86-jmp cgc main-lbl)
;;(generate-primitives cgc)
(generate-println cgc println-lbl)
(x86-translate-procs cgc)
(entry-point cgc (list-ref procs 0))
(let ((f (create-procedure cgc #t)))
(f)))
#f)
;; Define the entry point (main) of the program. Do all the
;; register shuffling, and jump to the main procedure of the
;; program.
(define nat-stack-limit-slot 0)
(define nat-heap-limit-slot 1)
(define nat-sp-slot 2) ; sp du code C.
(define nat-globals-slot 8)
(define nat-pstate-size 100) ; number of words
(define nat-stack-size (expt 2 20))
(define nat-stack-fudge (expt 2 14))
(define nat-heap-size (expt 2 20))
(define nat-heap-fudge (expt 2 14))
(define (entry-point cgc main-proc)
;; | | C stack
;; +-------+ <--- pstate register
;; | . |
;; | . | pstate (nat-pstate-size)
;; | . |
;; +-------+
;; | | Wasted space to align to multiple of 256.
;; +-------+ <--- stack pointer register
;; | . |
;; | . | Gambit stack (nat-stack-size)
;; | . |
;; |~~~~~~~| Gambit stack fudge (nat-stack-fudge)
;; +-------+ <--- heap pointer register
;; | . |
;; | . | Gambit heap (nat-heap-size)
;; | . |
;; |~~~~~~~| Gambit heap fudge (nat-heap-fudge)
(let* ((targ (codegen-context-target cgc))
(main-lbl (nat-label-ref cgc 'main))
(exit-lbl (nat-label-ref cgc 'exit))
(entry-lbl (nat-label-ref cgc (lbl->id 1 (proc-obj-name main-proc)))))
(codegen-context-nargs-set! cgc 0)
(x86-label cgc main-lbl)
;; Save general purpose registers, stack and base registers onto the stack.
(x86-push cgc (nat-target-stack-ptr-reg targ))
(x86-push cgc (nat-target-pstate-ptr-reg targ))
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 0))
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 1))
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 2))
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 3))
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 4))
;; First part of the memory is the pstate.
(x86-mov cgc (nat-target-pstate-ptr-reg targ) (nat-target-heap-ptr-reg targ))
(x86-sub cgc (nat-target-heap-ptr-reg targ) (x86-imm-int (* (nat-target-word-width targ) nat-pstate-size)))
(x86-and cgc (nat-target-heap-ptr-reg targ) (x86-imm-int -256)) ;; align to multiple of 256 (low 8 bits = 0) (256 = 0xfff_ff00)
(x86-mov cgc (x86-mem (* (nat-target-word-width targ) nat-sp-slot) (nat-target-heap-ptr-reg targ)) (nat-target-pstate-ptr-reg targ))
(x86-mov cgc (nat-target-pstate-ptr-reg targ) (nat-target-heap-ptr-reg targ))
;; Then comes the stack
(x86-mov cgc (nat-target-stack-ptr-reg targ) (nat-target-heap-ptr-reg targ))
(x86-sub cgc (nat-target-stack-ptr-reg targ) (x86-imm-int (* (nat-target-word-width targ) 16))) ;; TODO: remove me! (tracking of frame size seems wrong)
(x86-lea cgc (vector-ref (nat-target-gvm-reg-map targ) 1) (x86-mem (* (nat-target-word-width targ) (- nat-stack-fudge nat-stack-size)) (nat-target-heap-ptr-reg targ)))
(x86-mov cgc (x86-mem (* (nat-target-word-width targ) nat-stack-limit-slot) (nat-target-pstate-ptr-reg targ)) (vector-ref (nat-target-gvm-reg-map targ) 1))
(x86-sub cgc (nat-target-heap-ptr-reg targ) (x86-imm-int (* (nat-target-word-width targ) nat-stack-size)))
;; And finally, the heap.
(x86-lea cgc (vector-ref (nat-target-gvm-reg-map targ) 1) (x86-mem (* (nat-target-word-width targ) (- nat-heap-fudge nat-heap-size)) (nat-target-heap-ptr-reg targ)))
(x86-mov cgc (x86-mem (* (nat-target-word-width targ) nat-heap-limit-slot) (nat-target-pstate-ptr-reg targ)) (vector-ref (nat-target-gvm-reg-map targ) 1))
(let ((mem-loc (nat-global-ref cgc 'println))
(mem-opnd (nat-label-ref cgc 'println)))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) (x86-imm-lbl (nat-label-ref cgc 'println)))
(x86-mov cgc mem-loc (vector-ref (nat-target-gvm-reg-map targ) 1)))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 0) (x86-imm-lbl exit-lbl))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) (x86-imm-int 0))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 2) (x86-imm-int 0))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 3) (x86-imm-int 0))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 4) (x86-imm-int 0))
(x86-jmp cgc entry-lbl)
(x86-label cgc exit-lbl)
;; Restore the C stack pointer.
(x86-mov cgc (nat-target-heap-ptr-reg targ) (x86-mem (* (nat-target-word-width targ) nat-sp-slot) (nat-target-pstate-ptr-reg targ)))
;; Restore general purpose registers, stack and base registers from the stack.
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 4))
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 3))
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 2))
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 1))
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 0))
(x86-pop cgc (nat-target-pstate-ptr-reg targ))
(x86-pop cgc (nat-target-stack-ptr-reg targ))
;; (x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) (x86-imm-int 0))
(x86-ret cgc)))
;; Pop and translate every proc in procs-not-visited.
(define (x86-translate-procs cgc)
(if (queue-empty? procs-not-visited)
'()
(begin
(translate-proc cgc (queue-get! procs-not-visited))
(x86-translate-procs cgc))))
;; Do the code generation for a procedure.
