;;;; the VM definition arithmetic VOPs for the SPARC ;;;; 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") ;;;; unary operations. (define-vop (fast-safe-arith-op) (:policy :fast-safe) (:effects) (:affected)) (define-vop (fixnum-unop fast-safe-arith-op) (:args (x :scs (any-reg))) (:results (res :scs (any-reg))) (:note "inline fixnum arithmetic") (:arg-types tagged-num) (:result-types tagged-num)) (define-vop (signed-unop fast-safe-arith-op) (:args (x :scs (signed-reg))) (:results (res :scs (signed-reg))) (:note "inline (signed-byte 32) arithmetic") (:arg-types signed-num) (:result-types signed-num)) (define-vop (fast-negate/fixnum fixnum-unop) (:translate %negate) (:generator 1 (inst neg res x))) (define-vop (fast-negate/signed signed-unop) (:translate %negate) (:generator 2 (inst neg res x))) (define-vop (fast-lognot/fixnum fixnum-unop) (:translate lognot) (:generator 2 (inst xor res x (fixnumize -1)))) (define-vop (fast-lognot/signed signed-unop) (:translate lognot) (:generator 1 (inst not res x))) ;;;; Binary fixnum operations. ;;; Assume that any constant operand is the second arg... (define-vop (fast-fixnum-binop fast-safe-arith-op) (:args (x :target r :scs (any-reg zero)) (y :target r :scs (any-reg zero))) (:arg-types tagged-num tagged-num) (:results (r :scs (any-reg))) (:result-types tagged-num) (:note "inline fixnum arithmetic")) (define-vop (fast-unsigned-binop fast-safe-arith-op) (:args (x :target r :scs (unsigned-reg zero)) (y :target r :scs (unsigned-reg zero))) (:arg-types unsigned-num unsigned-num) (:results (r :scs (unsigned-reg))) (:result-types unsigned-num) (:note "inline (unsigned-byte 32) arithmetic")) (define-vop (fast-signed-binop fast-safe-arith-op) (:args (x :target r :scs (signed-reg zero)) (y :target r :scs (signed-reg zero))) (:arg-types signed-num signed-num) (:results (r :scs (signed-reg))) (:result-types signed-num) (:note "inline (signed-byte 32) arithmetic")) (define-vop (fast-fixnum-binop-c fast-safe-arith-op) (:args (x :target r :scs (any-reg zero))) (:info y) (:arg-types tagged-num (:constant (and (signed-byte 11) (not (integer 0 0))))) (:results (r :scs (any-reg))) (:result-types tagged-num) (:note "inline fixnum arithmetic")) (define-vop (fast-unsigned-binop-c fast-safe-arith-op) (:args (x :target r :scs (unsigned-reg zero))) (:info y) (:arg-types unsigned-num (:constant (and (signed-byte 13) (not (integer 0 0))))) (:results (r :scs (unsigned-reg))) (:result-types unsigned-num) (:note "inline (unsigned-byte 32) arithmetic")) (define-vop (fast-signed-binop-c fast-safe-arith-op) (:args (x :target r :scs (signed-reg zero))) (:info y) (:arg-types signed-num (:constant (and (signed-byte 13) (not (integer 0 0))))) (:results (r :scs (signed-reg))) (:result-types signed-num) (:note "inline (signed-byte 32) arithmetic")) (eval-when (:compile-toplevel :load-toplevel :execute) (defmacro define-binop (translate untagged-penalty op &optional arg-swap restore-fixnum-mask) `(progn (define-vop (,(symbolicate 'fast translate '/fixnum=>fixnum) fast-fixnum-binop) ,@(when restore-fixnum-mask `((:temporary (:sc non-descriptor-reg) temp))) (:translate ,translate) (:generator 2 ,(if arg-swap `(inst ,op ,(if restore-fixnum-mask 'temp 'r) y x) `(inst ,op ,(if restore-fixnum-mask 'temp 'r) x y)) ,@(when restore-fixnum-mask `((inst andn r temp fixnum-tag-mask))))) ,@(unless arg-swap `((define-vop (,(symbolicate 'fast- translate '-c/fixnum=>fixnum) fast-fixnum-binop-c) ,@(when restore-fixnum-mask `((:temporary (:sc non-descriptor-reg) temp))) (:translate ,translate) (:generator 1 (inst ,op ,(if restore-fixnum-mask 'temp 'r) x (fixnumize y)) ,@(when restore-fixnum-mask `((inst andn r temp fixnum-tag-mask))))))) (define-vop (,(symbolicate 'fast- translate '/signed=>signed) fast-signed-binop) (:translate ,translate) (:generator ,(1+ untagged-penalty) ,(if arg-swap `(inst ,op r y x) `(inst ,op r x y)))) ,@(unless arg-swap `((define-vop (,(symbolicate 'fast- translate '-c/signed=>signed) fast-signed-binop-c) (:translate ,translate) (:generator ,untagged-penalty (inst ,op r x y))))) (define-vop (,(symbolicate 'fast- translate '/unsigned=>unsigned) fast-unsigned-binop) (:translate ,translate) (:generator ,(1+ untagged-penalty) ,(if arg-swap `(inst ,op r y x) `(inst ,op r x y)))) ,@(unless arg-swap `((define-vop (,(symbolicate 'fast- translate '-c/unsigned=>unsigned) fast-unsigned-binop-c) (:translate ,translate) (:generator ,untagged-penalty (inst ,op r x y))))))) ); eval-when (define-binop + 4 add) (define-binop - 4 sub) (define-binop logand 2 and) (define-binop logandc1 2 andn t) (define-binop logandc2 2 andn) (define-binop logior 2 or) (define-binop logorc1 2 orn t t) (define-binop logorc2 2 orn nil t) (define-binop logxor 2 xor) (define-binop logeqv 2 xnor nil t) (define-vop (fast-logand/signed-unsigned=>unsigned fast-logand/unsigned=>unsigned) (:args (x :scs (signed-reg) :target r) (y :scs (unsigned-reg) :target r)) (:arg-types signed-num unsigned-num) (:translate logand)) ;;; Special case fixnum + and - that trap on overflow. Useful when we ;;; don't know that the output type is a fixnum. ;;; I (Raymond Toy) took these out. They don't seem to be used ;;; anywhere at all. #+nil (progn (define-vop (+/fixnum fast-+/fixnum=>fixnum) (:policy :safe) (:results (r :scs (any-reg descriptor-reg))) (:result-types tagged-num) (:note "safe inline fixnum arithmetic") (:generator 4 (inst taddcctv r x y))) (define-vop (+-c/fixnum fast-+-c/fixnum=>fixnum) (:policy :safe) (:results (r :scs (any-reg descriptor-reg))) (:result-types tagged-num) (:note "safe inline fixnum arithmetic") (:generator 3 (inst taddcctv r x (fixnumize y)))) (define-vop (-/fixnum fast--/fixnum=>fixnum) (:policy :safe) (:results (r :scs (any-reg descriptor-reg))) (:result-types tagged-num) (:note "safe inline fixnum arithmetic") (:generator 4 (inst tsubcctv r x y))) (define-vop (--c/fixnum fast---c/fixnum=>fixnum) (:policy :safe) (:results (r :scs (any-reg descriptor-reg))) (:result-types tagged-num) (:note "safe inline fixnum arithmetic") (:generator 3 (inst tsubcctv r x (fixnumize y)))) ) ;;; Truncate ;; This doesn't work for some reason. #+nil (define-vop (fast-v8-truncate/fixnum=>fixnum fast-safe-arith-op) (:translate truncate) (:args (x :scs (any-reg)) (y :scs (any-reg))) (:arg-types tagged-num tagged-num) (:results (quo :scs (any-reg)) (rem :scs (any-reg))) (:result-types tagged-num tagged-num) (:note "inline fixnum arithmetic") (:temporary (:scs (any-reg) :target quo) q) (:temporary (:scs (any-reg)) r) (:temporary (:scs (signed-reg)) y-int) (:vop-var vop) (:save-p :compute-only) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 12 (let ((zero (generate-error-code vop division-by-zero-error x y))) (inst cmp y zero-tn) (inst b :eq zero) ;; Extend the sign of X into the Y register (inst sra r x 31) (inst wry r) ;; Remove tag bits so Q and R will be tagged correctly. (inst sra y-int y n-fixnum-tag-bits) (inst nop) (inst nop) (inst sdiv q x y-int) ; Q is tagged. ;; We have the quotient so we need to compute the remainder (inst smul r q y-int) ; R is tagged (inst sub rem x r) (unless (location= quo q) (move quo q))))) (define-vop (fast-v8-truncate/signed=>signed fast-safe-arith-op) (:translate truncate) (:args (x :scs (signed-reg)) (y :scs (signed-reg))) (:arg-types signed-num signed-num) (:results (quo :scs (signed-reg)) (rem :scs (signed-reg))) (:result-types signed-num signed-num) (:note "inline (signed-byte 32) arithmetic") (:temporary (:scs (signed-reg) :target quo) q) (:temporary (:scs (signed-reg)) r) (:vop-var vop) (:save-p :compute-only) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 12 (let ((zero (generate-error-code vop division-by-zero-error x y))) (inst cmp y zero-tn) (if (member :sparc-v9 *backend-subfeatures*) (inst b :eq zero :pn) (inst b :eq zero)) ;; Extend the sign of X into the Y register (inst sra r x 31) (inst wry r) (inst nop) (inst nop) (inst nop) (inst sdiv q x y) ;; We have the quotient so we need to compue the remainder (inst smul r q y) ; rem (inst sub rem x r) (unless (location= quo q) (move quo q))))) (define-vop (fast-v8-truncate/unsigned=>unsigned fast-safe-arith-op) (:translate truncate) (:args (x :scs (unsigned-reg)) (y :scs (unsigned-reg))) (:arg-types unsigned-num unsigned-num) (:results (quo :scs (unsigned-reg)) (rem :scs (unsigned-reg))) (:result-types unsigned-num unsigned-num) (:note "inline (unsigned-byte 32) arithmetic") (:temporary (:scs (unsigned-reg) :target quo) q) (:temporary (:scs (unsigned-reg)) r) (:vop-var vop) (:save-p :compute-only) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 8 (let ((zero (generate-error-code vop division-by-zero-error x y))) (inst cmp y zero-tn) (if (member :sparc-v9 *backend-subfeatures*) (inst b :eq zero :pn) (inst b :eq zero)) (inst wry zero-tn) ; Clear out high part (inst nop) (inst nop) (inst nop) (inst udiv q x y) ;; Compute remainder (inst umul r q y) (inst sub rem x r) (unless (location= quo q) (inst move quo q))))) (define-vop (fast-v9-truncate/signed=>signed fast-safe-arith-op) (:translate truncate) (:args (x :scs (signed-reg)) (y :scs (signed-reg))) (:arg-types signed-num signed-num) (:results (quo :scs (signed-reg)) (rem :scs (signed-reg))) (:result-types signed-num signed-num) (:note "inline (signed-byte 32) arithmetic") (:temporary (:scs (signed-reg) :target quo) q) (:temporary (:scs (signed-reg)) r) (:vop-var vop) (:save-p :compute-only) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 8 (let ((zero (generate-error-code vop division-by-zero-error x y))) (inst cmp y zero-tn) (inst b :eq zero :pn) ;; Sign extend the numbers, just in case. (inst sra x 0) (inst sra y 0) (inst sdivx q x y) ;; Compute remainder (inst mulx r q y) (inst sub rem x r) (unless (location= quo q) (inst move quo q))))) (define-vop (fast-v9-truncate/unsigned=>unsigned fast-safe-arith-op) (:translate truncate) (:args (x :scs (unsigned-reg)) (y :scs (unsigned-reg))) (:arg-types unsigned-num unsigned-num) (:results (quo :scs (unsigned-reg)) (rem :scs (unsigned-reg))) (:result-types unsigned-num unsigned-num) (:note "inline (unsigned-byte 32) arithmetic") (:temporary (:scs (unsigned-reg) :target quo) q) (:temporary (:scs (unsigned-reg)) r) (:vop-var vop) (:save-p :compute-only) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 8 (let ((zero (generate-error-code vop division-by-zero-error x y))) (inst cmp y zero-tn) (inst b :eq zero :pn) ;; Zap the higher 32 bits, just in case (inst srl x 0) (inst srl y 0) (inst udivx q x y) ;; Compute remainder (inst mulx r q y) (inst sub rem x r) (unless (location= quo q) (inst move quo q))))) ;;; Shifting (define-vop (fast-ash/signed=>signed) (:note "inline ASH") (:args (number :scs (signed-reg) :to :save) (amount :scs (signed-reg) :to :save)) (:arg-types signed-num signed-num) (:results (result :scs (signed-reg))) (:result-types signed-num) (:translate ash) (:policy :fast-safe) (:temporary (:sc non-descriptor-reg) ndesc) (:generator 5 (let ((done (gen-label))) (inst cmp amount) (inst b :ge done) ;; The result-type assures us that this shift will not ;; overflow. (inst sll result number amount) (inst neg ndesc amount) (inst cmp ndesc 31) (if (member :sparc-v9 *backend-subfeatures*) (progn (inst cmove :ge ndesc 31) (inst sra result number ndesc)) (progn (inst b :le done) (inst sra result number ndesc) (inst sra result number 31))) (emit-label done)))) (define-vop (fast-ash-c/signed=>signed) (:note "inline constant ASH") (:args (number :scs (signed-reg))) (:info count) (:arg-types signed-num (:constant integer)) (:results (result :scs (signed-reg))) (:result-types signed-num) (:translate ash) (:policy :fast-safe) (:generator 4 (cond ((< count 0) (inst sra result number (min (- count) 31))) ((> count 0) (inst sll result number (min count 31))) (t (bug "identity ASH not transformed away"))))) (define-vop (fast-ash/unsigned=>unsigned) (:note "inline ASH") (:args (number :scs (unsigned-reg) :to :save) (amount :scs (signed-reg) :to :save)) (:arg-types unsigned-num signed-num) (:results (result :scs (unsigned-reg))) (:result-types unsigned-num) (:translate ash) (:policy :fast-safe) (:temporary (:sc non-descriptor-reg) ndesc) (:generator 5 (let ((done (gen-label))) (inst cmp amount) (inst b :ge done) ;; The result-type assures us that this shift will not ;; overflow. (inst sll result number amount) (inst neg ndesc amount) (inst cmp ndesc 32) (if (member :sparc-v9 *backend-subfeatures*) (progn (inst srl result number ndesc) (inst cmove :ge result zero-tn)) (progn (inst b :lt done) (inst srl result number ndesc) (move result zero-tn))) (emit-label done)))) (define-vop (fast-ash-c/unsigned=>unsigned) (:note "inline constant ASH") (:args (number :scs (unsigned-reg))) (:info count) (:arg-types unsigned-num (:constant integer)) (:results (result :scs (unsigned-reg))) (:result-types unsigned-num) (:translate ash) (:policy :fast-safe) (:generator 4 (cond ((< count -31) (move result zero-tn)) ((< count 0) (inst srl result number (min (- count) 31))) ((> count 0) (inst sll result number (min count 31))) (t (bug "identity ASH not transformed away"))))) ;; Some special cases where we know we want a left shift. Just do the ;; shift, instead of checking for the sign of the shift. (macrolet ((frob (name sc-type type result-type cost) `(define-vop (,name) (:note "inline ASH") (:translate