1 ;;;; the VM definition of function call for MIPS
3 ;;;; This software is part of the SBCL system. See the README file for
6 ;;;; This software is derived from the CMU CL system, which was
7 ;;;; written at Carnegie Mellon University and released into the
8 ;;;; public domain. The software is in the public domain and is
9 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
10 ;;;; files for more information.
14 ;;;; Interfaces to IR2 conversion:
16 ;;; Return a wired TN describing the N'th full call argument passing
18 (!def-vm-support-routine standard-arg-location (n)
19 (declare (type unsigned-byte n))
20 (if (< n register-arg-count)
21 (make-wired-tn *backend-t-primitive-type*
23 (elt *register-arg-offsets* n))
24 (make-wired-tn *backend-t-primitive-type*
25 control-stack-arg-scn n)))
28 ;;; Make a passing location TN for a local call return PC. If standard is
29 ;;; true, then use the standard (full call) location, otherwise use any legal
30 ;;; location. Even in the non-standard case, this may be restricted by a
31 ;;; desire to use a subroutine call instruction.
32 (!def-vm-support-routine make-return-pc-passing-location (standard)
34 (make-wired-tn *backend-t-primitive-type* register-arg-scn lra-offset)
35 (make-restricted-tn *backend-t-primitive-type* register-arg-scn)))
37 ;;; This is similar to MAKE-RETURN-PC-PASSING-LOCATION, but makes a
38 ;;; location to pass Old-FP in. This is (obviously) wired in the
39 ;;; standard convention, but is totally unrestricted in non-standard
40 ;;; conventions, since we can always fetch it off of the stack using
42 (!def-vm-support-routine make-old-fp-passing-location (standard)
44 (make-wired-tn *fixnum-primitive-type* immediate-arg-scn ocfp-offset)
45 (make-normal-tn *fixnum-primitive-type*)))
47 ;;; Make the TNs used to hold OLD-FP and RETURN-PC within the current
48 ;;; function. We treat these specially so that the debugger can find
49 ;;; them at a known location.
50 (!def-vm-support-routine make-old-fp-save-location (env)
52 (physenv-debug-live-tn (make-normal-tn *fixnum-primitive-type*) env)
53 (make-wired-tn *fixnum-primitive-type*
56 (!def-vm-support-routine make-return-pc-save-location (env)
57 (let ((ptype *backend-t-primitive-type*))
59 (physenv-debug-live-tn (make-normal-tn ptype) env)
60 (make-wired-tn ptype control-stack-arg-scn lra-save-offset))))
62 ;;; Make a TN for the standard argument count passing location. We only
63 ;;; need to make the standard location, since a count is never passed when we
64 ;;; are using non-standard conventions.
65 (!def-vm-support-routine make-arg-count-location ()
66 (make-wired-tn *fixnum-primitive-type* immediate-arg-scn nargs-offset))
69 ;;; Make a TN to hold the number-stack frame pointer. This is allocated
70 ;;; once per component, and is component-live.
71 (!def-vm-support-routine make-nfp-tn ()
73 (make-wired-tn *fixnum-primitive-type* immediate-arg-scn nfp-offset)))
75 (!def-vm-support-routine make-stack-pointer-tn ()
76 (make-normal-tn *fixnum-primitive-type*))
78 (!def-vm-support-routine make-number-stack-pointer-tn ()
79 (make-normal-tn *fixnum-primitive-type*))
81 ;;; Return a list of TNs that can be used to represent an unknown-values
82 ;;; continuation within a function.
83 (!def-vm-support-routine make-unknown-values-locations ()
84 (list (make-stack-pointer-tn)
85 (make-normal-tn *fixnum-primitive-type*)))
88 ;;; This function is called by the ENTRY-ANALYZE phase, allowing
89 ;;; VM-dependent initialization of the IR2-COMPONENT structure. We push
90 ;;; placeholder entries in the Constants to leave room for additional
91 ;;; noise in the code object header.
92 (!def-vm-support-routine select-component-format (component)
93 (declare (type component component))
94 (dotimes (i code-constants-offset)
95 (vector-push-extend nil
96 (ir2-component-constants (component-info component))))
102 ;;; BYTES-NEEDED-FOR-NON-DESCRIPTOR-STACK-FRAME -- internal
104 ;;; Return the number of bytes needed for the current non-descriptor stack
105 ;;; frame. Non-descriptor stack frames must be multiples of 8 bytes on
108 (defun bytes-needed-for-non-descriptor-stack-frame ()
109 (* (logandc2 (1+ (sb-allocated-size 'non-descriptor-stack)) 1)
112 ;;; Used for setting up the Old-FP in local call.
114 (define-vop (current-fp)
115 (:results (val :scs (any-reg)))
119 ;;; Used for computing the caller's NFP for use in known-values return. Only
120 ;;; works assuming there is no variable size stuff on the nstack.
122 (define-vop (compute-old-nfp)
123 (:results (val :scs (any-reg)))
126 (let ((nfp (current-nfp-tn vop)))
128 (inst addu val nfp (bytes-needed-for-non-descriptor-stack-frame))))))
131 (define-vop (xep-allocate-frame)
132 (:info start-lab copy-more-arg-follows)
133 (:ignore copy-more-arg-follows)
135 (:temporary (:scs (non-descriptor-reg)) temp)
137 ;; Make sure the function is aligned, and drop a label pointing to this
139 (align n-lowtag-bits)
140 (trace-table-entry trace-table-fun-prologue)
141 (emit-label start-lab)
142 ;; Allocate function header.