(define (translate-proc cgc proc)
(let* ((code (proc-obj-code proc))
(lst (bbs->code-list code))
(targ (codegen-context-target cgc))
(ctx (make-ctx targ (proc-obj-name proc))))
(for-each
(lambda (bb)
(let* ((gvm-instr (code-gvm-instr bb))
(gvm-type (gvm-instr-type gvm-instr)))
;;(pp gvm-type)
(case gvm-type
((label)
(let* ((lbl (make-lbl (label-lbl-num gvm-instr)))
(lbl-name (translate-lbl ctx lbl))
(asm-lbl (nat-label-ref cgc lbl-name))
(fs (frame-size (gvm-instr-frame gvm-instr))))
(codegen-context-frame-size-set! cgc fs)
(x86-label cgc asm-lbl)
(case (label-type gvm-instr)
((simple)
#f)
((entry)
(codegen-context-nargs-set! cgc 0)
(x86-sub cgc (nat-target-nb-arg-gvm-reg targ) (x86-imm-int (label-entry-nb-parms gvm-instr)))
;; TODO: add "jne wrong_nb_args_handler"
#f
)
((return)
(codegen-context-nargs-set! cgc 0)
#f)
((task-entry)
#f)
((task-return)
#f)
(else
(compiler-internal-error
"translate-proc, unknown label type")))))
((copy)
(let* ((loc (copy-loc gvm-instr))
(opnd (copy-opnd gvm-instr)))
(scan-opnd opnd)
(scan-opnd loc)
(let ((loc* (nat-opnd cgc ctx loc))
(opnd* (nat-opnd cgc ctx opnd)))
;; Can't move from memory to memory.
(if (or (x86-reg? loc*)
(x86-reg? opnd*)
(x86-imm-int? opnd*))
(x86-mov cgc
(if (asm-label? loc*) (x86-imm-lbl loc*) loc*)
(if (asm-label? opnd*) (x86-imm-lbl opnd*) opnd*)
(* (nat-target-word-width targ) 8))
(let ((temp-reg (vector-ref (nat-target-gvm-reg-map targ) 1)))
(x86-push cgc temp-reg)
(x86-mov cgc temp-reg (if (asm-label? opnd*) (x86-imm-lbl opnd*) opnd*))
(x86-mov cgc (if (asm-label? loc*) (x86-imm-lbl loc*) loc*) temp-reg)
(x86-pop cgc temp-reg))))))
((close)
(nat-close cgc (close-parms gvm-instr)))
((jump)
(let ((opnd (jump-opnd gvm-instr))
(nargs (jump-nb-args gvm-instr))
(jump-size (frame-size (gvm-instr-frame gvm-instr))))
(scan-opnd opnd)
(if nargs
(begin
(codegen-context-nargs-set! cgc nargs)
(x86-mov cgc (nat-target-nb-arg-gvm-reg targ) (x86-imm-int nargs))))
(adjust-frame-size cgc jump-size)
(x86-jmp cgc (nat-opnd cgc ctx opnd))))
((apply)
(let ((prim (apply-prim gvm-instr))
(opnds (apply-opnds gvm-instr))
(loc (apply-loc gvm-instr)))
(let ((proc (proc-obj-inline prim)))
(if proc
(proc cgc opnds loc)
(compiler-internal-error
"nat-gen-apply, unknown 'prim'" prim)))))
((ifjump)
(let* ((jump-size (frame-size (gvm-instr-frame gvm-instr)))
(test (ifjump-test gvm-instr))
(opnds (ifjump-opnds gvm-instr))
(true (ifjump-true gvm-instr))
(false (ifjump-false gvm-instr))
(test-proc (proc-obj-test test)))
;;(pp ctx)
(if test-proc
(begin
(adjust-frame-size cgc jump-size)
(test-proc cgc ctx opnds true false))
(compiler-internal-error "test is not a procedure"))))
(else
(compiler-internal-error "unrecognized type:" gvm-type)))
))
lst)))
(define (adjust-frame-size cgc jump-size)
(let* ((targ (codegen-context-target cgc))
(offset (- (codegen-context-frame-size cgc)
jump-size)))
(codegen-context-frame-size-set! cgc
(- (codegen-context-frame-size cgc) offset))
(if (not (= offset 0))
(x86-add cgc (nat-target-stack-ptr-reg targ)
(x86-imm-int (* (nat-target-word-width targ) offset))))))
;; (define (nat-if-then-else cgc ctx test opnds true* false*)
;; (let* ((targ (codegen-context-target cgc))
;; (true-lbl (nat-label-ref cgc (lbl->id true* (ctx-ns ctx))))
;; (false-lbl (nat-label-ref cgc (lbl->id false* (ctx-ns ctx)))))
;; (test cgc opnds)
;; (x86-jne cgc false-lbl)
;; (x86-jmp cgc true-lbl)))
(define (nat-close cgc parms)
(define (close parms)
(if (pair? parms)
(let* ((parm (car parms))
(lbl (closure-parms-lbl parm))
(loc (closure-parms-loc parm))
(opnds (closure-parms-opnds parm)))
(pp (list loc lbl opnds));;;;;;;;;;;;;;;
(close (cdr parms)))))
(close (reverse parms)))
(define (translate-lbl ctx lbl)
(lbl->id (lbl-num lbl) (ctx-ns ctx)))
(define (lbl->id num ns)
(string->symbol (string-append "lbl_"
(number->string num)
"_"
(scheme-id->c-id ns))))
(define (classify-opnd opnd)
(list (list 'reg? (reg? opnd))
(list 'stk? (stk? opnd))
(list 'lbl? (lbl? opnd))
(list 'glo? (glo? opnd))
(list 'obj? (obj? opnd))
(list 'clo? (clo? opnd))))
(define (nat-opnd cgc ctx opnd) ;; fetch GVM operand
;; (pp (classify-opnd opnd))
(let ((targ (codegen-context-target cgc)))
(cond ((reg? opnd)
(let ((n (reg-num opnd)))
(vector-ref (nat-target-gvm-reg-map targ) n)))
((stk? opnd)
(let ((n (stk-num opnd)))
(x86-mem (* (nat-target-word-width targ)
(+ (codegen-context-frame-size cgc) (- n) 1))
(nat-target-stack-ptr-reg targ))))
((glo? opnd)
(let* ((name (glo-name opnd))
(mem-loc (nat-global-ref cgc name)))
mem-loc))
((clo? opnd)
(let ((base (clo-base opnd))
(index (clo-index opnd)))
(let ((reg (nat-opnd-reg targ base)))
(x86-mem (+ 1 (* (nat-target-word-width targ) index))
reg)))) ;;;;;;;;;;;;;;;;
((lbl? opnd)
(let* ((lbl-name (translate-lbl ctx opnd))
(asm-lbl (nat-label-ref cgc lbl-name)))
asm-lbl))
((obj? opnd)
(let ((val (obj-val opnd)))
(cond ((and (integer? val) (exact? val))
(x86-imm-int (* val 4)))
((proc-obj? val)
;; Is the entry-point of a procedure always going to be
;; at label 1?