ash) (:args (number :scs (,sc-type)) (amount :scs (signed-reg unsigned-reg immediate))) (:arg-types ,type positive-fixnum) (:results (result :scs (,result-type))) (:result-types ,type) (:policy :fast-safe) (:generator ,cost ;; The result-type assures us that this shift will not ;; overflow. And for fixnums, the zero bits that get ;; shifted in are just fine for the fixnum tag. (sc-case amount ((signed-reg unsigned-reg) (inst sll result number amount)) (immediate (let ((amount (tn-value amount))) (aver (>= amount 0)) (inst sll result number amount)))))))) (frob fast-ash-left/signed=>signed signed-reg signed-num signed-reg 3) (frob fast-ash-left/fixnum=>fixnum any-reg tagged-num any-reg 2) (frob fast-ash-left/unsigned=>unsigned unsigned-reg unsigned-num unsigned-reg 3)) (define-vop (signed-byte-32-len) (:translate integer-length) (:note "inline (signed-byte 32) integer-length") (:policy :fast-safe) (:args (arg :scs (signed-reg) :target shift)) (:arg-types signed-num) (:results (res :scs (any-reg))) (:result-types positive-fixnum) (:temporary (:scs (non-descriptor-reg) :from (:argument 0)) shift) (:generator 30 (let ((loop (gen-label)) (test (gen-label))) (inst addcc shift zero-tn arg) (inst b :ge test) (move res zero-tn) (inst b test) (inst not shift) (emit-label loop) (inst add res (fixnumize 1)) (emit-label test) (inst cmp shift) (inst b :ne loop) (inst srl shift 1)))) (define-vop (unsigned-byte-32-count) (:translate logcount) (:note "inline (unsigned-byte 32) logcount") (:policy :fast-safe) (:args (arg :scs (unsigned-reg))) (:arg-types unsigned-num) (:results (res :scs (unsigned-reg))) (:result-types positive-fixnum) (:temporary (:scs (non-descriptor-reg) :from (:argument 0)) mask temp) (:generator 35 (move res arg) (dolist (stuff '((1 #x55555555) (2 #x33333333) (4 #x0f0f0f0f) (8 #x00ff00ff) (16 #x0000ffff))) (destructuring-bind (shift bit-mask) stuff ;; Set mask (inst sethi mask (ldb (byte 22 10) bit-mask)) (inst add mask (ldb (byte 10 0) bit-mask)) (inst and temp res mask) (inst srl res shift) (inst and res mask) (inst add res temp))))) ;;; Multiply and Divide. (define-vop (fast-v8-*/fixnum=>fixnum fast-fixnum-binop) (:temporary (:scs (non-descriptor-reg)) temp) (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 2 ;; The cost here should be less than the cost for ;; */signed=>signed. Why? A fixnum product using signed=>signed ;; has to convert both args to signed-nums. But using this, we ;; don't have to and that saves an instruction. (inst sra temp y n-fixnum-tag-bits) (inst smul r x temp))) (define-vop (fast-v8-*-c/fixnum=>fixnum fast-safe-arith-op) (:args (x :target r :scs (any-reg zero))) (:info y) (:arg-types tagged-num (:constant (and (signed-byte 13) (not (integer 0 0))))) (:results (r :scs (any-reg))) (:result-types tagged-num) (:note "inline fixnum arithmetic") (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 1 (inst smul r x y))) (define-vop (fast-v8-*/signed=>signed fast-signed-binop) (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 3 (inst smul r x y))) (define-vop (fast-v8-*-c/signed=>signed fast-signed-binop-c) (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 2 (inst smul r x y))) (define-vop (fast-v8-*/unsigned=>unsigned fast-unsigned-binop) (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 3 (inst umul r x y))) (define-vop (fast-v8-*-c/unsigned=>unsigned fast-unsigned-binop-c) (:translate *) (:guard (or (member :sparc-v8 *backend-subfeatures*) (and (member :sparc-v9 *backend-subfeatures*) (not (member :sparc-64 *backend-subfeatures*))))) (:generator 2 (inst umul r x y))) ;; The smul and umul instructions are deprecated on the Sparc V9. Use ;; mulx instead. (define-vop (fast-v9-*/fixnum=>fixnum fast-fixnum-binop) (:temporary (:scs (non-descriptor-reg)) temp) (:translate *) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 4 (inst sra temp y n-fixnum-tag-bits) (inst mulx r x temp))) (define-vop (fast-v9-*/signed=>signed fast-signed-binop) (:translate *) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 3 (inst mulx r x y))) (define-vop (fast-v9-*/unsigned=>unsigned fast-unsigned-binop) (:translate *) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 3 (inst mulx r x y))) ;;;; Modular functions: (define-modular-fun lognot-mod32 (x) lognot 32) (define-vop (lognot-mod32/unsigned=>unsigned) (:translate lognot-mod32) (:args (x :scs (unsigned-reg))) (:arg-types unsigned-num) (:results (res :scs (unsigned-reg))) (:result-types unsigned-num) (:policy :fast-safe) (:generator 1 (inst not res x))) (macrolet ((define-modular-backend (fun &optional constantp) (let ((mfun-name (symbolicate fun '-mod32)) (modvop (symbolicate 'fast- fun '-mod32/unsigned=>unsigned)) (modcvop (symbolicate 'fast- fun '-mod32-c/unsigned=>unsigned)) (vop (symbolicate 'fast- fun '/unsigned=>unsigned)) (cvop (symbolicate 'fast- fun '-c/unsigned=>unsigned))) `(progn (define-modular-fun ,mfun-name (x y) ,fun 32) (define-vop (,modvop ,vop) (:translate ,mfun-name)) ,@(when constantp `((define-vop (,modcvop ,cvop) (:translate ,mfun-name)))))))) (define-modular-backend + t) (define-modular-backend - t) (define-modular-backend logxor t) (define-modular-backend logeqv t) (define-modular-backend logandc1) (define-modular-backend logandc2 t) (define-modular-backend logorc1) (define-modular-backend logorc2 t)) (define-source-transform lognand (x y) `(lognot (logand ,x ,y))) (define-source-transform lognor (x y) `(lognot (logior ,x ,y))) (define-vop (fast-ash-left-mod32-c/unsigned=>unsigned fast-ash-c/unsigned=>unsigned) (:translate ash-left-mod32)) ;;;; Binary conditional VOPs: (define-vop (fast-conditional) (:conditional) (:info target not-p) (:effects) (:affected) (:policy :fast-safe)) (define-vop (fast-conditional/fixnum fast-conditional) (:args (x :scs (any-reg zero)) (y :scs (any-reg zero))) (:arg-types tagged-num tagged-num) (:note "inline fixnum comparison")) (define-vop (fast-conditional-c/fixnum fast-conditional/fixnum) (:args (x :scs (any-reg zero))) (:arg-types tagged-num (:constant (signed-byte 11))) (:info target not-p y)) (define-vop (fast-conditional/signed fast-conditional) (:args (x :scs (signed-reg zero)) (y :scs (signed-reg zero))) (:arg-types signed-num signed-num) (:note "inline (signed-byte 32) comparison")) (define-vop (fast-conditional-c/signed fast-conditional/signed) (:args (x :scs (signed-reg zero))) (:arg-types signed-num (:constant (signed-byte 13))) (:info target not-p y)) (define-vop (fast-conditional/unsigned fast-conditional) (:args (x :scs (unsigned-reg zero)) (y :scs (unsigned-reg zero))) (:arg-types unsigned-num unsigned-num) (:note "inline (unsigned-byte 32) comparison")) (define-vop (fast-conditional-c/unsigned fast-conditional/unsigned) (:args (x :scs (unsigned-reg zero))) (:arg-types unsigned-num (:constant (unsigned-byte 12))) (:info target not-p y)) (defmacro define-conditional-vop (tran cond unsigned not-cond not-unsigned) `(progn ,@(mapcar (lambda (suffix cost signed) (unless (and (member suffix '(/fixnum -c/fixnum)) (eq tran 'eql)) `(define-vop (,(intern (format nil "~:@(FAST-IF-~A~A~)" tran suffix)) ,(intern (format nil "~:@(FAST-CONDITIONAL~A~)" suffix))) (:translate ,tran) (:generator ,cost (inst cmp x ,(if (eq suffix '-c/fixnum) '(fixnumize y) 'y)) (inst b (if not-p ,(if signed not-cond not-unsigned) ,(if signed cond unsigned)) target) (inst nop))))) '(/fixnum -c/fixnum /signed -c/signed /unsigned -c/unsigned) '(4 3 6 5 6 5) '(t t t t nil nil)))) (define-conditional-vop < :lt :ltu :ge :geu) (define-conditional-vop > :gt :gtu :le :leu) (define-conditional-vop eql :eq :eq :ne :ne) ;;; EQL/FIXNUM is funny because the first arg can be of any type, not just a ;;; known fixnum. ;;; These versions specify a fixnum restriction on their first arg. We have ;;; also generic-eql/fixnum VOPs which are the same, but have no restriction on ;;; the first arg and a higher cost. The reason for doing this is to prevent ;;; fixnum specific operations from being used on word integers, spuriously ;;; consing the argument. ;;; (define-vop (fast-eql/fixnum fast-conditional) (:args (x :scs (any-reg descriptor-reg zero)) (y :scs (any-reg zero))) (:arg-types tagged-num tagged-num) (:note "inline fixnum comparison") (:translate eql) (:generator 4 (inst cmp x y) (inst b (if not-p :ne :eq) target) (inst nop))) ;;; (define-vop (generic-eql/fixnum fast-eql/fixnum) (:arg-types * tagged-num) (:variant-cost 7)) (define-vop (fast-eql-c/fixnum fast-conditional/fixnum) (:args (x :scs (any-reg descriptor-reg zero))) (:arg-types tagged-num (:constant (signed-byte 11))) (:info target not-p y) (:translate eql) (:generator 2 (inst cmp x (fixnumize y)) (inst b (if not-p :ne :eq) target) (inst nop))) ;;; (define-vop (generic-eql-c/fixnum fast-eql-c/fixnum) (:arg-types * (:constant (signed-byte 11))) (:variant-cost 6)) ;;;; 32-bit logical operations (define-vop (merge-bits) (:translate