;;;; the VM definition of function call for the PPC ;;;; This software is part of the SBCL system. See the README file for ;;;; more information. ;;;; ;;;; This software is derived from the CMU CL system, which was ;;;; written at Carnegie Mellon University and released into the ;;;; public domain. The software is in the public domain and is ;;;; provided with absolutely no warranty. See the COPYING and CREDITS ;;;; files for more information. (in-package "SB!VM") ;;;; Interfaces to IR2 conversion: ;;; Return a wired TN describing the N'th full call argument passing ;;; location. (defun standard-arg-location (n) (declare (type unsigned-byte n)) (if (< n register-arg-count) (make-wired-tn *backend-t-primitive-type* register-arg-scn (elt *register-arg-offsets* n)) (make-wired-tn *backend-t-primitive-type* control-stack-arg-scn n))) ;;; Make a passing location TN for a local call return PC. If ;;; standard is true, then use the standard (full call) location, ;;; otherwise use any legal location. Even in the non-standard case, ;;; this may be restricted by a desire to use a subroutine call ;;; instruction. (defun make-return-pc-passing-location (standard) (if standard (make-wired-tn *backend-t-primitive-type* register-arg-scn lra-offset) (make-restricted-tn *backend-t-primitive-type* register-arg-scn))) ;;; This is similar to MAKE-RETURN-PC-PASSING-LOCATION, but makes a ;;; location to pass OLD-FP in. This is (obviously) wired in the ;;; standard convention, but is totally unrestricted in non-standard ;;; conventions, since we can always fetch it off of the stack using ;;; the arg pointer. (defun make-old-fp-passing-location (standard) (if standard (make-wired-tn *fixnum-primitive-type* immediate-arg-scn ocfp-offset) (make-normal-tn *fixnum-primitive-type*))) ;;; Make the TNs used to hold OLD-FP and RETURN-PC within the current ;;; function. We treat these specially so that the debugger can find ;;; them at a known location. (defun make-old-fp-save-location (env) (specify-save-tn (physenv-debug-live-tn (make-normal-tn *fixnum-primitive-type*) env) (make-wired-tn *fixnum-primitive-type* control-stack-arg-scn ocfp-save-offset))) (defun make-return-pc-save-location (env) (specify-save-tn (physenv-debug-live-tn (make-normal-tn *backend-t-primitive-type*) env) (make-wired-tn *backend-t-primitive-type* control-stack-arg-scn lra-save-offset))) ;;; Make a TN for the standard argument count passing location. We ;;; only need to make the standard location, since a count is never ;;; passed when we are using non-standard conventions. (defun make-arg-count-location () (make-wired-tn *fixnum-primitive-type* immediate-arg-scn nargs-offset)) ;;; Make a TN to hold the number-stack frame pointer. This is ;;; allocated once per component, and is component-live. (defun make-nfp-tn () (component-live-tn (make-wired-tn *fixnum-primitive-type* immediate-arg-scn nfp-offset))) (defun make-stack-pointer-tn () (make-normal-tn *fixnum-primitive-type*)) (defun make-number-stack-pointer-tn () (make-normal-tn *fixnum-primitive-type*)) ;;; Return a list of TNs that can be used to represent an unknown-values ;;; continuation within a function. (defun make-unknown-values-locations () (list (make-stack-pointer-tn) (make-normal-tn *fixnum-primitive-type*))) ;;; This function is called by the ENTRY-ANALYZE phase, allowing ;;; VM-dependent initialization of the IR2-COMPONENT structure. We push ;;; placeholder entries in the Constants to leave room for additional ;;; noise in the code object header. (defun select-component-format (component) (declare (type component component)) (dotimes (i code-constants-offset) (vector-push-extend nil (ir2-component-constants (component-info component)))) (values)) ;;;; Frame hackery: ;;; this is the first function in this file that differs materially from ;;; ../alpha/call.lisp (defun bytes-needed-for-non-descriptor-stack-frame () (logandc2 (+ +stack-alignment-bytes+ number-stack-displacement (* (sb-allocated-size 'non-descriptor-stack) n-word-bytes)) +stack-alignment-bytes+)) ;;; Used for setting up the Old-FP in local call. (define-vop (current-fp) (:results (val :scs (any-reg))) (:generator 1 (move val cfp-tn))) ;;; Used for computing the caller's NFP for use in known-values return. Only ;;; works assuming there is no variable size stuff on the nstack. (define-vop (compute-old-nfp) (:results (val :scs (any-reg))) (:vop-var vop) (:generator 1 (let ((nfp (current-nfp-tn vop))) (when nfp (inst addi val nfp (bytes-needed-for-non-descriptor-stack-frame)))))) ;;; Accessing a slot from an earlier stack frame is definite hackery. (define-vop (ancestor-frame-ref) (:args (frame-pointer :scs (descriptor-reg)) (variable-home-tn :load-if nil)) (:results (value :scs (descriptor-reg any-reg))) (:policy :fast-safe) (:generator 4 (aver (sc-is variable-home-tn control-stack)) (loadw value frame-pointer (tn-offset variable-home-tn)))) (define-vop (ancestor-frame-set) (:args (frame-pointer :scs (descriptor-reg)) (value :scs (descriptor-reg any-reg))) (:results (variable-home-tn :load-if nil)) (:policy :fast-safe) (:generator 4 (aver (sc-is variable-home-tn control-stack)) (storew