(let ((lbl-name (lbl->id 1 (proc-obj-name val))))
(nat-label-ref cgc lbl-name)))
((string? val)
(x86-imm-int -2)) ; Temporarily to support a test case
((eq? val #f)
(x86-imm-int -2))
((eq? val #t)
(x86-imm-int -6))
((eq? val '())
(x86-imm-int -10))
(else
(x86-imm-int 0)))));;;;;;;;;;;;;;;;;;;;;;;;;
(else
(compiler-internal-error
"nat-opnd, unknown 'opnd'" opnd)))))
(define (make-ctx target ns)
(vector target ns 0))
(define (ctx-target ctx) (vector-ref ctx 0))
(define (ctx-target-set! ctx x) (vector-set! ctx 0 x))
(define (ctx-ns ctx) (vector-ref ctx 1))
(define (ctx-ns-set! ctx x) (vector-set! ctx 1 x))
(define (ctx-stack-base-offset ctx) (vector-ref ctx 2))
(define (ctx-stack-base-offset-set! ctx x) (vector-set! ctx 2 x))
(define (with-stack-base-offset ctx n proc)
(let ((save (ctx-stack-base-offset ctx)))
(ctx-stack-base-offset-set! ctx n)
(let ((result (proc ctx)))
(ctx-stack-base-offset-set! ctx save)
result)))
(define (with-stack-pointer-adjust ctx n proc)
(gen (if (= n 0)
(gen "")
(x86-increment ctx (x86-global ctx (x86-prefix ctx "sp")) n))
(with-stack-base-offset
ctx
(- (ctx-stack-base-offset ctx) n)
proc)))
(define x86-tag-bits 2)
(define x86-word-bits 32)
(define true (x86-imm-int -6))
(define false (x86-imm-int -2))
(define (generate-println cgc println-lbl)
(let* ((targ (codegen-context-target cgc))
(print-lbl (asm-make-label cgc 'print))
(print_other-lbl (asm-make-label cgc 'print_other))
(print_false-lbl (asm-make-label cgc 'print_false))
(print_true-lbl (asm-make-label cgc 'print_true))
(print_int-lbl (asm-make-label cgc 'print_int))
(write_int-lbl (asm-make-label cgc 'write_int))
(write_int_neg-lbl (asm-make-label cgc 'write_int_neg))
(write_int_pos-lbl (asm-make-label cgc 'write_int_pos))
(write_int_loop-lbl (asm-make-label cgc 'write_int_loop))
(write_digit-lbl (asm-make-label cgc 'write_digit))
(write_int_zero-lbl (asm-make-label cgc 'write_int_zero))
(write_char-lbl (asm-make-label cgc 'write_char)))
(define (reg x)
(case x
((0 1 2 3 4) (vector-ref (nat-target-gvm-reg-map targ) x))
((sp) (nat-target-stack-ptr-reg targ))
((hp) (nat-target-heap-ptr-reg targ))
(else (compiler-internal-error "invalid register" x))))
(nat-label-set! cgc 'println println-lbl)
(x86-label cgc println-lbl)
(codegen-context-nargs-set! cgc 0)
(x86-sub cgc (nat-target-nb-arg-gvm-reg targ) (x86-imm-int 1))
;; TODO: add "jne wrong_nb_args_handler"
(x86-call cgc print-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 10))
(x86-call cgc write_char-lbl)
(x86-mov cgc (reg 1) (x86-imm-int -2))
(x86-jmp cgc (reg 0))
(x86-label cgc print-lbl)
(x86-test cgc (reg 1) (x86-imm-int 3))
(x86-je cgc print_int-lbl)
(x86-cmp cgc (reg 1) (x86-imm-int -2))
(x86-je cgc print_false-lbl)
(x86-cmp cgc (reg 1) (x86-imm-int -6))
(x86-je cgc print_true-lbl)
(x86-label cgc print_other-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 63))
(x86-call cgc write_char-lbl)
(x86-ret cgc)
(x86-label cgc print_false-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 35))
(x86-call cgc write_char-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 102))
(x86-call cgc write_char-lbl)
(x86-ret cgc)
(x86-label cgc print_true-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 35))
(x86-call cgc write_char-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 116))
(x86-call cgc write_char-lbl)
(x86-ret cgc)
(x86-label cgc print_int-lbl)
(x86-sar cgc (reg 1) (x86-imm-int 2))
(x86-call cgc write_int-lbl)
(x86-ret cgc)
(x86-label cgc write_int-lbl)
(x86-cmp cgc (reg 1) (x86-imm-int 0))
(x86-je cgc write_int_zero-lbl)
(x86-jge cgc write_int_pos-lbl)
(x86-label cgc write_int_neg-lbl)
(x86-push cgc (reg 1))
(x86-mov cgc (reg 1) (x86-imm-int #x2d))
(x86-call cgc write_char-lbl)
(x86-pop cgc (reg 1))
(x86-neg cgc (reg 1))
(x86-label cgc write_int_pos-lbl)
(x86-neg cgc (reg 1))
(x86-push cgc (reg 2))
(x86-push cgc (reg 4))
(x86-call cgc write_int_loop-lbl)
(x86-pop cgc (reg 4))
(x86-pop cgc (reg 2))
(x86-ret cgc)
(x86-label cgc write_int_loop-lbl)
(x86-mov cgc (reg 4) (x86-imm-int -1))
(x86-mov cgc (reg 2) (x86-imm-int 10))
(x86-idiv cgc (reg 2))
(x86-cmp cgc (reg 1) (x86-imm-int 0))
(x86-je cgc write_digit-lbl)
(x86-push cgc (reg 4))
(x86-call cgc write_int_loop-lbl)
(x86-pop cgc (reg 4))
(x86-label cgc write_digit-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 48))
(x86-sub cgc (reg 1) (reg 4))
(x86-call cgc write_char-lbl)
(x86-ret cgc)