merge-bits) (:args (shift :scs (signed-reg unsigned-reg)) (prev :scs (unsigned-reg)) (next :scs (unsigned-reg))) (:arg-types tagged-num unsigned-num unsigned-num) (:temporary (:scs (unsigned-reg) :to (:result 0)) temp) (:temporary (:scs (unsigned-reg) :to (:result 0) :target result) res) (:results (result :scs (unsigned-reg))) (:result-types unsigned-num) (:policy :fast-safe) (:generator 4 (let ((done (gen-label))) (inst cmp shift) (inst b :eq done) (inst srl res next shift) (inst sub temp zero-tn shift) (inst sll temp prev temp) (inst or res temp) (emit-label done) (move result res)))) (define-source-transform word-logical-not (x) `(logand (lognot (the (unsigned-byte 32) ,x)) #.(1- (ash 1 32)))) (deftransform word-logical-and ((x y)) '(logand x y)) (deftransform word-logical-nand ((x y)) '(logand (lognand x y) #.(1- (ash 1 32)))) (deftransform word-logical-or ((x y)) '(logior x y)) (deftransform word-logical-nor ((x y)) '(logand (lognor x y) #.(1- (ash 1 32)))) (deftransform word-logical-xor ((x y)) '(logxor x y)) (deftransform word-logical-eqv ((x y)) '(logand (logeqv x y) #.(1- (ash 1 32)))) (deftransform word-logical-orc1 ((x y)) '(logand (logorc1 x y) #.(1- (ash 1 32)))) (deftransform word-logical-orc2 ((x y)) '(logand (logorc2 x y) #.(1- (ash 1 32)))) (deftransform word-logical-andc1 ((x y)) '(logand (logandc1 x y) #.(1- (ash 1 32)))) (deftransform word-logical-andc2 ((x y)) '(logand (logandc2 x y) #.(1- (ash 1 32)))) (define-vop (shift-towards-someplace) (:policy :fast-safe) (:args (num :scs (unsigned-reg)) (amount :scs (signed-reg))) (:arg-types unsigned-num tagged-num) (:results (r :scs (unsigned-reg))) (:result-types unsigned-num)) (define-vop (shift-towards-start shift-towards-someplace) (:translate shift-towards-start) (:note "shift-towards-start") (:generator 1 (inst sll r num amount))) (define-vop (shift-towards-end shift-towards-someplace) (:translate shift-towards-end) (:note "shift-towards-end") (:generator 1 (inst srl r num amount))) ;;;; Bignum stuff. (define-vop (bignum-length get-header-data) (:translate sb!bignum:%bignum-length) (:policy :fast-safe)) (define-vop (bignum-set-length set-header-data) (:translate sb!bignum:%bignum-set-length) (:policy :fast-safe)) (define-vop (bignum-ref word-index-ref) (:variant bignum-digits-offset other-pointer-lowtag) (:translate sb!bignum:%bignum-ref) (:results (value :scs (unsigned-reg))) (:result-types unsigned-num)) (define-vop (bignum-set word-index-set) (:variant bignum-digits-offset other-pointer-lowtag) (:translate sb!bignum:%bignum-set) (:args (object :scs (descriptor-reg)) (index :scs (any-reg immediate zero)) (value :scs (unsigned-reg))) (:arg-types t positive-fixnum unsigned-num) (:results (result :scs (unsigned-reg))) (:result-types unsigned-num)) (define-vop (digit-0-or-plus) (:translate sb!bignum:%digit-0-or-plusp) (:policy :fast-safe) (:args (digit :scs (unsigned-reg))) (:arg-types unsigned-num) (:results (result :scs (descriptor-reg))) (:guard (not (member :sparc-v9 *backend-subfeatures*))) (:generator 3 (let ((done (gen-label))) (inst cmp digit) (inst b :lt done) (move result null-tn) (load-symbol result t) (emit-label done)))) (define-vop (v9-digit-0-or-plus-cmove) (:translate sb!bignum:%digit-0-or-plusp) (:policy :fast-safe) (:args (digit :scs (unsigned-reg))) (:arg-types unsigned-num) (:results (result :scs (descriptor-reg))) (:guard (member :sparc-v9 *backend-subfeatures*)) (:generator 3 (inst cmp digit) (load-symbol result t) (inst cmove :lt result null-tn))) ;; This doesn't work? #+nil (define-vop (v9-digit-0-or-plus-movr) (:translate sb!bignum:%digit-0-or-plusp) (:policy :fast-safe) (:args (digit :scs (unsigned-reg))) (:arg-types unsigned-num) (:results (result :scs (descriptor-reg))) (:temporary (:scs (descriptor-reg)) temp) (:guard #!+:sparc-v9 t #!