143 (inst fun-header-word)
144 (dotimes (i (1- simple-fun-code-offset))
146 ;; The start of the actual code.
147 ;; Compute CODE from the address of this entry point.
148 (let ((entry-point (gen-label)))
149 (emit-label entry-point)
150 (inst compute-code-from-fn code-tn lip-tn entry-point temp)
151 ;; ### We should also save it on the stack so that the garbage collector
152 ;; won't forget about us if we call anyone else.
154 ;; Build our stack frames.
155 (inst addu csp-tn cfp-tn
156 (* n-word-bytes (sb-allocated-size 'control-stack)))
157 (let ((nfp (current-nfp-tn vop)))
159 (inst addu nsp-tn nsp-tn
160 (- (bytes-needed-for-non-descriptor-stack-frame)))
162 (trace-table-entry trace-table-normal)))
164 (define-vop (allocate-frame)
165 (:results (res :scs (any-reg))
166 (nfp :scs (any-reg)))
169 (trace-table-entry trace-table-fun-prologue)
171 (inst addu csp-tn csp-tn
172 (* n-word-bytes (sb-allocated-size 'control-stack)))
173 (when (ir2-physenv-number-stack-p callee)
174 (inst addu nsp-tn nsp-tn
175 (- (bytes-needed-for-non-descriptor-stack-frame)))
177 (trace-table-entry trace-table-normal)))
179 ;;; Allocate a partial frame for passing stack arguments in a full call. Nargs
180 ;;; is the number of arguments passed. If no stack arguments are passed, then
181 ;;; we don't have to do anything.
183 (define-vop (allocate-full-call-frame)
185 (:results (res :scs (any-reg)))
187 (when (> nargs register-arg-count)
189 (inst addu csp-tn csp-tn (* nargs n-word-bytes)))))
194 ;;; Emit code needed at the return-point from an unknown-values call for a
195 ;;; fixed number of values. Values is the head of the TN-Ref list for the
196 ;;; locations that the values are to be received into. Nvals is the number of
197 ;;; values that are to be received (should equal the length of Values).
199 ;;; MOVE-TEMP is a DESCRIPTOR-REG TN used as a temporary.
201 ;;; This code exploits the fact that in the unknown-values convention, a
202 ;;; single value return returns at the return PC + 8, whereas a return of other
203 ;;; than one value returns directly at the return PC.
205 ;;; If 0 or 1 values are expected, then we just emit an instruction to reset
206 ;;; the SP (which will only be executed when other than 1 value is returned.)
208 ;;; In the general case, we have to do three things:
209 ;;; -- Default unsupplied register values. This need only be done when a
210 ;;; single value is returned, since register values are defaulted by the
211 ;;; called in the non-single case.
212 ;;; -- Default unsupplied stack values. This needs to be done whenever there
213 ;;; are stack values.
214 ;;; -- Reset SP. This must be done whenever other than 1 value is returned,
215 ;;; regardless of the number of values desired.
217 ;;; The general-case code looks like this:
219 b regs-defaulted ; Skip if MVs
222 move a1 null-tn ; Default register values
224 loadi nargs 1 ; Force defaulting of stack values
225 move ocfp csp ; Set up args for SP resetting
228 subu temp nargs register-arg-count
230 bltz temp default-value-7 ; jump to default code
232 loadw move-temp ocfp-tn 6 ; Move value to correct location.
233 store-stack-tn val4-tn move-temp
235 bltz temp default-value-8
237 loadw move-temp ocfp-tn 7
238 store-stack-tn val5-tn move-temp
243 move sp ocfp ; Reset SP.
248 store-stack-tn val4-tn null-tn ; Nil out 7'th value. (first on stack)
251 store-stack-tn val5-tn null-tn ; Nil out 8'th value.
259 (defun default-unknown-values (vop values nvals move-temp temp lra-label)
260 (declare (type (or tn-ref null) values)
261 (type unsigned-byte nvals) (type tn move-temp temp))
264 ;; Note that this is a single-value return point. This is actually
265 ;; the multiple-value entry point for a single desired value, but
266 ;; the code location has to be here, or the debugger backtrace
268 (without-scheduling ()
269 (note-this-location vop :single-value-return)
270 (inst move csp-tn ocfp-tn)
273 (inst compute-code-from-lra code-tn code-tn lra-label temp)))
274 (let ((regs-defaulted (gen-label))
275 (defaulting-done (gen-label))
276 (default-stack-vals (gen-label)))
277 (without-scheduling ()
278 ;; Note that this is an unknown-values return point.
279 (note-this-location vop :unknown-return)
280 ;; Branch off to the MV case.
281 (inst b regs-defaulted)
282 ;; If there are no stack results, clear the stack now.
283 (if (> nvals register-arg-count)
284 (inst addu temp nargs-tn (fixnumize (- register-arg-count)))
285 (move csp-tn ocfp-tn t)))
287 ;; Do the single value calse.