value frame-pointer (tn-offset variable-home-tn)))) (define-vop (xep-allocate-frame) (:info start-lab copy-more-arg-follows) (:ignore copy-more-arg-follows) (:vop-var vop) (:temporary (:scs (non-descriptor-reg)) temp) (:generator 1 ;; Make sure the function is aligned, and drop a label pointing to this ;; function header. (emit-alignment n-lowtag-bits) (trace-table-entry trace-table-fun-prologue) (emit-label start-lab) ;; Allocate function header. (inst simple-fun-header-word) (dotimes (i (1- simple-fun-code-offset)) (inst word 0)) (let* ((entry-point (gen-label))) (emit-label entry-point) (inst compute-code-from-lip code-tn lip-tn entry-point temp)) ;; FIXME alpha port has a ### note here saying we should "save it ;; on the stack" so that GC sees it. No idea what "it" is -dan 20020110 ;; Build our stack frames. (inst addi csp-tn cfp-tn (* n-word-bytes (sb-allocated-size 'control-stack))) (let ((nfp-tn (current-nfp-tn vop))) (when nfp-tn (let* ((nbytes (bytes-needed-for-non-descriptor-stack-frame))) (when (> nbytes number-stack-displacement) (inst stwu nsp-tn nsp-tn (- nbytes)) (inst addi nfp-tn nsp-tn number-stack-displacement))))) (trace-table-entry trace-table-normal))) (define-vop (allocate-frame) (:results (res :scs (any-reg)) (nfp :scs (any-reg))) (:info callee) (:generator 2 (trace-table-entry trace-table-fun-prologue) (move res csp-tn) (inst addi csp-tn csp-tn (* n-word-bytes (sb-allocated-size 'control-stack))) (when (ir2-physenv-number-stack-p callee) (let* ((nbytes (bytes-needed-for-non-descriptor-stack-frame))) (when (> nbytes number-stack-displacement) (inst stwu nsp-tn nsp-tn (- (bytes-needed-for-non-descriptor-stack-frame))) (inst addi nfp nsp-tn number-stack-displacement)))) (trace-table-entry trace-table-normal))) ;;; Allocate a partial frame for passing stack arguments in a full call. Nargs ;;; is the number of arguments passed. If no stack arguments are passed, then ;;; we don't have to do anything. (define-vop (allocate-full-call-frame) (:info nargs) (:results (res :scs (any-reg))) (:generator 2 (when (> nargs register-arg-count) (move res csp-tn) (inst addi csp-tn csp-tn (* nargs n-word-bytes))))) ;;; Emit code needed at the return-point from an unknown-values call ;;; for a fixed number of values. Values is the head of the TN-REF ;;; list for the locations that the values are to be received into. ;;; Nvals is the number of values that are to be received (should ;;; equal the length of Values). ;;; ;;; MOVE-TEMP is a DESCRIPTOR-REG TN used as a temporary. ;;; ;;; This code exploits the fact that in the unknown-values convention, ;;; a single value return returns at the return PC + 8, whereas a ;;; return of other than one value returns directly at the return PC. ;;; ;;; If 0 or 1 values are expected, then we just emit an instruction to ;;; reset the SP (which will only be executed when other than 1 value ;;; is returned.) ;;; ;;; In the general case, we have to do three things: ;;; -- Default unsupplied register values. This need only be done when a ;;; single value is returned, since register values are defaulted by the ;;; callee in the non-single case. ;;; -- Default unsupplied stack values. This needs to be done whenever there ;;; are stack values. ;;; -- Reset SP. This must be done whenever other than 1 value is returned, ;;; regardless of the number of values desired. ;;; ;;; The general-case code looks like this: #| b regs-defaulted ; Skip if MVs nop move a1 null-tn ; Default register values ... loadi nargs 1 ; Force defaulting of stack values move old-fp csp ; Set up args for SP resetting regs-defaulted subcc temp nargs register-arg-count b :lt default-value-7 ; jump to default code loadw move-temp ocfp-tn 6 ; Move value to correct location. subcc temp 1 store-stack-tn val4-tn move-temp b :lt default-value-8 loadw move-temp ocfp-tn 7 subcc temp 1 store-stack-tn val5-tn move-temp ... defaulting-done move csp ocfp ; Reset SP. default-value-7 store-stack-tn val4-tn null-tn ; Nil out 7'th value. (first on stack) default-value-8 store-stack-tn val5-tn null-tn ; Nil out 8'th value. ... br defaulting-done nop |# ;;; differences from alpha: (1) alpha tests for lra-label before ;;; compute-code-from-lra and skips if nil. (2) loop termination is ;;; different when clearing stack defaults (defun default-unknown-values (vop values nvals move-temp temp lra-label) (declare (type (or tn-ref null) values) (type unsigned-byte nvals) (type tn move-temp temp)) (if (<= nvals 1) (progn (sb!assem:without-scheduling () (note-this-location vop :single-value-return) (move csp-tn ocfp-tn) (inst nop)) (inst compute-code-from-lra code-tn lra-tn lra-label temp)) (let ((regs-defaulted (gen-label)) (defaulting-done (gen-label)) (default-stack-vals (gen-label))) ;; Branch off to the MV case. (sb!assem:without-scheduling () (note-this-location vop :unknown-return) (if (> nvals register-arg-count) (inst addic. temp nargs-tn (- (fixnumize register-arg-count))) (move csp-tn ocfp-tn)) (inst b regs-defaulted)) ;; Do the single value case. (do ((i 1 (1+ i)) (val (tn-ref-across values) (tn-ref-across val))) ((= i (min nvals register-arg-count))) (move (tn-ref-tn