(x86-label cgc write_int_zero-lbl)
(x86-mov cgc (reg 1) (x86-imm-int 48))
(x86-call cgc write_char-lbl)
(x86-ret cgc)
;; Mac OS X version of write_char
(if (memq (caddr (system-type)) '(darwin9 darwin11.3.0))
(case (nat-target-arch targ)
((x86-32)
(x86-label cgc write_char-lbl)
(x86-push cgc (x86-ebp))
(x86-push cgc (x86-esi))
(x86-push cgc (x86-edi))
(x86-push cgc (x86-edx))
(x86-push cgc (x86-ecx))
(x86-push cgc (x86-ebx))
(x86-push cgc (x86-eax)) ;; put character to write on stack
(x86-mov cgc (x86-eax) (x86-esp)) ;; get address of character in %eax
(x86-push cgc (x86-imm-int 1)) ;; number of bytes to write = 1
(x86-push cgc (x86-eax)) ;; address of byte to write
(x86-push cgc (x86-imm-int 1)) ;; "stdout" is file descriptor 1
(x86-push cgc (x86-imm-int 0)) ;; reserve space for system call
(x86-mov cgc (x86-eax) (x86-imm-int 4)) ;; "write" system call is 4
(x86-int cgc #x80) ;; perform system call
(x86-add cgc (x86-esp) (x86-imm-int 16)) ;; pop what was pushed
(x86-pop cgc (x86-eax))
(x86-pop cgc (x86-ebx))
(x86-pop cgc (x86-ecx))
(x86-pop cgc (x86-edx))
(x86-pop cgc (x86-edi))
(x86-pop cgc (x86-esi))
(x86-pop cgc (x86-ebp))
(x86-ret cgc))
((x86-64)
(x86-label cgc write_char-lbl)
(x86-push cgc (x86-r11))
(x86-push cgc (x86-rbp))
(x86-push cgc (x86-rsi))
(x86-push cgc (x86-rdi))
(x86-push cgc (x86-rdx))
(x86-push cgc (x86-rcx))
(x86-push cgc (x86-rbx))
(x86-push cgc (x86-rax)) ;; put character to write on stack
(x86-mov cgc (x86-rsi) (x86-rsp)) ;; get address of character in %rsi
(x86-mov cgc (x86-rdx) (x86-imm-int 1)) ;; number of bytes to write = 1
(x86-mov cgc (x86-rdi) (x86-imm-int 1)) ;; "stdout" is file descriptor 1
(x86-mov cgc (x86-rax) (x86-imm-int #x2000004)) ;; "write" system call is 0x2000004
(x86-syscall cgc)
(x86-pop cgc (x86-rax))
(x86-pop cgc (x86-rbx))
(x86-pop cgc (x86-rcx))
(x86-pop cgc (x86-rdx))
(x86-pop cgc (x86-rdi))
(x86-pop cgc (x86-rsi))
(x86-pop cgc (x86-rbp))
(x86-pop cgc (x86-r11))
(x86-ret cgc))))
;; Linux version of write_char
(if (memq (caddr (system-type)) '(linux-gnu))
(case (nat-target-arch targ)
((x86-32)
(x86-label cgc write_char-lbl)
(x86-push cgc (x86-ebp))
(x86-push cgc (x86-esi))
(x86-push cgc (x86-edi))
(x86-push cgc (x86-edx))
(x86-push cgc (x86-ecx))
(x86-push cgc (x86-ebx))
(x86-push cgc (x86-eax)) ;; put character to write on stack
(x86-mov cgc (x86-ecx) (x86-esp)) ;; get address of character in %ecx
(x86-mov cgc (x86-edx) (x86-imm-int 1)) ;; number of bytes to write = 1
(x86-mov cgc (x86-ebx) (x86-imm-int 1)) ;; "stdout" is file descriptor 1
(x86-mov cgc (x86-eax) (x86-imm-int 4)) ;; "write" system call is 4
(x86-int cgc #x80) ;; perform system call (int 0x80)
(x86-pop cgc (x86-eax))
(x86-pop cgc (x86-ebx))
(x86-pop cgc (x86-ecx))
(x86-pop cgc (x86-edx))
(x86-pop cgc (x86-edi))
(x86-pop cgc (x86-esi))
(x86-pop cgc (x86-ebp))
(x86-ret cgc))
((x86-64)
(x86-label cgc write_char-lbl)
;; Save args + destroyed registers
(x86-push cgc (x86-r11))
(x86-push cgc (x86-rbp))
(x86-push cgc (x86-rsi))
(x86-push cgc (x86-rdi))
(x86-push cgc (x86-rdx))
(x86-push cgc (x86-rcx))
(x86-push cgc (x86-rbx))
(x86-push cgc (x86-rax)) ;; put character to write on stack
;; Perform "write" syscall
(x86-mov cgc (x86-rdi) (x86-imm-int 1)) ;; fd = stdout
(x86-mov cgc (x86-rsi) (x86-rsp)) ;; buf = 0(%esp)
(x86-mov cgc (x86-rdx) (x86-imm-int 1)) ;; count = 1
(x86-mov cgc (x86-rax) (x86-imm-int 1)) ;; write
(x86-syscall cgc)
(x86-pop cgc (x86-rax))
(x86-pop cgc (x86-rbx))
(x86-pop cgc (x86-rcx))
(x86-pop cgc (x86-rdx))
(x86-pop cgc (x86-rdi))
(x86-pop cgc (x86-rsi))
(x86-pop cgc (x86-rbp))
(x86-pop cgc (x86-r11))
(x86-ret cgc))))
))
(define make-temp-label
(let ((n 0))
(lambda (cgc)
(set! n (+ n 1))
(let* ((g (gensym))
(label-name (lbl->id n (symbol->string g))))
(asm-make-label cgc label-name)))))
;; (define (generate-primitives cgc)
;; (let ((targ (codegen-context-target cgc)))
;; ;; ##not
;; (let ((entry-label (nat-label-ref targ (lbl->id 1 "##not")))
;; (eq-label (make-temp-label cgc)))
;; (x86-label cgc entry-label)
;; (x86-cmp cgc (vector-ref (nat-target-gvm-reg-map targ) 1) false)
;; (x86-je cgc eq-label)
;; (x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) false)
;; (x86-jmp cgc (vector-ref (nat-target-gvm-reg-map targ) 0))
;; (x86-label cgc eq-label)
;; (x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) true)
;; (x86-jmp cgc (vector-ref (nat-target-gvm-reg-map targ) 0))
;; ;; Update primitives table.