289 (val (tn-ref-across values) (tn-ref-across val)))
290 ((= i (min nvals register-arg-count)))
291 (move (tn-ref-tn val) null-tn))
292 (when (> nvals register-arg-count)
293 (inst b default-stack-vals)
294 (move ocfp-tn csp-tn t))
296 (emit-label regs-defaulted)
298 (when (> nvals register-arg-count)
299 ;; If there are stack results, we have to default them
300 ;; and clear the stack.
301 (collect ((defaults))
302 (do ((i register-arg-count (1+ i))
303 (val (do ((i 0 (1+ i))
304 (val values (tn-ref-across val)))
305 ((= i register-arg-count) val))
306 (tn-ref-across val)))
309 (let ((default-lab (gen-label))
310 (tn (tn-ref-tn val)))
311 (defaults (cons default-lab tn))
313 (inst blez temp default-lab)
314 (inst lw move-temp ocfp-tn (* i n-word-bytes))
315 (inst addu temp temp (fixnumize -1))
316 (store-stack-tn tn move-temp)))
318 (emit-label defaulting-done)
319 (move csp-tn ocfp-tn)
321 (let ((defaults (defaults)))
323 (assemble (*elsewhere*)
324 (emit-label default-stack-vals)
325 (do ((remaining defaults (cdr remaining)))
327 (let ((def (car remaining)))
328 (emit-label (car def))
329 (when (null (cdr remaining))
330 (inst b defaulting-done))
331 (store-stack-tn (cdr def) null-tn)))))))
334 (inst compute-code-from-lra code-tn code-tn lra-label temp))))
338 ;;;; Unknown values receiving:
340 ;;; Emit code needed at the return point for an unknown-values call for an
341 ;;; arbitrary number of values.
343 ;;; We do the single and non-single cases with no shared code: there doesn't
344 ;;; seem to be any potential overlap, and receiving a single value is more
345 ;;; important efficiency-wise.
347 ;;; When there is a single value, we just push it on the stack, returning
348 ;;; the old SP and 1.
350 ;;; When there is a variable number of values, we move all of the argument
351 ;;; registers onto the stack, and return Args and Nargs.
353 ;;; Args and Nargs are TNs wired to the named locations. We must
354 ;;; explicitly allocate these TNs, since their lifetimes overlap with the
355 ;;; results Start and Count (also, it's nice to be able to target them).
357 (defun receive-unknown-values (args nargs start count lra-label temp)
358 (declare (type tn args nargs start count temp))
359 (let ((variable-values (gen-label))
361 (without-scheduling ()
362 (inst b variable-values)
366 (inst compute-code-from-lra code-tn code-tn lra-label temp))
367 (inst addu csp-tn csp-tn 4)
368 (storew (first register-arg-tns) csp-tn -1)
369 (inst addu start csp-tn -4)
370 (inst li count (fixnumize 1))
374 (assemble (*elsewhere*)
375 (emit-label variable-values)
377 (inst compute-code-from-lra code-tn code-tn lra-label temp))
378 (do ((arg register-arg-tns (rest arg))
381 (storew (first arg) args i))
384 (move count nargs t)))
388 ;;; VOP that can be inherited by unknown values receivers. The main thing this
389 ;;; handles is allocation of the result temporaries.
391 (define-vop (unknown-values-receiver)
393 (start :scs (any-reg))
394 (count :scs (any-reg)))
395 (:temporary (:sc descriptor-reg :offset ocfp-offset
396 :from :eval :to (:result 0))
398 (:temporary (:sc any-reg :offset nargs-offset
399 :from :eval :to (:result 1))
401 (:temporary (:scs (non-descriptor-reg)) temp))
405 ;;;; Local call with unknown values convention return:
407 ;;; Non-TR local call for a fixed number of values passed according to the
408 ;;; unknown values convention.
410 ;;; Args are the argument passing locations, which are specified only to
411 ;;; terminate their lifetimes in the caller.
413 ;;; Values are the return value locations (wired to the standard passing
416 ;;; Save is the save info, which we can ignore since saving has been done.
417 ;;; Return-PC is the TN that the return PC should be passed in.
418 ;;; Target is a continuation pointing to the start of the called function.
419 ;;; Nvals is the number of values received.
421 ;;; Note: we can't use normal load-tn allocation for the fixed args, since all
422 ;;; registers may be tied up by the more operand. Instead, we use
423 ;;; MAYBE-LOAD-STACK-TN.
425 (define-vop (call-local)
429 (:results (values :more t))
431 (:move-args :local-call)
432 (:info arg-locs callee target nvals)
434 (:temporary (:scs (descriptor-reg) :from :eval) move-temp)
435 (:temporary (:scs (non-descriptor-reg)) temp)
436 (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save)
437 (:temporary (:sc any-reg :offset ocfp-offset :from :eval) ocfp)
438 (:ignore arg-locs args ocfp)
440 (let ((label (gen-label))
441 (cur-nfp (current-nfp-tn vop)))
443 (store-stack-tn nfp-save cur-nfp))
444 (let ((callee-nfp (callee-nfp-tn callee)))
446 (maybe-load-stack-tn callee-nfp nfp)))
447 (maybe-load-stack-tn cfp-tn fp)
448 (trace-table-entry trace-table-call-site)
449 (inst compute-lra-from-code
450 (callee-return-pc-tn callee) code-tn label temp)
451 (note-this-location vop :call-site)
454 (trace-table-entry trace-table-normal)
455 (emit-return-pc label)
456 (default-unknown-values vop values nvals move-temp temp label)
458 (load-stack-tn cur-nfp nfp-save)))))
461 ;;; Non-TR local call for a variable number of return values passed according
462 ;;; to the unknown values convention. The results are the start of the values
463 ;;; glob and the number of values received.