val) null-tn)) (when (> nvals register-arg-count) (move ocfp-tn csp-tn) (inst b default-stack-vals)) (emit-label regs-defaulted) (when (> nvals register-arg-count) (collect ((defaults)) (do ((i register-arg-count (1+ i)) (val (do ((i 0 (1+ i)) (val values (tn-ref-across val))) ((= i register-arg-count) val)) (tn-ref-across val))) ((null val)) (let ((default-lab (gen-label)) (tn (tn-ref-tn val))) (defaults (cons default-lab tn)) (inst lwz move-temp ocfp-tn (* i n-word-bytes)) (inst ble default-lab) (inst addic. temp temp (- (fixnumize 1))) (store-stack-tn tn move-temp))) (emit-label defaulting-done) (move csp-tn ocfp-tn) (let ((defaults (defaults))) (when defaults (assemble (*elsewhere*) (emit-label default-stack-vals) (trace-table-entry trace-table-fun-prologue) (do ((remaining defaults (cdr remaining))) ((null remaining)) (let ((def (car remaining))) (emit-label (car def)) (store-stack-tn (cdr def) null-tn))) (inst b defaulting-done) (trace-table-entry trace-table-normal)))))) (inst compute-code-from-lra code-tn lra-tn lra-label temp))) (values)) ;;;; Unknown values receiving: ;;; Emit code needed at the return point for an unknown-values call for an ;;; arbitrary number of values. ;;; ;;; We do the single and non-single cases with no shared code: there doesn't ;;; seem to be any potential overlap, and receiving a single value is more ;;; important efficiency-wise. ;;; ;;; When there is a single value, we just push it on the stack, returning ;;; the old SP and 1. ;;; ;;; When there is a variable number of values, we move all of the argument ;;; registers onto the stack, and return Args and Nargs. ;;; ;;; Args and Nargs are TNs wired to the named locations. We must ;;; explicitly allocate these TNs, since their lifetimes overlap with the ;;; results Start and Count (also, it's nice to be able to target them). (defun receive-unknown-values (args nargs start count lra-label temp) (declare (type tn args nargs start count temp)) (let ((variable-values (gen-label)) (done (gen-label))) (sb!assem:without-scheduling () (inst b variable-values) (inst nop)) (inst compute-code-from-lra code-tn lra-tn lra-label temp) (inst addi csp-tn csp-tn 4) (storew (first *register-arg-tns*) csp-tn -1) (inst subi start csp-tn 4) (inst li count (fixnumize 1)) (emit-label done) (assemble (*elsewhere*) (trace-table-entry trace-table-fun-prologue) (emit-label variable-values) (inst compute-code-from-lra code-tn lra-tn lra-label temp) (do ((arg *register-arg-tns* (rest arg)) (i 0 (1+ i))) ((null arg)) (storew (first arg) args i)) (move start args) (move count nargs) (inst b done) (trace-table-entry trace-table-normal))) (values)) ;;; VOP that can be inherited by unknown values receivers. The main ;;; thing this handles is allocation of the result temporaries. (define-vop (unknown-values-receiver) (:results (start :scs (any-reg)) (count :scs (any-reg))) (:temporary (:sc descriptor-reg :offset ocfp-offset :from :eval :to (:result 0)) values-start) (:temporary (:sc any-reg :offset nargs-offset :from :eval :to (:result 1)) nvals) (:temporary (:scs (non-descriptor-reg)) temp)) ;;; This hook in the codegen pass lets us insert code before fall-thru entry ;;; points, local-call entry points, and tail-call entry points. The default ;;; does nothing. (defun emit-block-header (start-label trampoline-label fall-thru-p alignp) (declare (ignore fall-thru-p alignp)) (when trampoline-label (emit-label trampoline-label)) (emit-label start-label)) ;;;; Local call with unknown values convention return: ;;; Non-TR local call for a fixed number of values passed according to the ;;; unknown values convention. ;;; ;;; Args are the argument passing locations, which are specified only to ;;; terminate their lifetimes in the caller. ;;; ;;; Values are the return value locations (wired to the standard passing ;;; locations). ;;; ;;; Save is the save info, which we can ignore since saving has been done. ;;; Return-PC is the TN that the return PC should be passed in. ;;; Target is a continuation pointing to the start of the called function. ;;; Nvals is the number of values received. ;;; ;;; Note: we can't use normal load-tn allocation for the fixed args, since all ;;; registers may be tied up by the more operand. Instead, we use ;;; MAYBE-LOAD-STACK-TN. (define-vop (call-local) (:args (fp) (nfp) (args :more t)) (:results (values :more t)) (:save-p t) (:move-args :local-call) (:info arg-locs callee target nvals) (:vop-var vop) (:temporary (:scs (descriptor-reg) :from (:eval 0)) move-temp) (:temporary (:scs (non-descriptor-reg)) temp) (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save) (:temporary (:sc any-reg :offset ocfp-offset :from (:eval 0)) ocfp) (:ignore arg-locs args ocfp) (:generator 5 (trace-table-entry trace-table-call-site) (let ((label (gen-label)) (cur-nfp (current-nfp-tn vop))) (when cur-nfp (store-stack-tn nfp-save cur-nfp)) (let ((callee-nfp (callee-nfp-tn callee))) (when callee-nfp (maybe-load-stack-tn callee-nfp nfp))) (maybe-load-stack-tn cfp-tn fp) (inst compute-lra-from-code (callee-return-pc-tn callee) code-tn label temp) (note-this-location vop :call-site) (inst b target) (emit-return-pc