;;;; the x86-64 VM definition of operand loading/saving and the MOVE vop ;;;; 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") (defun zeroize (tn) (let ((offset (tn-offset tn))) ;; Using the 32-bit instruction accomplishes the same thing and is ;; one byte shorter. (if (<= offset edi-offset) (let ((tn (make-random-tn :kind :normal :sc (sc-or-lose 'dword-reg) :offset offset))) (inst xor tn tn)) (inst xor tn tn)))) (define-move-fun (load-immediate 1) (vop x y) ((immediate) (any-reg descriptor-reg)) (let ((val (tn-value x))) (etypecase val (integer (if (zerop val) (zeroize y) (inst mov y (fixnumize val)))) (symbol (load-symbol y val)) (character (inst mov y (logior (ash (char-code val) n-widetag-bits) character-widetag)))))) (define-move-fun (load-number 1) (vop x y) ((immediate) (signed-reg unsigned-reg)) (let ((val (tn-value x))) (if (zerop val) (zeroize y) (inst mov y val)))) (define-move-fun (load-character 1) (vop x y) ((immediate) (character-reg)) (inst mov y (char-code (tn-value x)))) (define-move-fun (load-system-area-pointer 1) (vop x y) ((immediate) (sap-reg)) (inst mov y (sap-int (tn-value x)))) (define-move-fun (load-constant 5) (vop x y) ((constant) (descriptor-reg any-reg)) (inst mov y x)) (define-move-fun (load-stack 5) (vop x y) ((control-stack) (any-reg descriptor-reg) (character-stack) (character-reg) (sap-stack) (sap-reg) (signed-stack) (signed-reg) (unsigned-stack) (unsigned-reg)) (inst mov y x)) (define-move-fun (store-stack 5) (vop x y) ((any-reg descriptor-reg) (control-stack) (character-reg) (character-stack) (sap-reg) (sap-stack) (signed-reg) (signed-stack) (unsigned-reg) (unsigned-stack)) (inst mov y x)) ;;;; the MOVE VOP (define-vop (move) (:args (x :scs (any-reg descriptor-reg immediate) :target y :load-if (not (location= x y)))) (:results (y :scs (any-reg descriptor-reg) :load-if (not (or (location= x y) (and (sc-is x any-reg descriptor-reg immediate) (sc-is y control-stack)))))) (:temporary (:sc unsigned-reg) temp) (:effects) (:affected) (:generator 0 (if (and (sc-is x immediate) (sc-is y any-reg descriptor-reg control-stack)) (let ((val (tn-value x))) (etypecase val (integer (if (and (zerop val) (sc-is y any-reg descriptor-reg)) (zeroize y) (move-immediate y (fixnumize val) temp))) (symbol (inst mov y (+ nil-value (static-symbol-offset val)))) (character (inst mov y (logior (ash (char-code val) n-widetag-bits) character-widetag))))) (move y x)))) (define-move-vop move :move (any-reg descriptor-reg immediate) (any-reg descriptor-reg)) ;;; Make MOVE the check VOP for T so that type check generation ;;; doesn't think it is a hairy type. This also allows checking of a ;;; few of the values in a continuation to fall out. (primitive-type-vop move (:check) t) (defun move-immediate (target val &optional tmp-tn) (cond ;; If target is a register, we can just mov it there directly ((and (tn-p target) (sc-is target signed-reg unsigned-reg descriptor-reg any-reg)) (inst mov target val)) ;; Likewise if the value is small enough. ((typep val '(signed-byte 31)) (inst mov target val)) ;; Otherwise go through the temporary register (tmp-tn (inst mov tmp-tn val) (inst mov target tmp-tn)) (t (error "~A is not a register, no temporary given, and immediate ~A too large" target val)))) ;;; The MOVE-ARG VOP is used for moving descriptor values into ;;; another frame for argument or known value passing. ;;; ;;; Note: It is not going to be possible to move a constant directly ;;; to another frame, except if the destination is a register and in ;;; this case the loading works out. (define-vop (move-arg) (:args (x :scs (any-reg descriptor-reg immediate) :target y :load-if (not (and (sc-is y any-reg descriptor-reg) (sc-is x control-stack)))) (fp :scs (any-reg) :load-if (not (sc-is y any-reg descriptor-reg)))) (:results (y)) (:generator 0 (sc-case y ((any-reg descriptor-reg) (if (sc-is x immediate) (let ((val (tn-value x))) (etypecase val ((integer 0 0) (zeroize y)) ((or (signed-byte 29) (unsigned-byte 29)) (inst mov