465 ;;; Note: we can't use normal load-tn allocation for the fixed args, since all
466 ;;; registers may be tied up by the more operand. Instead, we use
467 ;;; MAYBE-LOAD-STACK-TN.
469 (define-vop (multiple-call-local unknown-values-receiver)
474 (:move-args :local-call)
475 (:info save callee target)
478 (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save)
480 (let ((label (gen-label))
481 (cur-nfp (current-nfp-tn vop)))
483 (store-stack-tn nfp-save cur-nfp))
484 (let ((callee-nfp (callee-nfp-tn callee)))
486 (maybe-load-stack-tn callee-nfp nfp)))
487 (maybe-load-stack-tn cfp-tn fp)
488 (trace-table-entry trace-table-call-site)
489 (inst compute-lra-from-code
490 (callee-return-pc-tn callee) code-tn label temp)
491 (note-this-location vop :call-site)
494 (trace-table-entry trace-table-normal)
495 (emit-return-pc label)
496 (note-this-location vop :unknown-return)
497 (receive-unknown-values values-start nvals start count label temp)
499 (load-stack-tn cur-nfp nfp-save)))))
502 ;;;; Local call with known values return:
504 ;;; Non-TR local call with known return locations. Known-value return works
505 ;;; just like argument passing in local call.
507 ;;; Note: we can't use normal load-tn allocation for the fixed args, since all
508 ;;; registers may be tied up by the more operand. Instead, we use
509 ;;; MAYBE-LOAD-STACK-TN.
511 (define-vop (known-call-local)
515 (:results (res :more t))
516 (:move-args :local-call)
518 (:info save callee target)
519 (:ignore args res save)
521 (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save)
522 (:temporary (:scs (non-descriptor-reg)) temp)
524 (let ((label (gen-label))
525 (cur-nfp (current-nfp-tn vop)))
527 (store-stack-tn nfp-save cur-nfp))
528 (let ((callee-nfp (callee-nfp-tn callee)))
530 (maybe-load-stack-tn callee-nfp nfp)))
531 (maybe-load-stack-tn cfp-tn fp)
532 (trace-table-entry trace-table-call-site)
533 (inst compute-lra-from-code
534 (callee-return-pc-tn callee) code-tn label temp)
535 (note-this-location vop :call-site)
538 (trace-table-entry trace-table-normal)
539 (emit-return-pc label)
540 (note-this-location vop :known-return)
542 (load-stack-tn cur-nfp nfp-save)))))
544 ;;; Return from known values call. We receive the return locations as
545 ;;; arguments to terminate their lifetimes in the returning function. We
546 ;;; restore FP and CSP and jump to the Return-PC.
548 ;;; Note: we can't use normal load-tn allocation for the fixed args, since all
549 ;;; registers may be tied up by the more operand. Instead, we use
550 ;;; MAYBE-LOAD-STACK-TN.
552 (define-vop (known-return)
553 (:args (ocfp :target ocfp-temp)
554 (return-pc :target return-pc-temp)
556 (:temporary (:sc any-reg :from (:argument 0)) ocfp-temp)
557 (:temporary (:sc descriptor-reg :from (:argument 1))
559 (:temporary (:scs (interior-reg)) lip)
560 (:move-args :known-return)
562 (:ignore val-locs vals)
565 (trace-table-entry trace-table-fun-epilogue)
566 (maybe-load-stack-tn ocfp-temp ocfp)
567 (maybe-load-stack-tn return-pc-temp return-pc)
569 (let ((cur-nfp (current-nfp-tn vop)))
571 (inst addu nsp-tn cur-nfp
572 (bytes-needed-for-non-descriptor-stack-frame))))
573 (inst addu lip return-pc-temp (- n-word-bytes other-pointer-lowtag))
575 (move cfp-tn ocfp-temp t)
576 (trace-table-entry trace-table-normal)))
581 ;;; There is something of a cross-product effect with full calls. Different
582 ;;; versions are used depending on whether we know the number of arguments or
583 ;;; the name of the called function, and whether we want fixed values, unknown
584 ;;; values, or a tail call.
586 ;;; In full call, the arguments are passed creating a partial frame on the
587 ;;; stack top and storing stack arguments into that frame. On entry to the
588 ;;; callee, this partial frame is pointed to by FP. If there are no stack
589 ;;; arguments, we don't bother allocating a partial frame, and instead set FP
590 ;;; to SP just before the call.
592 ;;; This macro helps in the definition of full call VOPs by avoiding code
593 ;;; replication in defining the cross-product VOPs.
595 ;;; Name is the name of the VOP to define.
597 ;;; Named is true if the first argument is a symbol whose global function
598 ;;; definition is to be called.