label) (default-unknown-values vop values nvals move-temp temp label) ;; alpha uses (maybe-load-stack-nfp-tn cur-nfp nfp-save temp) ;; instead of the clause below (when cur-nfp (load-stack-tn cur-nfp nfp-save))) (trace-table-entry trace-table-normal))) ;;; Non-TR local call for a variable number of return values passed according ;;; to the unknown values convention. The results are the start of the values ;;; glob and the number of values received. ;;; ;;; Note: we can't use normal load-tn allocation for the fixed args, since all ;;; registers may be tied up by the more operand. Instead, we use ;;; MAYBE-LOAD-STACK-TN. (define-vop (multiple-call-local unknown-values-receiver) (:args (fp) (nfp) (args :more t)) (:save-p t) (:move-args :local-call) (:info save callee target) (:ignore args save) (:vop-var vop) (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save) (:temporary (:scs (non-descriptor-reg)) temp) (:generator 20 (trace-table-entry trace-table-call-site) (let ((label (gen-label)) (cur-nfp (current-nfp-tn vop))) (when cur-nfp (store-stack-tn nfp-save cur-nfp)) (let ((callee-nfp (callee-nfp-tn callee))) ;; alpha doesn't test this before the maybe-load (when callee-nfp (maybe-load-stack-tn callee-nfp nfp))) (maybe-load-stack-tn cfp-tn fp) (inst compute-lra-from-code (callee-return-pc-tn callee) code-tn label temp) (note-this-location vop :call-site) (inst b target) (emit-return-pc label) (note-this-location vop :unknown-return) (receive-unknown-values values-start nvals start count label temp) (when cur-nfp (load-stack-tn cur-nfp nfp-save))) (trace-table-entry trace-table-normal))) ;;;; Local call with known values return: ;;; Non-TR local call with known return locations. Known-value return works ;;; just like argument passing in local call. ;;; ;;; Note: we can't use normal load-tn allocation for the fixed args, since all ;;; registers may be tied up by the more operand. Instead, we use ;;; MAYBE-LOAD-STACK-TN. (define-vop (known-call-local) (:args (fp) (nfp) (args :more t)) (:results (res :more t)) (:move-args :local-call) (:save-p t) (:info save callee target) (:ignore args res save) (:vop-var vop) (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save) (:temporary (:scs (non-descriptor-reg)) temp) (:generator 5 (trace-table-entry trace-table-call-site) (let ((label (gen-label)) (cur-nfp (current-nfp-tn vop))) (when cur-nfp (store-stack-tn nfp-save cur-nfp)) (let ((callee-nfp (callee-nfp-tn callee))) (when callee-nfp (maybe-load-stack-tn callee-nfp nfp))) (maybe-load-stack-tn cfp-tn fp) (inst compute-lra-from-code (callee-return-pc-tn callee) code-tn label temp) (note-this-location vop :call-site) (inst b target) (emit-return-pc label) (note-this-location vop :known-return) (when cur-nfp (load-stack-tn cur-nfp nfp-save))) (trace-table-entry trace-table-normal))) ;;; Return from known values call. We receive the return locations as ;;; arguments to terminate their lifetimes in the returning function. We ;;; restore FP and CSP and jump to the Return-PC. ;;; ;;; Note: we can't use normal load-tn allocation for the fixed args, since all ;;; registers may be tied up by the more operand. Instead, we use ;;; MAYBE-LOAD-STACK-TN. (define-vop (known-return) (:args (old-fp :target old-fp-temp) (return-pc :target return-pc-temp) (vals :more t)) (:temporary (:sc any-reg :from (:argument 0)) old-fp-temp) (:temporary (:sc descriptor-reg :from (:argument 1)) return-pc-temp) (:move-args :known-return) (:info val-locs) (:ignore val-locs vals) (:vop-var vop) (:generator 6 (trace-table-entry trace-table-fun-epilogue) (maybe-load-stack-tn old-fp-temp old-fp) (maybe-load-stack-tn return-pc-temp return-pc) (move csp-tn cfp-tn) (let ((cur-nfp (current-nfp-tn vop))) (when cur-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) (move cfp-tn old-fp-temp) (inst j return-pc-temp (- n-word-bytes other-pointer-lowtag)) (trace-table-entry trace-table-normal))) ;;;; Full call: ;;; ;;; There is something of a cross-product effect with full calls. Different ;;; versions are used depending on whether we know the number of arguments or ;;; the name of the called function, and whether we want fixed values, unknown ;;; values, or a tail call. ;;; ;;; In full call, the arguments are passed creating a partial frame on the ;;; stack top and storing stack arguments into that frame. On entry to the ;;; callee, this partial frame is pointed to by FP. If there are no stack ;;; arguments, we don't bother allocating a partial frame, and instead set FP ;;; to SP just before the call. ;;; This macro helps in the definition of full call VOPs by avoiding code ;;; replication in defining the cross-product VOPs. ;;; ;;; NAME is the name of the VOP to define. ;;; ;;; NAMED is true if the first argument is a symbol whose global function ;;; definition is to be called. ;;; ;;; RETURN is either :FIXED, :UNKNOWN or :TAIL: ;;; -- If :FIXED, then the call is for a fixed number of values, returned in ;;; the standard passing locations (passed as result operands). ;;; -- If :UNKNOWN, then the result values are pushed on the stack, and the ;;; result values are specified by the Start and Count as