y (fixnumize val))) (integer (move-immediate y (fixnumize val))) (symbol (load-symbol y val)) (character (inst mov y (logior (ash (char-code val) n-widetag-bits) character-widetag))))) (move y x))) ((control-stack) (if (sc-is x immediate) (let ((val (tn-value x))) (if (= (tn-offset fp) esp-offset) ;; C-call (etypecase val (integer (storew (fixnumize val) fp (tn-offset y))) (symbol (storew (+ nil-value (static-symbol-offset val)) fp (tn-offset y))) (character (storew (logior (ash (char-code val) n-widetag-bits) character-widetag) fp (tn-offset y)))) ;; Lisp stack (etypecase val (integer (storew (fixnumize val) fp (- (1+ (tn-offset y))))) (symbol (storew (+ nil-value (static-symbol-offset val)) fp (- (1+ (tn-offset y))))) (character (storew (logior (ash (char-code val) n-widetag-bits) character-widetag) fp (- (1+ (tn-offset y)))))))) (if (= (tn-offset fp) esp-offset) ;; C-call (storew x fp (tn-offset y)) ;; Lisp stack (storew x fp (- (1+ (tn-offset y)))))))))) (define-move-vop move-arg :move-arg (any-reg descriptor-reg) (any-reg descriptor-reg)) ;;;; ILLEGAL-MOVE ;;; This VOP exists just to begin the lifetime of a TN that couldn't ;;; be written legally due to a type error. An error is signalled ;;; before this VOP is so we don't need to do anything (not that there ;;; would be anything sensible to do anyway.) (define-vop (illegal-move) (:args (x) (type)) (:results (y)) (:ignore y) (:vop-var vop) (:save-p :compute-only) (:generator 666 (error-call vop object-not-type-error x type))) ;;;; moves and coercions ;;; These MOVE-TO-WORD VOPs move a tagged integer to a raw full-word ;;; representation. Similarly, the MOVE-FROM-WORD VOPs converts a raw ;;; integer to a tagged bignum or fixnum. ;;; Arg is a fixnum, so just shift it. We need a type restriction ;;; because some possible arg SCs (control-stack) overlap with ;;; possible bignum arg SCs. (define-vop (move-to-word/fixnum) (:args (x :scs (any-reg descriptor-reg) :target y :load-if (not (location= x y)))) (:results (y :scs (signed-reg unsigned-reg) :load-if (not (location= x y)))) (:arg-types tagged-num) (:note "fixnum untagging") (:generator 1 (move y x) (inst sar y (1- n-lowtag-bits)))) (define-move-vop move-to-word/fixnum :move (any-reg descriptor-reg) (signed-reg unsigned-reg)) ;;; Arg is a non-immediate constant, load it. (define-vop (move-to-word-c) (:args (x :scs (constant))) (:results (y :scs (signed-reg unsigned-reg))) (:note "constant load") (:generator 1 (inst mov y (tn-value x)))) (define-move-vop move-to-word-c :move (constant) (signed-reg unsigned-reg)) ;;; Arg is a fixnum or bignum, figure out which and load if necessary. (define-vop (move-to-word/integer) (:args (x :scs (descriptor-reg) :target eax)) (:results (y :scs (signed-reg unsigned-reg))) (:note "integer to untagged word coercion") (:temporary (:sc unsigned-reg :offset eax-offset :from (:argument 0) :to (:result 0) :target y) eax) (:generator 4 (move eax x) (inst test al-tn 7) ; a symbolic constant for this (inst jmp :z FIXNUM) ; would be nice (loadw y eax bignum-digits-offset other-pointer-lowtag) (inst jmp DONE) FIXNUM (inst sar eax (1- n-lowtag-bits)) (move y eax) DONE)) (define-move-vop move-to-word/integer :move (descriptor-reg) (signed-reg unsigned-reg)) ;;; Result is a fixnum, so we can just shift. We need the result type ;;; restriction because of the control-stack ambiguity noted above. (define-vop (move-from-word/fixnum) (:args (x :scs (signed-reg unsigned-reg) :target y :load-if (not (location= x y)))) (:results (y :scs (any-reg descriptor-reg) :load-if (not (location= x y)))) (:result-types tagged-num) (:note "fixnum tagging") (:generator 1 (cond ((and (sc-is x signed-reg unsigned-reg) (not (location= x y))) ;; Uses 7 bytes, but faster on the Pentium (inst lea y (make-ea :qword :index x :scale 8))) (t ;; Uses: If x is a reg 2 + 3; if x = y uses only 3 bytes (move y x) (inst shl y (1- n-lowtag-bits)))))) (define-move-vop move-from-word/fixnum :move (signed-reg unsigned-reg) (any-reg