600 ;;; Return is either :Fixed, :Unknown or :Tail:
601 ;;; -- If :Fixed, then the call is for a fixed number of values, returned in
602 ;;; the standard passing locations (passed as result operands).
603 ;;; -- If :Unknown, then the result values are pushed on the stack, and the
604 ;;; result values are specified by the Start and Count as in the
605 ;;; unknown-values continuation representation.
606 ;;; -- If :Tail, then do a tail-recursive call. No values are returned.
607 ;;; The Ocfp and Return-PC are passed as the second and third arguments.
609 ;;; In non-tail calls, the pointer to the stack arguments is passed as the last
610 ;;; fixed argument. If Variable is false, then the passing locations are
611 ;;; passed as a more arg. Variable is true if there are a variable number of
612 ;;; arguments passed on the stack. Variable cannot be specified with :Tail
613 ;;; return. TR variable argument call is implemented separately.
615 ;;; In tail call with fixed arguments, the passing locations are passed as a
616 ;;; more arg, but there is no new-FP, since the arguments have been set up in
617 ;;; the current frame.
619 (defmacro define-full-call (name named return variable)
620 (aver (not (and variable (eq return :tail))))
622 ,@(when (eq return :unknown)
623 '(unknown-values-receiver)))
625 ,@(unless (eq return :tail)
626 '((new-fp :scs (any-reg) :to :eval)))
629 '(name :target name-pass)
630 '(arg-fun :target lexenv))
632 ,@(when (eq return :tail)
633 '((ocfp :target ocfp-pass)
634 (return-pc :target return-pc-pass)))
636 ,@(unless variable '((args :more t :scs (descriptor-reg)))))
638 ,@(when (eq return :fixed)
639 '((:results (values :more t))))
641 (:save-p ,(if (eq return :tail) :compute-only t))
643 ,@(unless (or (eq return :tail) variable)
644 '((:move-args :full-call)))
647 (:info ,@(unless (or variable (eq return :tail)) '(arg-locs))
648 ,@(unless variable '(nargs))
649 ,@(when (eq return :fixed) '(nvals)))
651 (:ignore ,@(unless (or variable (eq return :tail)) '(arg-locs))
652 ,@(unless variable '(args)))
654 (:temporary (:sc descriptor-reg
657 ,@(unless (eq return :fixed)
661 (:temporary (:sc descriptor-reg
663 :from (:argument ,(if (eq return :tail) 2 1))
668 `((:temporary (:sc descriptor-reg :offset fdefn-offset
669 :from (:argument ,(if (eq return :tail) 0 1))
673 `((:temporary (:sc descriptor-reg :offset lexenv-offset
674 :from (:argument ,(if (eq return :tail) 0 1))
677 (:temporary (:scs (descriptor-reg) :from (:argument 0) :to :eval)
680 (:temporary (:sc any-reg :offset nargs-offset :to :eval)
684 (mapcar #'(lambda (name offset)
685 `(:temporary (:sc descriptor-reg
689 register-arg-names *register-arg-offsets*))
690 ,@(when (eq return :fixed)
691 '((:temporary (:scs (descriptor-reg) :from :eval) move-temp)))
693 ,@(unless (eq return :tail)
694 '((:temporary (:scs (non-descriptor-reg)) temp)
695 (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save)))
697 (:temporary (:sc interior-reg :offset lip-offset) entry-point)
699 (:generator ,(+ (if named 5 0)
701 (if (eq return :tail) 0 10)
703 (if (eq return :unknown) 25 0))
704 (let* ((cur-nfp (current-nfp-tn vop))
705 ,@(unless (eq return :tail)
706 '((lra-label (gen-label))))
710 ,@(if (eq return :tail)
711 '((unless (location= ocfp ocfp-pass)
713 (unless (location= return-pc
723 (flet ((do-next-filler ()
724 (let* ((next (pop filler))
725 (what (if (consp next) (car next) next)))
729 `((inst subu nargs-pass csp-tn new-fp)
731 (mapcar #'(lambda (name)
732 `(inst lw ,name new-fp
735 register-arg-names)))
736 '((inst li nargs-pass (fixnumize nargs)))))
737 ,@(if (eq return :tail)
741 (move ocfp-pass ocfp t))
743 (inst lw ocfp-pass cfp-tn
744 (ash (tn-offset ocfp)
749 (move return-pc-pass return-pc t))
751 (inst lw return-pc-pass cfp-tn
752 (ash (tn-offset return-pc)
755 (inst addu nsp-tn cur-nfp
756 (bytes-needed-for-non-descriptor-stack-frame))))
758 (inst compute-lra-from-code
759 return-pc-pass code-tn lra-label temp))
761 (store-stack-tn nfp-save cur-nfp))
763 (move ocfp-pass cfp-tn t))
766 '(move cfp-tn new-fp)
767 '(if (> nargs register-arg-count)
769 (move cfp-tn csp-tn)))
770 (trace-table-entry trace-table-call-site))))
776 (descriptor-reg (move name-pass name))
778 (inst lw name-pass cfp-tn
779 (ash (tn-offset name) word-shift))
782 (inst lw name-pass code-tn
783 (- (ash (tn-offset name) word-shift)
784 other-pointer-lowtag))
786 (inst lw entry-point name-pass
787 (- (ash fdefn-raw-addr-slot word-shift)
788 other-pointer-lowtag))