;; (let ((not-prim (x86-prim-info* '##not)))
;; (proc-obj-test-set! not-prim
;; (lambda (cgc args true-lbl false-lbl)
;; (x86-cmp cgc (nat-opnd cgc (make-ctx targ #f) (car args)) false)
;; (x86-jne cgc false-lbl)
;; (x86-jmp cgc true-lbl)))))))
(define (x86-prim-define
name
proc-safe?
side-effects?
apply-gen
#!optional
(ifjump-gen #f)
(jump-gen #f))
(let ((prim (x86-prim-info* (string->canonical-symbol name))))
(if apply-gen
(begin
(proc-obj-inlinable?-set!
prim
(lambda (env)
(or proc-safe? (not (safe? env)))))
(proc-obj-inline-set!
prim
(lambda (cgc opnds loc)
(let ((targ (codegen-context-target cgc)))
(if loc
(apply-gen cgc opnds loc)
(if side-effects?
(apply-gen cgc opnds #f))))))))
(if ifjump-gen
(begin
(proc-obj-testable?-set!
prim
(lambda (env)
(or proc-safe? (not (safe? env)))))
(proc-obj-test-set!
prim
(lambda (cgc ctx opnds true-branch false-branch)
(ifjump-gen cgc ctx opnds true-branch false-branch)))))
(if jump-gen
(begin
(proc-obj-jump-inlinable?-set!
prim
(lambda (env) #t))
(proc-obj-jump-inline-set!
prim
jump-gen)))))
(x86-prim-define "##not" #t #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(is-false-lbl (make-temp-label cgc))
(end-if-lbl (make-temp-label cgc))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(opnd (nat-opnd cgc (make-ctx targ #f) (list-ref opnds 0)))
(translated-loc (nat-opnd cgc (make-ctx targ #f) loc)))
(if (not (eq? translated-loc r1))
(x86-push cgc r1))
(if (not (eq? r1 opnd))
(x86-mov cgc r1 opnd))
(x86-cmp cgc r1 false)
(x86-je cgc is-false-lbl)
(x86-mov cgc r1 false)
(x86-jmp cgc end-if-lbl)
(x86-label cgc is-false-lbl)
(x86-mov cgc r1 true)
(x86-label cgc end-if-lbl)
(if (not (eq? translated-loc r1))
(x86-mov cgc translated-loc r1))
(if (not (eq? translated-loc r1))
(x86-pop cgc r1))))
(lambda (cgc ctx opnds true-branch false-branch)
;; (let* ((targ (codegen-context-target cgc))
;; (true-lbl (nat-label-ref cgc (lbl->id true* (ctx-ns ctx))))
;; (false-lbl (nat-label-ref cgc (lbl->id false* (ctx-ns ctx)))))
;; (test cgc opnds)
;; (x86-jne cgc false-lbl)
;; (x86-jmp cgc true-lbl)))
(let* ((targ (codegen-context-target cgc))
(opnd (nat-opnd cgc (make-ctx targ #f) (car opnds)))
(true-lbl (nat-label-ref cgc (lbl->id true-branch (ctx-ns ctx))))
(false-lbl (nat-label-ref cgc (lbl->id false-branch (ctx-ns ctx)))))
(if (x86-reg? opnd)
(x86-cmp cgc opnd false)
(begin
(x86-push cgc (vector-ref (nat-target-gvm-reg-map targ) 1))
(x86-mov cgc (vector-ref (nat-target-gvm-reg-map targ) 1) opnd)
(x86-cmp cgc (vector-ref (nat-target-gvm-reg-map targ) 1) false)
(x86-pop cgc (vector-ref (nat-target-gvm-reg-map targ) 1))))
(x86-jne cgc false-lbl)
(x86-jmp cgc true-lbl))))
(define (mov cgc loc value)
(if (or (x86-reg? loc) (x86-reg? value))
(x86-mov cgc loc value)
(let* ((targ (codegen-context-target cgc))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1)))
(x86-push cgc r1)
(x86-mov cgc r1 value)
(x86-mov cgc loc r1)
(x86-pop cgc r1))))
(define (remove x xs)
(cond ((null? xs) '())
((eq? x (car xs)) (cdr xs))
(else (cons (car xs) (remove x (cdr xs))))))
;; if loc is a register:
;; if loc is in opnds:
;; remove loc from opnds
;; add each opnd in opnds to loc
;; else:
;; move (car opnds) into loc
;; add each opnd in (cdr opnds) to loc
;; else:
;; if r1 { accumulating register } is in opnds:
;; push r1
;; remove r1 from opnds
;; add each opnd in opnds to r1
;; move r1 into loc
;; pop r1
;; else:
;; push r1
;; move (car opnd) into r1
;; add each opnd in (cdr opnds) to r1
;; move r1 into loc
;; pop r1
(define (fxadd-nary cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(loc (nat-opnd cgc ctx loc))
(opnds (map (lambda (opnd) (nat-opnd cgc ctx opnd)) opnds)))
(cond ((x86-reg? loc)
(cond ((member loc opnds)
(let ((opnds2 (remove loc opnds)))
(for-each (lambda (opnd) (x86-add cgc loc opnd)) opnds2)))
(else
(x86-mov cgc loc (car opnds))
(for-each (lambda (opnd) (x86-add cgc loc opnd)) (cdr opnds)))))
(else
(cond ((member r1 opnds)
(let ((opnds2 (remove r1 opnds)))
(x86-push cgc r1)
(for-each (lambda (opnd) (x86-add cgc r1 opnd)) opnds2)