in the ;;; unknown-values continuation representation. ;;; -- If :TAIL, then do a tail-recursive call. No values are returned. ;;; The Old-Fp and Return-PC are passed as the second and third arguments. ;;; ;;; In non-tail calls, the pointer to the stack arguments is passed as the last ;;; fixed argument. If VARIABLE is false, then the passing locations are ;;; passed as a more arg. VARIABLE is true if there are a variable number of ;;; arguments passed on the stack. VARIABLE cannot be specified with :TAIL ;;; return. TR variable argument call is implemented separately. ;;; ;;; In tail call with fixed arguments, the passing locations are passed as a ;;; more arg, but there is no new-FP, since the arguments have been set up in ;;; the current frame. (defmacro define-full-call (name named return variable) (aver (not (and variable (eq return :tail)))) `(define-vop (,name ,@(when (eq return :unknown) '(unknown-values-receiver))) (:args ,@(unless (eq return :tail) '((new-fp :scs (any-reg) :to :eval))) ,(if named '(name :target name-pass) '(arg-fun :target lexenv)) ,@(when (eq return :tail) '((old-fp :target old-fp-pass) (return-pc :target return-pc-pass))) ,@(unless variable '((args :more t :scs (descriptor-reg))))) ,@(when (eq return :fixed) '((:results (values :more t)))) (:save-p ,(if (eq return :tail) :compute-only t)) ,@(unless (or (eq return :tail) variable) '((:move-args :full-call))) (:vop-var vop) (:info ,@(unless (or variable (eq return :tail)) '(arg-locs)) ,@(unless variable '(nargs)) ,@(when (eq return :fixed) '(nvals)) step-instrumenting) (:ignore ,@(unless (or variable (eq return :tail)) '(arg-locs)) ,@(unless variable '(args))) (:temporary (:sc descriptor-reg :offset ocfp-offset :from (:argument 1) ,@(unless (eq return :fixed) '(:to :eval))) old-fp-pass) (:temporary (:sc descriptor-reg :offset lra-offset :from (:argument ,(if (eq return :tail) 2 1)) :to (:result 0)) return-pc-pass) ,(if named `(:temporary (:sc descriptor-reg :offset fdefn-offset ; -dan :from (:argument ,(if (eq return :tail) 0 1)) :to :eval) name-pass) `(:temporary (:sc descriptor-reg :offset lexenv-offset :from (:argument ,(if (eq return :tail) 0 1)) :to :eval) lexenv)) (:temporary (:scs (descriptor-reg) :from (:argument 0) :to :eval) function) (:temporary (:sc any-reg :offset nargs-offset :to :eval) nargs-pass) ,@(when variable (mapcar #'(lambda (name offset) `(:temporary (:sc descriptor-reg :offset ,offset :to :eval) ,name)) register-arg-names *register-arg-offsets*)) ,@(when (eq return :fixed) '((:temporary (:scs (descriptor-reg) :from :eval) move-temp))) (:temporary (:scs (descriptor-reg) :to :eval) stepping) ,@(unless (eq return :tail) '((:temporary (:scs (non-descriptor-reg)) temp) (:temporary (:sc control-stack :offset nfp-save-offset) nfp-save))) (:temporary (:sc interior-reg :offset lip-offset) entry-point) (:generator ,(+ (if named 5 0) (if variable 19 1) (if (eq return :tail) 0 10) 15 (if (eq return :unknown) 25 0)) (trace-table-entry trace-table-call-site) (let* ((cur-nfp (current-nfp-tn vop)) ,@(unless (eq return :tail) '((lra-label (gen-label)))) (step-done-label (gen-label)) (filler (remove nil (list :load-nargs ,@(if (eq return :tail) '((unless (location= old-fp old-fp-pass) :load-old-fp) (unless (location= return-pc return-pc-pass) :load-return-pc) (when cur-nfp :frob-nfp)) '(:comp-lra (when cur-nfp :frob-nfp) :save-fp :load-fp)))))) (flet ((do-next-filler () (let* ((next (pop filler)) (what (if (consp next) (car next) next))) (ecase what (:load-nargs ,@(if variable `((inst sub nargs-pass csp-tn new-fp) ,@(let ((index -1)) (mapcar #'(lambda (name) `(loadw ,name new-fp ,(incf index))) register-arg-names))) '((inst lr nargs-pass (fixnumize nargs))))) ,@(if (eq return :tail) '((:load-old-fp (sc-case old-fp (any-reg (inst mr old-fp-pass old-fp)) (control-stack (loadw old-fp-pass cfp-tn (tn-offset old-fp))))) (:load-return-pc (sc-case return-pc (descriptor-reg (inst mr return-pc-pass return-pc)) (control-stack (loadw return-pc-pass cfp-tn (tn-offset return-pc))))) (:frob-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) `((:comp-lra (inst compute-lra-from-code return-pc-pass code-tn lra-label temp)) (:frob-nfp (store-stack-tn nfp-save cur-nfp)) (:save-fp (inst mr old-fp-pass cfp-tn)) (:load-fp ,(if variable '(move cfp-tn new-fp) '(if (> nargs register-arg-count) (move cfp-tn new-fp) (move cfp-tn csp-tn)))))) ((nil))))) (insert-step-instrumenting (callable-tn) ;; Conditionally insert a conditional trap: (when step-instrumenting ;; Get the symbol-value of SB!IMPL::*STEPPING* #!-sb-thread (load-symbol-value stepping sb!impl::*stepping*) #!