791 (descriptor-reg (move lexenv arg-fun))
793 (inst lw lexenv cfp-tn
794 (ash (tn-offset arg-fun) word-shift))
797 (inst lw lexenv code-tn
798 (- (ash (tn-offset arg-fun) word-shift)
799 other-pointer-lowtag))
801 (inst lw function lexenv
802 (- (ash closure-fun-slot word-shift)
805 (inst addu entry-point function
806 (- (ash simple-fun-code-offset word-shift)
807 fun-pointer-lowtag))))
814 (note-this-location vop :call-site)
820 '((trace-table-entry trace-table-normal)
821 (emit-return-pc lra-label)
822 (default-unknown-values vop values nvals
823 move-temp temp lra-label)
825 (load-stack-tn cur-nfp nfp-save))))
827 '((trace-table-entry trace-table-normal)
828 (emit-return-pc lra-label)
829 (note-this-location vop :unknown-return)
830 (receive-unknown-values values-start nvals start count
833 (load-stack-tn cur-nfp nfp-save))))
837 (define-full-call call nil :fixed nil)
838 (define-full-call call-named t :fixed nil)
839 (define-full-call multiple-call nil :unknown nil)
840 (define-full-call multiple-call-named t :unknown nil)
841 (define-full-call tail-call nil :tail nil)
842 (define-full-call tail-call-named t :tail nil)
844 (define-full-call call-variable nil :fixed t)
845 (define-full-call multiple-call-variable nil :unknown t)
848 ;;; Defined separately, since needs special code that BLT's the arguments
851 (define-vop (tail-call-variable)
853 (args-arg :scs (any-reg) :target args)
854 (function-arg :scs (descriptor-reg) :target lexenv)
855 (ocfp-arg :scs (any-reg) :target ocfp)
856 (lra-arg :scs (descriptor-reg) :target lra))
858 (:temporary (:sc any-reg :offset nl0-offset :from (:argument 0)) args)
859 (:temporary (:sc any-reg :offset lexenv-offset :from (:argument 1)) lexenv)
860 (:temporary (:sc any-reg :offset ocfp-offset :from (:argument 2)) ocfp)
861 (:temporary (:sc any-reg :offset lra-offset :from (:argument 3)) lra)
867 ;; Move these into the passing locations if they are not already there.
869 (move lexenv function-arg)
873 ;; Clear the number stack if anything is there and jump to the
874 ;; assembly-routine that does the bliting.
875 (inst j (make-fixup 'tail-call-variable :assembly-routine))
876 (let ((cur-nfp (current-nfp-tn vop)))
878 (inst addu nsp-tn cur-nfp
879 (bytes-needed-for-non-descriptor-stack-frame))
883 ;;;; Unknown values return:
885 ;;; Return a single value using the unknown-values convention.
887 (define-vop (return-single)
888 (:args (ocfp :scs (any-reg))
889 (return-pc :scs (descriptor-reg))
892 (:temporary (:scs (interior-reg)) lip)
895 ;; Clear the number stack.
896 (trace-table-entry trace-table-fun-epilogue)
897 (let ((cur-nfp (current-nfp-tn vop)))
899 (inst addu nsp-tn cur-nfp
900 (bytes-needed-for-non-descriptor-stack-frame))))
901 ;; Clear the control stack, and restore the frame pointer.
905 (lisp-return return-pc lip :offset 2)
906 (trace-table-entry trace-table-normal)))
909 ;;; Do unknown-values return of a fixed number of values. The Values are
910 ;;; required to be set up in the standard passing locations. Nvals is the
911 ;;; number of values returned.
913 ;;; If returning a single value, then deallocate the current frame, restore
914 ;;; FP and jump to the single-value entry at Return-PC + 8.
916 ;;; If returning other than one value, then load the number of values returned,
917 ;;; NIL out unsupplied values registers, restore FP and return at Return-PC.
918 ;;; When there are stack values, we must initialize the argument pointer to
919 ;;; point to the beginning of the values block (which is the beginning of the
923 (:args (ocfp :scs (any-reg))
924 (return-pc :scs (descriptor-reg) :to (:eval 1))
928 (:temporary (:sc descriptor-reg :offset a0-offset :from (:eval 0)) a0)
929 (:temporary (:sc descriptor-reg :offset a1-offset :from (:eval 0)) a1)
930 (:temporary (:sc descriptor-reg :offset a2-offset :from (:eval 0)) a2)
931 (:temporary (:sc descriptor-reg :offset a3-offset :from (:eval 0)) a3)
932 (:temporary (:sc descriptor-reg :offset a4-offset :from (:eval 0)) a4)
933 (:temporary (:sc descriptor-reg :offset a5-offset :from (:eval 0)) a5)
934 (:temporary (:sc any-reg :offset nargs-offset) nargs)
935 (:temporary (:sc any-reg :offset ocfp-offset) val-ptr)
936 (:temporary (:scs (interior-reg)) lip)
939 ;; Clear the number stack.
940 (trace-table-entry trace-table-fun-epilogue)
941 (let ((cur-nfp (current-nfp-tn vop)))
943 (inst addu nsp-tn cur-nfp
944 (bytes-needed-for-non-descriptor-stack-frame))))
945 ;; Establish the values pointer and values count.