(x86-mov cgc loc r1)
(x86-pop cgc r1)))
(else
(x86-push cgc r1)
(x86-mov cgc r1 (car opnds))
(for-each (lambda (opnd) (x86-add cgc r1 opnd)) (cdr opnds))
(x86-mov cgc loc r1)
(x86-pop cgc r1)))))))
;; TODO: handle >2-ary cases
(x86-prim-define "##fx+" #f #f
(lambda (cgc opnds loc)
(let ((ctx (make-ctx (codegen-context-target cgc) #f)))
(cond ((null? opnds) (mov cgc (nat-opnd cgc ctx loc) (x86-imm-int 0)))
((null? (cdr opnds))
(mov cgc (nat-opnd cgc ctx loc) (nat-opnd cgc ctx (car opnds))))
(else (fxadd-nary cgc opnds loc))))))
(x86-prim-define "##fx+?" #f #f
(lambda (cgc opnds loc)
(if (not (= 2 (length opnds)))
(compiler-internal-error "##fx+? takes only 2 arguments")
(let* ((no-overflow (make-temp-label cgc))
(targ (codegen-context-target cgc))
(translated-loc (nat-opnd cgc (make-ctx targ #f) loc)))
(fxadd-nary cgc opnds loc)
(x86-jno cgc no-overflow)
(mov cgc translated-loc false)
(x86-label cgc no-overflow)))))
(define (fxmul-nary cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(loc (nat-opnd cgc ctx loc))
(opnds (map (lambda (opnd) (nat-opnd cgc ctx opnd)) opnds)))
(cond ((x86-reg? loc)
(cond ((member loc opnds)
(let ((opnds2 (remove loc opnds)))
(for-each (lambda (opnd)
(unbox-fixnum cgc loc)
(x86-imul cgc loc opnd))
opnds2)))
(else
(x86-mov cgc loc (car opnds))
(for-each (lambda (opnd)
(unbox-fixnum cgc loc)
(x86-imul cgc loc opnd))
(cdr opnds)))))
(else
(cond ((member r1 opnds)
(let ((opnds2 (remove r1 opnds)))
(x86-push cgc r1)
(for-each (lambda (opnd)
(unbox-fixnum cgc r1)
(x86-imul cgc r1 opnd))
opnds2)
(x86-mov cgc loc r1)
(x86-pop cgc r1)))
(else
(x86-push cgc r1)
(x86-mov cgc r1 (car opnds))
(for-each (lambda (opnd)
(unbox-fixnum cgc r1)
(x86-imul cgc r1 opnd))
(cdr opnds))
(x86-mov cgc loc r1)
(x86-pop cgc r1)))))))
;; TODO: handle >2-ary cases
(x86-prim-define "##fx*" #f #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(translated-loc (nat-opnd cgc ctx loc)))
(cond ((null? opnds) (mov cgc (nat-opnd cgc ctx loc) (x86-imm-int 1)))
((null? (cdr opnds)) (mov cgc
(nat-opnd cgc ctx loc)
(nat-opnd cgc ctx (car opnds))))
(else (fxmul-nary cgc opnds loc))))))
(define fxsub-nary
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(translated-loc (nat-opnd cgc ctx loc))
(opnd1 (nat-opnd cgc ctx (list-ref opnds 0)))
(opnd2 (nat-opnd cgc ctx (list-ref opnds 1))))
(if (x86-reg? translated-loc)
(cond ((eq? translated-loc opnd1) (x86-sub cgc translated-loc opnd2))
((eq? translated-loc opnd2)
(x86-neg cgc opnd2)
(x86-add cgc translated-loc opnd1)
(x86-neg cgc opnd2))
(else
(x86-mov cgc translated-loc opnd1)
(x86-sub cgc translated-loc opnd2)))
(cond ((x86-reg? opnd1)
(x86-push cgc opnd1)
(x86-sub cgc opnd1 opnd2)
(x86-mov cgc translated-loc opnd1)
(x86-pop cgc opnd1))
((x86-reg? opnd2)
(x86-push cgc opnd2)
(x86-sub cgc opnd2 opnd1)
(x86-mov cgc translated-loc opnd2)
(x86-pop cgc opnd2))
(else
(x86-push cgc r1)
(x86-mov cgc r1 opnd1)
(x86-sub cgc r1 opnd2)
(x86-mov cgc translated-loc r1)
(x86-pop cgc r1)))))))
(define (fxnegate cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(opnd (nat-opnd cgc ctx (car opnds)))
(loc (nat-opnd cgc ctx loc)))
(if (x86-reg? loc)
(begin
(x86-mov cgc loc opnd)
(x86-neg cgc loc))
(let ((r1 (vector-ref (nat-target-gvm-reg-map targ) 1)))
(x86-push cgc r1)
(x86-mov cgc r1 opnd)
(x86-neg cgc r1)
(x86-mov cgc loc r1)
(x86-pop cgc r1)))))
;; TODO: handle >2-ary cases
(x86-prim-define "##fx-" #f #f
(lambda (cgc opnds loc)
(cond ((null? opnds) (compiler-internal-error "##fx- requires at least one argument"))
((null? (cdr opnds)) (fxnegate cgc opnds loc))
(else (fxsub-nary cgc opnds loc)))))
(x86-prim-define "##fx-?" #f #f
(lambda (cgc opnds loc)
(cond ((not (= 2 (length opnds)))
(compiler-internal-error "##fx-? requires exactly 2 arguments"))
(else
(let* ((no-overflow (make-temp-label cgc))
(targ (codegen-context-target cgc))
(translated-loc (nat-opnd cgc (make-ctx targ #f) loc)))
(fxsub-nary cgc opnds loc)
(x86-jno cgc no-overflow)
(mov cgc translated-loc false)
(x86-label cgc no-overflow))))))
;; FIXME: what to do with immediate values?