-:sparc-v9 nil) (:generator 2 (load-symbol temp t) (inst movr result null-tn digit :lz) (inst movr result temp digit :gez))) (define-vop (add-w/carry) (:translate sb!bignum:%add-with-carry) (:policy :fast-safe) (:args (a :scs (unsigned-reg)) (b :scs (unsigned-reg)) (c :scs (any-reg))) (:arg-types unsigned-num unsigned-num positive-fixnum) (:results (result :scs (unsigned-reg)) (carry :scs (unsigned-reg))) (:result-types unsigned-num positive-fixnum) (:generator 3 (inst addcc zero-tn c -1) (inst addxcc result a b) (inst addx carry zero-tn zero-tn))) (define-vop (sub-w/borrow) (:translate sb!bignum:%subtract-with-borrow) (:policy :fast-safe) (:args (a :scs (unsigned-reg)) (b :scs (unsigned-reg)) (c :scs (any-reg))) (:arg-types unsigned-num unsigned-num positive-fixnum) (:results (result :scs (unsigned-reg)) (borrow :scs (unsigned-reg))) (:result-types unsigned-num positive-fixnum) (:generator 4 (inst subcc zero-tn c 1) (inst subxcc result a b) (inst addx borrow zero-tn zero-tn) (inst xor borrow 1))) ;;; EMIT-MULTIPLY -- This is used both for bignum stuff and in assembly ;;; routines. ;;; (defun emit-multiply (multiplier multiplicand result-high result-low) "Emit code to multiply MULTIPLIER with MULTIPLICAND, putting the result in RESULT-HIGH and RESULT-LOW. KIND is either :signed or :unsigned. Note: the lifetimes of MULTIPLICAND and RESULT-HIGH overlap." (declare (type tn multiplier result-high result-low) (type (or tn (signed-byte 13)) multiplicand)) ;; It seems that emit-multiply is only used to do an unsigned ;; multiply, so the code only does an unsigned multiply. (cond ((member :sparc-64 *backend-subfeatures*) ;; Take advantage of V9's 64-bit multiplier. ;; ;; Make sure the multiplier and multiplicand are really ;; unsigned 64-bit numbers. (inst srl multiplier 0) (inst srl multiplicand 0) ;; Multiply the two numbers and put the result in ;; result-high. Copy the low 32-bits to result-low. Then ;; shift result-high so the high 32-bits end up in the low ;; 32-bits. (inst mulx result-high multiplier multiplicand) (inst move result-low result-high) (inst srax result-high 32)) ((or (member :sparc-v8 *backend-subfeatures*) (member :sparc-v9 *backend-subfeatures*)) ;; V8 has a multiply instruction. This should also work for ;; the V9, but umul and the Y register is deprecated on the ;; V9. (inst umul result-low multiplier multiplicand) (inst rdy result-high)) (t (let ((label (gen-label))) (inst wry multiplier) (inst andcc result-high zero-tn) ;; Note: we can't use the Y register until three insts ;; after it's written. (inst nop) (inst nop) (dotimes (i 32) (inst mulscc result-high multiplicand)) (inst mulscc result-high zero-tn) (inst cmp multiplicand) (inst b :ge label) (inst nop) (inst add result-high multiplier) (emit-label label) (inst rdy result-low))))) (define-vop (bignum-mult-and-add-3-arg) (:translate sb!bignum:%multiply-and-add) (:policy :fast-safe) (:args (x :scs (unsigned-reg) :to (:eval 1)) (y :scs (unsigned-reg) :to (:eval 1)) (carry-in :scs (unsigned-reg) :to (:eval 2))) (:arg-types unsigned-num unsigned-num unsigned-num) (:results (hi :scs (unsigned-reg) :from (:eval 0)) (lo :scs (unsigned-reg) :from (:eval 1))) (:result-types unsigned-num unsigned-num) (:generator 40 (emit-multiply x y hi lo) (inst addcc lo carry-in) (inst addx hi zero-tn))) (define-vop (bignum-mult-and-add-4-arg) (:translate sb!bignum:%multiply-and-add) (:policy :fast-safe) (:args (x :scs (unsigned-reg) :to (:eval 1)) (y :scs (unsigned-reg) :to (:eval 1)) (prev :scs (unsigned-reg) :to (:eval 2)) (carry-in :scs (unsigned-reg) :to (:eval 2))) (:arg-types unsigned-num unsigned-num unsigned-num unsigned-num) (:results (hi :scs (unsigned-reg) :from (:eval 0)) (lo :scs (unsigned-reg) :from (:eval 1))) (:result-types unsigned-num unsigned-num) (:generator 40 (emit-multiply x y hi lo) (inst addcc lo carry-in) (inst addx hi zero-tn) (inst addcc lo prev) (inst addx hi zero-tn))) (define-vop (bignum-mult) (:translate sb!bignum:%multiply) (:policy :fast-safe) (:args (x :scs (unsigned-reg) :to (:result 1)) (y :scs (unsigned-reg) :to (:result 1))) (:arg-types unsigned-num unsigned-num) (:results (hi :scs (unsigned-reg)) (lo :scs (unsigned-reg))) (:result-types unsigned-num unsigned-num) (:generator 40 (emit-multiply x y hi lo))) (define-vop (bignum-lognot lognot-mod32/unsigned=>unsigned) (:translate sb!bignum:%lognot)) (define-vop (fixnum-to-digit) (:translate sb!bignum:%fixnum-to-digit) (:policy :fast-safe) (:args (fixnum :scs (any-reg))) (:arg-types tagged-num) (:results (digit :scs (unsigned-reg))) (:result-types unsigned-num) (:generator 1 (inst sra digit fixnum n-fixnum-tag-bits))) (define-vop (bignum-floor) (:translate sb!bignum:%floor) (:policy :fast-safe) (:args (div-high :scs (unsigned-reg) :target rem) (div-low :scs (unsigned-reg) :target quo) (divisor :scs (unsigned-reg))) (:arg-types unsigned-num unsigned-num unsigned-num) (:results (quo :scs (unsigned-reg) :from (:argument 1)) (rem :scs (unsigned-reg) :from (:argument 0))) (:result-types unsigned-num unsigned-num) (:generator 300 (move rem div-high) (move