+sb-thread (loadw stepping thread-base-tn thread-stepping-slot) (inst cmpw stepping null-tn) ;; If it's not null, trap. (inst beq step-done-label) ;; CONTEXT-PC will be pointing here when the ;; interrupt is handled, not after the UNIMP. (note-this-location vop :step-before-vop) ;; Construct a trap code with the low bits from ;; SINGLE-STEP-AROUND-TRAP and the high bits from ;; the register number of CALLABLE-TN. (inst unimp (logior single-step-around-trap (ash (reg-tn-encoding callable-tn) 5))) (emit-label step-done-label)))) ,@(if named `((sc-case name (descriptor-reg (move name-pass name)) (control-stack (loadw name-pass cfp-tn (tn-offset name)) (do-next-filler)) (constant (loadw name-pass code-tn (tn-offset name) other-pointer-lowtag) (do-next-filler))) ;; The step instrumenting must be done after ;; FUNCTION is loaded, but before ENTRY-POINT is ;; calculated. (insert-step-instrumenting name-pass) ;; The raw-addr (ENTRY-POINT) will be one of: ;; closure_tramp, undefined_tramp, or somewhere ;; within a simple-fun object. If the latter, then ;; it is essential (due to it being an interior ;; pointer) that the function itself be in a ;; register before the raw-addr is loaded. (sb!assem:without-scheduling () (loadw function name-pass fdefn-fun-slot other-pointer-lowtag) (loadw entry-point name-pass fdefn-raw-addr-slot other-pointer-lowtag)) (do-next-filler)) `((sc-case arg-fun (descriptor-reg (move lexenv arg-fun)) (control-stack (loadw lexenv cfp-tn (tn-offset arg-fun)) (do-next-filler)) (constant (loadw lexenv code-tn (tn-offset arg-fun) other-pointer-lowtag) (do-next-filler))) (loadw function lexenv closure-fun-slot fun-pointer-lowtag) (do-next-filler) ;; The step instrumenting must be done before ;; after FUNCTION is loaded, but before ENTRY-POINT ;; is calculated. (insert-step-instrumenting function) (inst addi entry-point function (- (ash simple-fun-code-offset word-shift) fun-pointer-lowtag)) )) (loop (if filler (do-next-filler) (return))) (note-this-location vop :call-site) (inst mtctr entry-point) ;; this following line is questionable. or else the alpha ;; code (which doesn't do it) is questionable ;; (inst mr code-tn function) (inst bctr)) ,@(ecase return (:fixed '((emit-return-pc lra-label) (default-unknown-values vop values nvals move-temp temp lra-label) (when cur-nfp (load-stack-tn cur-nfp nfp-save)))) (:unknown '((emit-return-pc lra-label) (note-this-location vop :unknown-return) (receive-unknown-values values-start nvals start count lra-label temp) (when cur-nfp (load-stack-tn cur-nfp nfp-save)))) (:tail))) (trace-table-entry trace-table-normal)))) (define-full-call call nil :fixed nil) (define-full-call call-named t :fixed nil) (define-full-call multiple-call nil :unknown nil) (define-full-call multiple-call-named t :unknown nil) (define-full-call tail-call nil :tail nil) (define-full-call tail-call-named t :tail nil) (define-full-call call-variable nil :fixed t) (define-full-call multiple-call-variable nil :unknown t) ;;; Defined separately, since needs special code that BLT's the ;;; arguments down. (define-vop (tail-call-variable) (:args (args-arg :scs (any-reg) :target args) (function-arg :scs (descriptor-reg) :target lexenv) (old-fp-arg :scs (any-reg) :target old-fp) (lra-arg :scs (descriptor-reg) :target lra)) (:temporary (:sc any-reg :offset nl0-offset :from (:argument 0)) args) (:temporary (:sc any-reg :offset lexenv-offset :from (:argument 1)) lexenv) (:temporary (:sc any-reg :offset ocfp-offset :from (:argument 2)) old-fp) (:temporary (:sc any-reg :offset lra-offset :from (:argument 3)) lra) (:temporary (:sc any-reg) temp) (:vop-var vop) (:generator 75 ;; Move these into the passing locations if they are not already there. (move args args-arg) (move lexenv function-arg) (move old-fp old-fp-arg) (move lra lra-arg) ;; Clear the number stack if anything is there. (let ((cur-nfp (current-nfp-tn vop))) (when cur-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) (inst lr temp (make-fixup 'tail-call-variable :assembly-routine)) (inst mtlr temp) (inst blr))) ;;;; Unknown values return: ;;; Return a single value using the unknown-values convention. (define-vop (return-single) (:args (old-fp :scs (any-reg) :to :eval) (return-pc :scs (descriptor-reg) :target lra) (value)) (:ignore value) (:temporary (:sc descriptor-reg :offset lra-offset :from (:argument 1)) lra) (:temporary (:scs (interior-reg)) lip) (:vop-var vop) (:generator 6 (trace-table-entry trace-table-fun-epilogue) (move lra return-pc) ;; Clear the number stack. (let ((cur-nfp (current-nfp-tn vop))) (when cur-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) ;; Clear the control stack, and restore the frame pointer. (move csp-tn cfp-tn) (move cfp-tn old-fp) ;; Out of here. (lisp-return lra lip :offset 2) (trace-table-entry trace-table-normal))) ;;; Do unknown-values return of a fixed number of values. The Values are ;;; required to be set up in the standard passing locations. Nvals is the ;;; number of values returned. ;;; ;;; If returning a single value, then deallocate the current frame, restore ;;; FP and jump to the single-value entry at Return-PC + 8. ;;; ;;; If returning other than one value, then load the number of values returned, ;;; NIL out unsupplied values registers, restore FP and return at Return-PC. ;;; When there are stack values, we must initialize the argument pointer to ;;; point to the beginning of the values block (which is the beginning of the ;;; current frame.) (define-vop (return) (:args (old-fp :scs (any-reg)) (return-pc :scs (descriptor-reg) :to (:eval 1) :target lra) (values :more t)) (:ignore values) (:info nvals) (:temporary (:sc descriptor-reg :offset a0-offset :from (:eval 0)) a0) (:temporary (:sc descriptor-reg :offset a1-offset :from (:eval 0)) a1) (:temporary (:sc descriptor-reg :offset a2-offset :from (:eval 0)) a2) (:temporary (:sc descriptor-reg :offset a3-offset :from (:eval 0)) a3) (:temporary (:sc descriptor-reg :offset lra-offset :from (:eval 1)) lra) (:temporary (:sc any-reg :offset nargs-offset) nargs) (:temporary (:sc any-reg :offset ocfp-offset) val-ptr) (:temporary (:scs (interior-reg)) lip) (:vop-var vop) (:generator 6 (trace-table-entry trace-table-fun-epilogue) (move lra return-pc) ;; Clear the number stack. (let ((cur-nfp (current-nfp-tn vop))) (when cur-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) (cond ((= nvals 1) ;; Clear the control stack, and restore the frame pointer. (move csp-tn cfp-tn) (move cfp-tn old-fp) ;; Out of here. (lisp-return lra lip :offset 2)) (t ;; Establish the values pointer and values count. (move val-ptr cfp-tn) (inst lr nargs (fixnumize nvals)) ;; restore the frame pointer and clear as much of the control ;; stack as possible. (move cfp-tn old-fp) (inst addi csp-tn val-ptr (* nvals n-word-bytes)) ;; pre-default any argument register that need it. (when (< nvals register-arg-count) (dolist (reg (subseq (list a0 a1 a2 a3) nvals)) (move reg null-tn))) ;; And away we go. (lisp-return lra lip))) (trace-table-entry trace-table-normal))) ;;; Do unknown-values return of an arbitrary number of values (passed ;;; on the stack.) We check for the common case of a single return ;;; value, and do that inline using the normal single value return ;;; convention. Otherwise, we branch off to code that calls an ;;; assembly-routine. (define-vop (return-multiple) (:args (old-fp-arg :scs (any-reg) :to (:eval 1)) (lra-arg :scs (descriptor-reg) :to (:eval 1)) (vals-arg :scs (any-reg) :target vals) (nvals-arg :scs (any-reg) :target nvals)) (:temporary (:sc any-reg :offset nl1-offset :from (:argument 0)) old-fp) (:temporary (:sc descriptor-reg :offset lra-offset :from (:argument 1)) lra) (:temporary (:sc any-reg :offset nl0-offset :from (:argument 2)) vals) (:temporary (:sc any-reg :offset nargs-offset :from (:argument 3)) nvals) (:temporary (:sc descriptor-reg :offset a0-offset) a0) (:temporary (:scs (interior-reg)) lip) (:temporary (:sc any-reg) temp) (:vop-var vop) (:generator 13 (trace-table-entry trace-table-fun-epilogue) (move lra lra-arg) (let ((not-single (gen-label))) ;; Clear the number stack. (let ((cur-nfp (current-nfp-tn vop))) (when cur-nfp (inst addi nsp-tn cur-nfp (- (bytes-needed-for-non-descriptor-stack-frame) number-stack-displacement)))) ;; Check for the single case. (inst cmpwi nvals-arg (fixnumize 1)) (inst lwz a0 vals-arg 0) (inst bne not-single) ;; Return with one value. (move csp-tn cfp-tn) (move cfp-tn old-fp-arg) (lisp-return lra-arg lip :offset 2) ;; Nope, not the single case. (emit-label not-single) (move old-fp old-fp-arg) (move vals vals-arg) (move nvals nvals-arg) (inst lr temp (make-fixup 'return-multiple :assembly-routine)) (inst mtlr temp) (inst blr)) (trace-table-entry trace-table-normal))) ;;;; XEP hackery: ;;; We don't need to do anything special for regular functions. (define-vop (setup-environment) (:info label) (:ignore label) (:generator 0 ;; Don't bother doing anything. )) ;;; Get the lexical environment from its passing location. (define-vop (setup-closure-environment) (:temporary (:sc descriptor-reg :offset lexenv-offset :target closure :to (:result 0)) lexenv) (:results (closure :scs (descriptor-reg))) (:info label) (:ignore label) (:generator 6 ;; Get result. (move closure lexenv))) ;;; Copy a more arg from the argument area to the end of the current frame. ;;; Fixed is the number of non-more arguments. (define-vop (copy-more-arg) (:temporary (:sc any-reg :offset nl0-offset) result) (:temporary (:sc any-reg :offset nl1-offset) count) (:temporary (:sc any-reg :offset nl2-offset) src) (:temporary (:sc any-reg :offset nl3-offset) dst) (:temporary (:sc descriptor-reg :offset l0-offset) temp) (:info fixed) (:generator 20 (let ((loop (gen-label)) (do-regs (gen-label)) (done (gen-label))) (when (< fixed register-arg-count) ;; Save a pointer to the results so we can fill in register args. ;; We don't need this if there are more fixed args than reg args. (move result csp-tn)) ;; Allocate the space on the stack. (cond ((zerop fixed) (inst cmpwi nargs-tn 0) (inst add csp-tn csp-tn nargs-tn) (inst beq done)) (t (inst addic. count nargs-tn (- (fixnumize fixed))) (inst ble done) (inst add csp-tn csp-tn count))) (when (< fixed register-arg-count) ;; We must stop when we run out of stack args, not when we run out of ;; more args. (inst addic. count nargs-tn (- (fixnumize register-arg-count))) ;; Everything of interest is in registers. (inst ble do-regs)) ;; Initialize dst to be end of stack. (move dst csp-tn) ;; Initialize src to be end of args. (inst add src cfp-tn nargs-tn) (emit-label loop) ;; *--dst = *--src, --count (inst lwzu temp src (- n-word-bytes)) (inst addic. count count (- (fixnumize 1))) (inst stwu temp dst (- n-word-bytes)) (inst bgt loop) (emit-label do-regs) (when (< fixed register-arg-count) ;; Now we have to deposit any more args that