(define (box/unbox-fixnum cgc opnd fn)
(cond
((x86-reg? opnd)
(fn cgc opnd (x86-imm-int 2)))
(else
(let* ((targ (codegen-context-target cgc))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1)))
(x86-push cgc r1)
(x86-mov cgc r1 opnd)
(fn cgc r1 (x86-imm-int 2))
(x86-mov cgc opnd r1)
(x86-pop cgc r1)))))
(define (unbox-fixnum cgc opnd)
(box/unbox-fixnum cgc opnd x86-sar))
(define (box-fixnum cgc opnd)
(box/unbox-fixnum cgc opnd x86-shl))
(define (zip-with fn as bs)
(cond
((or (null? as) (null? bs)) '())
(else (cons (fn (car as) (car bs))
(zip-with fn (cdr as) (cdr bs))))))
;; All fixnum primitives (<, <=, =, >=, >) are defined simply in terms
;; of their names and their corresponding jump operation.
;; TODO: variable number of arguments.
(define (define-fxcmp-primitive name jump-op)
(x86-prim-define name #f #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(not-true-lbl (make-temp-label cgc))
(end-if-lbl (make-temp-label cgc))
(ctx (make-ctx targ #f))
(loc (nat-opnd cgc ctx loc))
(opnds (map (lambda (opnd) (nat-opnd cgc ctx opnd)) opnds))
(zipped-opnds (zip-with cons opnds (cdr opnds))))
(if (< (length opnds) 2)
(mov cgc loc true)
(begin
(for-each (lambda (p)
(let ((a (car p))
(b (cdr p)))
(if (or (x86-reg? a) (x86-reg? b))
(x86-cmp cgc a b)
(begin
(x86-push cgc r1)
(x86-mov cgc r1 a)
(x86-cmp cgc r1 b)
(x86-pop cgc r1)))
(jump-op cgc not-true-lbl)))
zipped-opnds)
(x86-mov cgc r1 true)
(x86-jmp cgc end-if-lbl)
(x86-label cgc not-true-lbl)
(x86-mov cgc r1 false)
(x86-label cgc end-if-lbl)))))
(lambda (cgc ctx opnds true-branch false-branch)
(let* ((targ (codegen-context-target cgc))
(true-lbl (nat-label-ref cgc (lbl->id true-branch (ctx-ns ctx))))
(false-lbl (nat-label-ref cgc (lbl->id false-branch (ctx-ns ctx))))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1)))
(if (< (length opnds) 2)
(x86-jmp cgc true-lbl)
(let* ((opnds (map (lambda (opnd) (nat-opnd cgc ctx opnd)) opnds))
(zipped-opnds (zip-with cons opnds (cdr opnds)))
(not-true-lbl (make-temp-label cgc)))
(for-each (lambda (p)
(let ((a (car p))
(b (cdr p)))
(if (or (x86-reg? a) (x86-reg? b))
(x86-cmp cgc a b)
(begin
(x86-push cgc r1)
(x86-mov cgc r1 a)
(x86-cmp cgc r1 b)
(x86-pop cgc r1)))
(jump-op cgc not-true-lbl)))
zipped-opnds)
(x86-jmp cgc true-lbl)
(x86-label cgc not-true-lbl)
(x86-jmp cgc false-lbl)))))))
(x86-prim-define "##fixnum?" #f #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(not-fixnum-lbl (make-temp-label cgc))
(end-if-lbl (make-temp-label cgc))
(ctx (make-ctx targ #f))
(opnd (nat-opnd cgc ctx (list-ref opnds 0)))
(loc (nat-opnd cgc ctx loc)))
(if (x86-reg? loc)
(begin
(x86-mov cgc loc opnd)
(x86-and cgc loc (x86-imm-int 3))
(x86-jne cgc not-fixnum-lbl)
(x86-mov cgc loc true)
(x86-jmp cgc end-if-lbl)
(x86-label cgc not-fixnum-lbl)
(x86-mov cgc loc false)
(x86-label cgc end-if-lbl))
(begin
(x86-push cgc r1)
(x86-mov cgc r1 opnd)
(x86-and cgc r1 (x86-imm-int 3))
(x86-jne cgc not-fixnum-lbl)
(mov cgc loc true)
(x86-jmp cgc end-if-lbl)
(x86-label cgc not-fixnum-lbl)
(mov cgc loc false)
(x86-label cgc end-if-lbl)
(x86-pop cgc r1)))))
(lambda (cgc ctx opnds true-branch false-branch)
(let* ((targ (codegen-context-target cgc))
(true-lbl (nat-label-ref cgc (lbl->id true-branch (ctx-ns ctx))))
(false-lbl (nat-label-ref cgc (lbl->id false-branch (ctx-ns ctx))))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(opnd (nat-opnd cgc ctx (list-ref opnds 0))))
(if (x86-reg? opnd)
(begin
(x86-push cgc opnd)
(x86-and cgc opnd (x86-imm-int 3))
(x86-pop cgc opnd)
(x86-je cgc true-lbl)
(x86-jmp cgc false-lbl))
(begin
(x86-push cgc r1)
(x86-mov cgc r1 opnd)
(x86-and cgc r1 (x86-imm-int 3))
(x86-pop cgc r1)
(x86-je cgc true-lbl)
(x86-jmp cgc false-lbl))))))
;; Use the opposite operator to make code easier to generate.