946 (move val-ptr cfp-tn)
947 (inst li nargs (fixnumize nvals))
948 ;; restore the frame pointer and clear as much of the control
949 ;; stack as possible.
951 (inst addu csp-tn val-ptr (* nvals n-word-bytes))
952 ;; pre-default any argument register that need it.
953 (when (< nvals register-arg-count)
954 (dolist (reg (subseq (list a0 a1 a2 a3 a4 a5) nvals))
957 (lisp-return return-pc lip)
958 (trace-table-entry trace-table-normal)))
960 ;;; Do unknown-values return of an arbitrary number of values (passed on the
961 ;;; stack.) We check for the common case of a single return value, and do that
962 ;;; inline using the normal single value return convention. Otherwise, we
963 ;;; branch off to code that calls an assembly-routine.
965 (define-vop (return-multiple)
966 (:args (ocfp-arg :scs (any-reg) :target ocfp)
967 (lra-arg :scs (descriptor-reg) :target lra)
968 (vals-arg :scs (any-reg) :target vals)
969 (nvals-arg :scs (any-reg) :target nvals))
971 (:temporary (:sc any-reg :offset nl1-offset :from (:argument 0)) ocfp)
972 (:temporary (:sc descriptor-reg :offset lra-offset :from (:argument 1)) lra)
973 (:temporary (:sc any-reg :offset nl0-offset :from (:argument 2)) vals)
974 (:temporary (:sc any-reg :offset nargs-offset :from (:argument 3)) nvals)
975 (:temporary (:sc descriptor-reg :offset a0-offset) a0)
976 (:temporary (:scs (interior-reg)) lip)
981 (trace-table-entry trace-table-fun-epilogue)
982 (let ((not-single (gen-label)))
983 ;; Clear the number stack.
984 (let ((cur-nfp (current-nfp-tn vop)))
986 (inst addu nsp-tn cur-nfp
987 (bytes-needed-for-non-descriptor-stack-frame))))
989 ;; Check for the single case.
990 (inst li a0 (fixnumize 1))
991 (inst bne nvals-arg a0 not-single)
992 (inst lw a0 vals-arg)
994 ;; Return with one value.
996 (move cfp-tn ocfp-arg)
997 (lisp-return lra-arg lip :offset 2)
999 ;; Nope, not the single case.
1000 (emit-label not-single)
1001 (move ocfp ocfp-arg)
1003 (move vals vals-arg)
1005 (inst j (make-fixup 'return-multiple :assembly-routine))
1006 (move nvals nvals-arg t))
1007 (trace-table-entry trace-table-normal)))
1014 ;;; We don't need to do anything special for regular functions.
1016 (define-vop (setup-environment)
1020 ;; Don't bother doing anything.
1023 ;;; Get the lexical environment from its passing location.
1025 (define-vop (setup-closure-environment)
1026 (:temporary (:sc descriptor-reg :offset lexenv-offset :target closure
1029 (:results (closure :scs (descriptor-reg)))
1034 (move closure lexenv)))
1036 ;;; Copy a more arg from the argument area to the end of the current frame.
1037 ;;; Fixed is the number of non-more arguments.
1039 (define-vop (copy-more-arg)
1040 (:temporary (:sc any-reg :offset nl0-offset) result)
1041 (:temporary (:sc any-reg :offset nl1-offset) count)
1042 (:temporary (:sc any-reg :offset nl2-offset) src)
1043 (:temporary (:sc any-reg :offset nl3-offset) dst)
1044 (:temporary (:sc descriptor-reg :offset l0-offset) temp)
1047 (let ((loop (gen-label))
1048 (do-regs (gen-label))
1050 (when (< fixed register-arg-count)
1051 ;; Save a pointer to the results so we can fill in register args.
1052 ;; We don't need this if there are more fixed args than reg args.
1053 (move result csp-tn))
1054 ;; Allocate the space on the stack.
1055 (cond ((zerop fixed)
1056 (inst beq nargs-tn done)
1057 (inst addu csp-tn csp-tn nargs-tn))
1059 (inst addu count nargs-tn (fixnumize (- fixed)))
1060 (inst blez count done)
1062 (inst addu csp-tn csp-tn count)))
1063 (when (< fixed register-arg-count)
1064 ;; We must stop when we run out of stack args, not when we run out of
1066 (inst addu count nargs-tn (fixnumize (- register-arg-count))))
1067 ;; Everything of interest in registers.
1068 (inst blez count do-regs)
1069 ;; Initialize dst to be end of stack.
1071 ;; Initialize src to be end of args.
1072 (inst addu src cfp-tn nargs-tn)
1075 ;; *--dst = *--src, --count
1076 (inst addu src src (- n-word-bytes))
1077 (inst addu count count (fixnumize -1))
1079 (inst addu dst dst (- n-word-bytes))
1080 (inst bgtz count loop)
1083 (emit-label do-regs)
1084 (when (< fixed register-arg-count)
1085 ;; Now we have to deposit any more args that showed up in registers.
1086 ;; We know there is at least one more arg, otherwise we would have
1087 ;; branched to done up at the top.
1088 (inst subu count nargs-tn (fixnumize (1+ fixed)))
1089 (do ((i fixed (1+ i)))
1090 ((>= i register-arg-count))
1091 ;; Is this the last one?