showed up in registers. (inst subic. count nargs-tn (fixnumize fixed)) (do ((i fixed (1+ i))) ((>= i register-arg-count)) ;; Don't deposit any more than there are. (inst beq done) (inst subic. count count (fixnumize 1)) ;; Store it relative to the pointer saved at the start. (storew (nth i *register-arg-tns*) result (- i fixed)))) (emit-label done)))) ;;; More args are stored consecutively on the stack, starting ;;; immediately at the context pointer. The context pointer is not ;;; typed, so the lowtag is 0. (define-vop (more-arg word-index-ref) (:variant 0 0) (:translate %more-arg)) ;;; Turn more arg (context, count) into a list. (define-vop (listify-rest-args) (:args (context-arg :target context :scs (descriptor-reg)) (count-arg :target count :scs (any-reg))) (:arg-types * tagged-num) (:temporary (:scs (any-reg) :from (:argument 0)) context) (:temporary (:scs (any-reg) :from (:argument 1)) count) (:temporary (:scs (descriptor-reg) :from :eval) temp) (:temporary (:scs (non-descriptor-reg) :from :eval) dst) (:temporary (:sc non-descriptor-reg :offset nl3-offset) pa-flag) (:results (result :scs (descriptor-reg))) (:translate %listify-rest-args) (:policy :safe) (:node-var node) (:generator 20 (let* ((enter (gen-label)) (loop (gen-label)) (done (gen-label)) (dx-p (node-stack-allocate-p node))) (move context context-arg) (move count count-arg) ;; Check to see if there are any arguments. (inst cmpwi count 0) (move result null-tn) (inst beq done) ;; We need to do this atomically. (pseudo-atomic (pa-flag) ;; Allocate a cons (2 words) for each item. (if dx-p (progn (align-csp temp) (inst clrrwi result csp-tn n-lowtag-bits) (inst ori result result list-pointer-lowtag) (move dst result) (inst slwi temp count 1) (inst add csp-tn csp-tn temp)) (progn (inst slwi temp count 1) (allocation result temp list-pointer-lowtag :temp-tn dst :flag-tn pa-flag) (move dst result))) (inst b enter) ;; Compute the next cons and store it in the current one. (emit-label loop) (inst addi dst dst (* 2 n-word-bytes)) (storew dst dst -1 list-pointer-lowtag) ;; Grab one value. (emit-label enter) (loadw temp context) (inst addi context context n-word-bytes) ;; Dec count, and if != zero, go back for more. (inst addic. count count (- (fixnumize 1))) ;; Store the value into the car of the current cons (in the delay ;; slot). (storew temp dst 0 list-pointer-lowtag) (inst bgt loop) ;; NIL out the last cons. (storew null-tn dst 1 list-pointer-lowtag)) (emit-label done)))) ;;; Return the location and size of the more arg glob created by ;;; COPY-MORE-ARG. SUPPLIED is the total number of arguments supplied ;;; (originally passed in NARGS.) Fixed is the number of non-rest ;;; arguments. ;;; ;;; We must duplicate some of the work done by COPY-MORE-ARG, since at ;;; that time the environment is in a pretty brain-damaged state, ;;; preventing this info from being returned as values. What we do is ;;; compute (- SUPPLIED FIXED), and return a pointer that many words ;;; below the current stack top. (define-vop (more-arg-context) (:policy :fast-safe) (:translate sb!c::%more-arg-context) (:args (supplied :scs (any-reg))) (:arg-types tagged-num (:constant fixnum)) (:info fixed) (:results (context :scs (descriptor-reg)) (count :scs (any-reg))) (:result-types t tagged-num) (:note "more-arg-context") (:generator 5 (inst subi count supplied (fixnumize fixed)) (inst sub context csp-tn count))) (define-vop (verify-arg-count) (:policy :fast-safe) (:translate sb!c::%verify-arg-count) (:args (nargs :scs (any-reg))) (:arg-types positive-fixnum (:constant t)) (:info count) (:vop-var vop) (:save-p :compute-only) (:generator 3 (inst twi :ne nargs (fixnumize count)))) ;;; Signal various errors. (macrolet ((frob (name error translate &rest args) `(define-vop (,name) ,@(when translate `((:policy :fast-safe) (:translate ,translate))) (:args ,@(mapcar #'(lambda (arg) `(,arg :scs (any-reg descriptor-reg))) args)) (:vop-var vop) (:save-p :compute-only) (:generator 1000 (error-call vop ',error ,@args))))) (frob arg-count-error invalid-arg-count-error sb!c::%arg-count-error nargs) (frob type-check-error object-not-type-error sb!c::%type-check-error object type) (frob layout-invalid-error layout-invalid-error sb!c::%layout-invalid-error object layout) (frob odd-key-args-error odd-key-args-error sb!c::%odd-key-args-error) (frob unknown-key-arg-error unknown-key-arg-error sb!c::%unknown-key-arg-error key) (frob nil-fun-returned-error nil-fun-returned-error nil fun)) (define-vop (step-instrument-before-vop) (:temporary (:scs (descriptor-reg)) stepping) (:policy :fast-safe) (:vop-var vop) (:generator 3 ;; Get the symbol-value of SB!IMPL::*STEPPING* #!-sb-thread (load-symbol-value stepping sb!impl::*stepping*) #!+sb-thread (loadw stepping thread-base-tn thread-stepping-slot) (inst cmpw stepping null-tn) ;; If it's not null, trap. (inst beq DONE) ;; CONTEXT-PC will be pointing here when the interrupt is handled, ;; not after the UNIMP. (note-this-location vop :step-before-vop) ;; CALLEE-REGISTER-OFFSET isn't needed for before-traps, so we ;; can just use a bare SINGLE-STEP-BEFORE-TRAP as the code. (inst unimp single-step-before-trap) DONE))