;; e.g.:
;; (< 1 2 3)
;; =>
;; cmp 1 2
;; jge not-true
;; cmp 2 3
;; jge not-true
;; mov true, r1
;; jmp end-if
;; not-true:
;; mov false, r1
;; jmp end-if
;; end-if:
(define-fxcmp-primitive "##fx<" x86-jge)
(define-fxcmp-primitive "##fx<=" x86-jg)
(define-fxcmp-primitive "##fx>" x86-jle)
(define-fxcmp-primitive "##fx>=" x86-jl)
(define-fxcmp-primitive "##fx=" x86-jne)
(x86-prim-define "##cons" #t #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(sp (nat-target-heap-ptr-reg targ))
(loc (nat-opnd cgc ctx loc)))
(x86-push cgc (nat-opnd cgc ctx (list-ref opnds 0)))
(x86-push cgc (nat-opnd cgc ctx (list-ref opnds 1)))
(x86-push cgc (x86-imm-int (macro-subtype-pair)))
(x86-mov cgc loc sp))))
;; Create the primitive op-name (##car, ##caar, etc.) by following the
;; links (as described in operations).
(define (x86-define-cxxxxr op-name operations)
(x86-prim-define op-name #f #f
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(pair (nat-opnd cgc ctx (car opnds)))
(loc (nat-opnd cgc ctx loc))
(working-reg (nat-target-pstate-ptr-reg targ)))
(x86-push cgc working-reg)
(x86-mov cgc working-reg pair)
(for-each
(lambda (car-or-cdr)
(let ((offset (if (eq? car-or-cdr 'a)
(* 2 (nat-target-word-width targ))
(nat-target-word-width targ))))
(x86-mov cgc working-reg (x86-mem offset working-reg))))
operations)
(x86-mov cgc loc working-reg)
(x86-pop cgc working-reg)))))
(x86-define-cxxxxr "##car" (reverse '(a)))
(x86-define-cxxxxr "##cdr" (reverse '(d)))
(x86-define-cxxxxr "##caar" (reverse '(a a)))
(x86-define-cxxxxr "##cadr" (reverse '(a d)))
(x86-define-cxxxxr "##cddr" (reverse '(d d)))
(x86-define-cxxxxr "##cdar" (reverse '(d a)))
(x86-define-cxxxxr "##caaar" (reverse '(a a a)))
(x86-define-cxxxxr "##caadr" (reverse '(a a d)))
(x86-define-cxxxxr "##cadar" (reverse '(a d a)))
(x86-define-cxxxxr "##caddr" (reverse '(a d d)))
(x86-define-cxxxxr "##cdaar" (reverse '(d a a)))
(x86-define-cxxxxr "##cdadr" (reverse '(d a d)))
(x86-define-cxxxxr "##cddar" (reverse '(d d a)))
(x86-define-cxxxxr "##cdddr" (reverse '(d d d)))
(x86-define-cxxxxr "##caaaar" (reverse '(a a a a)))
(x86-define-cxxxxr "##cdaaar" (reverse '(d a a a)))
(x86-define-cxxxxr "##cadaar" (reverse '(a d a a)))
(x86-define-cxxxxr "##cddaar" (reverse '(d d a a)))
(x86-define-cxxxxr "##caadar" (reverse '(a a d a)))
(x86-define-cxxxxr "##cdadar" (reverse '(d a d a)))
(x86-define-cxxxxr "##caddar" (reverse '(a d d a)))
(x86-define-cxxxxr "##cdddar" (reverse '(d d d a)))
(x86-define-cxxxxr "##caaadr" (reverse '(a a a d)))
(x86-define-cxxxxr "##cdaadr" (reverse '(d a a d)))
(x86-define-cxxxxr "##cadadr" (reverse '(a d a d)))
(x86-define-cxxxxr "##cddadr" (reverse '(d d a d)))
(x86-define-cxxxxr "##caaddr" (reverse '(a a d d)))
(x86-define-cxxxxr "##cdaddr" (reverse '(d a d d)))
(x86-define-cxxxxr "##cadddr" (reverse '(a d d d)))
(x86-define-cxxxxr "##cddddr" (reverse '(d d d d)))
(define (##set-car/cdr name offset)
(x86-prim-define name #f #t
(lambda (cgc opnds loc)
(let* ((targ (codegen-context-target cgc))
(ctx (make-ctx targ #f))
(loc (if loc (nat-opnd cgc ctx loc) loc))
(pair (nat-opnd cgc ctx (list-ref opnds 0)))
(value (nat-opnd cgc ctx (list-ref opnds 1)))
(r1 (vector-ref (nat-target-gvm-reg-map targ) 1))
(r2 (vector-ref (nat-target-gvm-reg-map targ) 2)))
(x86-push cgc r1)
(x86-push cgc r2)
(x86-mov cgc r1 pair)
(x86-mov cgc r2 value)
(x86-mov cgc (x86-mem (* offset (nat-target-word-width targ)) r1) r2)
(x86-pop cgc r2)
(x86-pop cgc r1)
(if loc
(mov cgc loc pair))))))
(##set-car/cdr "##set-car!" 2)
(##set-car/cdr "##set-cdr!" 1)
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