1092 (inst beq count done)
1093 ;; Store it relative to the pointer saved at the start.
1094 (storew (nth i register-arg-tns) result (- i fixed))
1096 (inst subu count (fixnumize 1))))
1097 (emit-label done))))
1100 ;;; More args are stored consequtively on the stack, starting immediately at
1101 ;;; the context pointer. The context pointer is not typed, so the lowtag is 0.
1103 (define-full-reffer more-arg * 0 0 (descriptor-reg any-reg) * %more-arg)
1106 ;;; Turn more arg (context, count) into a list.
1108 (define-vop (listify-rest-args)
1109 (:args (context-arg :target context :scs (descriptor-reg))
1110 (count-arg :target count :scs (any-reg)))
1111 (:arg-types * tagged-num)
1112 (:temporary (:scs (any-reg) :from (:argument 0)) context)
1113 (:temporary (:scs (any-reg) :from (:argument 1)) count)
1114 (:temporary (:scs (descriptor-reg) :from :eval) temp dst)
1115 (:temporary (:sc non-descriptor-reg :offset nl4-offset) pa-flag)
1116 (:results (result :scs (descriptor-reg)))
1117 (:translate %listify-rest-args)
1120 (let ((enter (gen-label))
1123 (move context context-arg)
1124 (move count count-arg)
1125 ;; Check to see if there are any arguments.
1126 (inst beq count zero-tn done)
1127 (move result null-tn t)
1129 ;; We need to do this atomically.
1130 (pseudo-atomic (pa-flag)
1131 ;; Allocate a cons (2 words) for each item.
1132 (inst or result alloc-tn list-pointer-lowtag)
1134 (inst sll temp count 1)
1136 (inst addu alloc-tn alloc-tn temp)
1138 ;; Store the current cons in the cdr of the previous cons.
1140 (inst addu dst dst (* 2 n-word-bytes))
1141 (storew dst dst -1 list-pointer-lowtag)
1145 (loadw temp context)
1146 (inst addu context context n-word-bytes)
1148 ;; Dec count, and if != zero, go back for more.
1149 (inst addu count count (fixnumize -1))
1150 (inst bne count zero-tn loop)
1152 ;; Store the value in the car (in delay slot)
1153 (storew temp dst 0 list-pointer-lowtag)
1155 ;; NIL out the last cons.
1156 (storew null-tn dst 1 list-pointer-lowtag))
1157 (emit-label done))))
1159 ;;; Return the location and size of the more arg glob created by Copy-More-Arg.
1160 ;;; Supplied is the total number of arguments supplied (originally passed in
1161 ;;; NARGS.) Fixed is the number of non-rest arguments.
1163 ;;; We must duplicate some of the work done by Copy-More-Arg, since at that
1164 ;;; time the environment is in a pretty brain-damaged state, preventing this
1165 ;;; info from being returned as values. What we do is compute
1166 ;;; supplied - fixed, and return a pointer that many words below the current
1169 (define-vop (more-arg-context)
1170 (:policy :fast-safe)
1171 (:translate sb!c::%more-arg-context)
1172 (:args (supplied :scs (any-reg)))
1173 (:arg-types tagged-num (:constant fixnum))
1175 (:results (context :scs (descriptor-reg))
1176 (count :scs (any-reg)))
1177 (:result-types t tagged-num)
1178 (:note "more-arg-context")
1180 (inst addu count supplied (fixnumize (- fixed)))
1181 (inst subu context csp-tn count)))
1184 ;;; Signal wrong argument count error if Nargs isn't = to Count.
1186 (define-vop (verify-arg-count)
1187 (:policy :fast-safe)
1188 (:translate sb!c::%verify-arg-count)
1189 (:args (nargs :scs (any-reg)))
1190 (:arg-types positive-fixnum (:constant t))
1191 (:temporary (:scs (any-reg) :type fixnum) temp)
1194 (:save-p :compute-only)
1197 (generate-error-code vop invalid-arg-count-error nargs)))
1198 (cond ((zerop count)
1199 (inst bne nargs zero-tn err-lab)
1202 (inst li temp (fixnumize count))
1203 (inst bne nargs temp err-lab)
1206 ;;; Various other error signalers.
1208 (macrolet ((frob (name error translate &rest args)
1209 `(define-vop (,name)
1211 `((:policy :fast-safe)
1212 (:translate ,translate)))
1213 (:args ,@(mapcar #'(lambda (arg)
1214 `(,arg :scs (any-reg descriptor-reg)))
1217 (:save-p :compute-only)
1219 (error-call vop ,error ,@args)))))
1220 (frob arg-count-error invalid-arg-count-error
1221 sb!c::%arg-count-error nargs)
1222 (frob type-check-error object-not-type-error sb!c::%type-check-error
1224 (frob layout-invalid-error layout-invalid-error sb!c::%layout-invalid-error
1226 (frob odd-key-args-error odd-key-args-error
1227 sb!c::%odd-key-args-error)
1228 (frob unknown-key-arg-error unknown-key-arg-error
1229 sb!c::%unknown-key-arg-error key)
1230 (frob nil-fun-returned-error nil-fun-returned-error nil fun))