descriptor-reg)) ;;; Result may be a bignum, so we have to check. Use a worst-case cost ;;; to make sure people know they may be number consing. (define-vop (move-from-signed) (:args (x :scs (signed-reg unsigned-reg) :to :result)) (:results (y :scs (any-reg descriptor-reg) :from :argument)) (:note "signed word to integer coercion") (:node-var node) (:generator 20 (aver (not (location= x y))) (let ((bignum (gen-label)) (done (gen-label))) ;; We can't do the overflow check with SHL Y, 3, since the ;; state of the overflow flag is only reliably set when ;; shifting by 1. There used to be code here for doing "shift ;; by one, check whether it overflowed" three times. But on all ;; x86-64 processors IMUL is a reasonably fast instruction, so ;; we can just do a straight multiply instead of trying to ;; optimize it to a shift. This is both faster and smaller. ;; -- JES, 2006-07-08 (inst imul y x (ash 1 n-fixnum-tag-bits)) (inst jmp :o bignum) (emit-label done) (assemble (*elsewhere*) (emit-label bignum) (with-fixed-allocation (y bignum-widetag (+ bignum-digits-offset 1) node) (storew x y bignum-digits-offset other-pointer-lowtag)) (inst jmp done))))) (define-move-vop move-from-signed :move (signed-reg) (descriptor-reg)) ;;; Check for fixnum, and possibly allocate one or two word bignum ;;; result. Use a worst-case cost to make sure people know they may be ;;; number consing. (define-vop (move-from-unsigned) (:args (x :scs (signed-reg unsigned-reg) :to :save)) (:temporary (:sc unsigned-reg) alloc) (:results (y :scs (any-reg descriptor-reg))) (:node-var node) (:note "unsigned word to integer coercion") (:generator 20 (aver (not (location= x y))) (aver (not (location= x alloc))) (aver (not (location= y alloc))) (let ((bignum (gen-label)) (done (gen-label)) (one-word-bignum (gen-label)) (L1 (gen-label))) (inst bsr y x) ;find msb (inst cmov :z y x) (inst cmp y 60) (inst jmp :ae bignum) (inst lea y (make-ea :qword :index x :scale 8)) (emit-label done) (assemble (*elsewhere*) (emit-label bignum) ;; Note: As on the mips port, space for a two word bignum is ;; always allocated and the header size is set to either one ;; or two words as appropriate. (inst cmp y 63) (inst jmp :l one-word-bignum) ;; two word bignum (inst mov y (logior (ash (1- (+ bignum-digits-offset 2)) n-widetag-bits) bignum-widetag)) (inst jmp L1) (emit-label one-word-bignum) (inst mov y (logior (ash (1- (+ bignum-digits-offset 1)) n-widetag-bits) bignum-widetag)) (emit-label L1) (pseudo-atomic (allocation alloc (pad-data-block (+ bignum-digits-offset 2)) node) (storew y alloc) (inst lea y (make-ea :byte :base alloc :disp other-pointer-lowtag)) (storew x y bignum-digits-offset other-pointer-lowtag)) (inst jmp done))))) (define-move-vop move-from-unsigned :move (unsigned-reg) (descriptor-reg)) ;;; Move untagged numbers. (define-vop (word-move) (:args (x :scs (signed-reg unsigned-reg) :target y :load-if (not (location= x y)))) (:results (y :scs (signed-reg unsigned-reg) :load-if (not (or (location= x y) (and (sc-is x signed-reg unsigned-reg) (sc-is y signed-stack unsigned-stack)))))) (:effects) (:affected) (:note "word integer move") (:generator 0 (move y x))) (define-move-vop word-move :move (signed-reg unsigned-reg) (signed-reg unsigned-reg)) ;;; Move untagged number arguments/return-values. (define-vop (move-word-arg) (:args (x :scs (signed-reg unsigned-reg) :target y) (fp :scs (any-reg) :load-if (not (sc-is y sap-reg)))) (:results (y)) (:note "word integer argument move") (:generator 0 (sc-case y ((signed-reg unsigned-reg) (move y x)) ((signed-stack unsigned-stack) (if (= (tn-offset fp) esp-offset) (storew x fp (tn-offset y)) ; c-call (storew x fp (- (1+ (tn-offset y))))))))) (define-move-vop move-word-arg :move-arg (descriptor-reg any-reg signed-reg unsigned-reg) (signed-reg unsigned-reg)) ;;; Use standard MOVE-ARG and coercion to move an untagged number ;;; to a descriptor passing location. (define-move-vop move-arg :move-arg (signed-reg unsigned-reg) (any-reg descriptor-reg))