quo div-low) (dotimes (i 33) (let ((label (gen-label))) (inst cmp rem divisor) (inst b :ltu label) (inst addxcc quo quo) (inst sub rem divisor) (emit-label label) (unless (= i 32) (inst addx rem rem)))) (inst not quo))) (define-vop (bignum-floor-v8) (:translate sb!bignum:%floor) (:policy :fast-safe) (:args (div-high :scs (unsigned-reg) :target rem) (div-low :scs (unsigned-reg) :target quo) (divisor :scs (unsigned-reg))) (:arg-types unsigned-num unsigned-num unsigned-num) (:results (quo :scs (unsigned-reg) :from (:argument 1)) (rem :scs (unsigned-reg) :from (:argument 0))) (:result-types unsigned-num unsigned-num) (:temporary (:scs (unsigned-reg) :target quo) q) ;; This vop is for a v8 or v9, provided we're also not using ;; sparc-64, for which there a special sparc-64 vop. (:guard (or (member :sparc-v8 *backend-subfeatures*) (member :sparc-v9 *backend-subfeatures*))) (:generator 15 (inst wry div-high) (inst nop) (inst nop) (inst nop) ;; Compute the quotient [Y, div-low] / divisor (inst udiv q div-low divisor) ;; Compute the remainder. The high part of the result is in the Y ;; register. (inst umul rem q divisor) (inst sub rem div-low rem) (unless (location= quo q) (move quo q)))) (define-vop (bignum-floor-v9) (:translate sb!bignum:%floor) (:policy :fast-safe) (:args (div-high :scs (unsigned-reg)) (div-low :scs (unsigned-reg)) (divisor :scs (unsigned-reg) :to (:result 1))) (:arg-types unsigned-num unsigned-num unsigned-num) (:temporary (:sc unsigned-reg :from (:argument 0)) dividend) (:results (quo :scs (unsigned-reg)) (rem :scs (unsigned-reg))) (:result-types unsigned-num unsigned-num) (:guard (member :sparc-64 *backend-subfeatures*)) (:generator 5 ;; Set dividend to be div-high and div-low (inst sllx dividend div-high 32) (inst add dividend div-low) ;; Compute quotient (inst udivx quo dividend divisor) ;; Compute the remainder (inst mulx rem quo divisor) (inst sub rem dividend rem))) (define-vop (signify-digit) (:translate sb!bignum:%fixnum-digit-with-correct-sign) (:policy :fast-safe) (:args (digit :scs (unsigned-reg) :target res)) (:arg-types unsigned-num) (:results (res :scs (any-reg signed-reg))) (:result-types signed-num) (:generator 1 (sc-case res (any-reg (inst sll res digit n-fixnum-tag-bits)) (signed-reg (move res digit))))) (define-vop (digit-ashr) (:translate sb!bignum:%ashr) (:policy :fast-safe) (:args (digit :scs (unsigned-reg)) (count :scs (unsigned-reg))) (:arg-types unsigned-num positive-fixnum) (:results (result :scs (unsigned-reg))) (:result-types unsigned-num) (:generator 1 (inst sra result digit count))) (define-vop (digit-lshr digit-ashr) (:translate sb!bignum:%digit-logical-shift-right) (:generator 1 (inst srl result digit count))) (define-vop (digit-ashl digit-ashr) (:translate sb!bignum:%ashl) (:generator 1 (inst sll result digit count))) ;;;; Static functions. (define-static-fun two-arg-gcd (x y) :translate gcd) (define-static-fun two-arg-lcm (x y) :translate lcm) (define-static-fun two-arg-+ (x y) :translate +) (define-static-fun two-arg-- (x y) :translate -) (define-static-fun two-arg-* (x y) :translate *) (define-static-fun two-arg-/ (x y) :translate /) (define-static-fun two-arg-< (x y) :translate <) (define-static-fun two-arg-<= (x y) :translate <=) (define-static-fun two-arg-> (x y) :translate >) (define-static-fun two-arg->= (x y) :translate >=) (define-static-fun two-arg-= (x y) :translate =) (define-static-fun two-arg-/= (x y) :translate /=) (define-static-fun %negate (x) :translate %negate) (define-static-fun two-arg-and (x y) :translate logand) (define-static-fun two-arg-ior (x y) :translate logior) (define-static-fun two-arg-xor (x y) :translate logxor) (define-static-fun two-arg-eqv (x y) :translate logeqv) (in-package "SB!C") (deftransform * ((x y) ((unsigned-byte 32) (constant-arg (unsigned-byte 32))) (unsigned-byte 32)) "recode as shifts and adds" (let ((y (lvar-value y))) (multiple-value-bind (result adds shifts) (ub32-strength-reduce-constant-multiply 'x y) (cond ;; we assume, perhaps foolishly, that good SPARCs don't have an ;; issue with multiplications. (Remember that there's a ;; different transform for converting x*2^k to a shift). ((member :sparc-64 *backend-subfeatures*) (give-up-ir1-transform)) ((or (member :sparc-v9 *backend-subfeatures*) (member :sparc-v8 *backend-subfeatures*)) ;; breakeven point as measured by Raymond Toy (when (> (+ adds shifts) 9) (give-up-ir1-transform)))) (or result 0))))