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1 /*
2  * Copyright (C) 2008 Apple Inc. All rights reserved.
3  *
4  * Redistribution and use in source and binary forms, with or without
5  * modification, are permitted provided that the following conditions
6  * are met:
7  * 1. Redistributions of source code must retain the above copyright
8  *    notice, this list of conditions and the following disclaimer.
9  * 2. Redistributions in binary form must reproduce the above copyright
10  *    notice, this list of conditions and the following disclaimer in the
11  *    documentation and/or other materials provided with the distribution.
12  *
13  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
14  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
15  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
16  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
17  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
18  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
19  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
20  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
21  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
22  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
23  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
24  */
25 
26 #ifndef MacroAssemblerX86Common_h
27 #define MacroAssemblerX86Common_h
28 
29 #include <wtf/Platform.h>
30 
31 #if ENABLE(ASSEMBLER)
32 
33 #include "X86Assembler.h"
34 #include "AbstractMacroAssembler.h"
35 
36 namespace JSC {
37 
38 class MacroAssemblerX86Common : public AbstractMacroAssembler<X86Assembler> {
39     static const int DoubleConditionBitInvert = 0x10;
40     static const int DoubleConditionBitSpecial = 0x20;
41     static const int DoubleConditionBits = DoubleConditionBitInvert | DoubleConditionBitSpecial;
42 
43 public:
44 
45     enum Condition {
46         Equal = X86Assembler::ConditionE,
47         NotEqual = X86Assembler::ConditionNE,
48         Above = X86Assembler::ConditionA,
49         AboveOrEqual = X86Assembler::ConditionAE,
50         Below = X86Assembler::ConditionB,
51         BelowOrEqual = X86Assembler::ConditionBE,
52         GreaterThan = X86Assembler::ConditionG,
53         GreaterThanOrEqual = X86Assembler::ConditionGE,
54         LessThan = X86Assembler::ConditionL,
55         LessThanOrEqual = X86Assembler::ConditionLE,
56         Overflow = X86Assembler::ConditionO,
57         Signed = X86Assembler::ConditionS,
58         Zero = X86Assembler::ConditionE,
59         NonZero = X86Assembler::ConditionNE
60     };
61 
62     enum DoubleCondition {
63         // These conditions will only evaluate to true if the comparison is ordered - i.e. neither operand is NaN.
64         DoubleEqual = X86Assembler::ConditionE | DoubleConditionBitSpecial,
65         DoubleNotEqual = X86Assembler::ConditionNE,
66         DoubleGreaterThan = X86Assembler::ConditionA,
67         DoubleGreaterThanOrEqual = X86Assembler::ConditionAE,
68         DoubleLessThan = X86Assembler::ConditionA | DoubleConditionBitInvert,
69         DoubleLessThanOrEqual = X86Assembler::ConditionAE | DoubleConditionBitInvert,
70         // If either operand is NaN, these conditions always evaluate to true.
71         DoubleEqualOrUnordered = X86Assembler::ConditionE,
72         DoubleNotEqualOrUnordered = X86Assembler::ConditionNE | DoubleConditionBitSpecial,
73         DoubleGreaterThanOrUnordered = X86Assembler::ConditionB | DoubleConditionBitInvert,
74         DoubleGreaterThanOrEqualOrUnordered = X86Assembler::ConditionBE | DoubleConditionBitInvert,
75         DoubleLessThanOrUnordered = X86Assembler::ConditionB,
76         DoubleLessThanOrEqualOrUnordered = X86Assembler::ConditionBE,
77     };
78     COMPILE_ASSERT(
79         !((X86Assembler::ConditionE | X86Assembler::ConditionNE | X86Assembler::ConditionA | X86Assembler::ConditionAE | X86Assembler::ConditionB | X86Assembler::ConditionBE) & DoubleConditionBits),
80         DoubleConditionBits_should_not_interfere_with_X86Assembler_Condition_codes);
81 
82     static const RegisterID stackPointerRegister = X86Registers::esp;
83 
84     // Integer arithmetic operations:
85     //
86     // Operations are typically two operand - operation(source, srcDst)
87     // For many operations the source may be an Imm32, the srcDst operand
88     // may often be a memory location (explictly described using an Address
89     // object).
90 
add32(RegisterID src,RegisterID dest)91     void add32(RegisterID src, RegisterID dest)
92     {
93         m_assembler.addl_rr(src, dest);
94     }
95 
add32(Imm32 imm,Address address)96     void add32(Imm32 imm, Address address)
97     {
98         m_assembler.addl_im(imm.m_value, address.offset, address.base);
99     }
100 
add32(Imm32 imm,RegisterID dest)101     void add32(Imm32 imm, RegisterID dest)
102     {
103         m_assembler.addl_ir(imm.m_value, dest);
104     }
105 
add32(Address src,RegisterID dest)106     void add32(Address src, RegisterID dest)
107     {
108         m_assembler.addl_mr(src.offset, src.base, dest);
109     }
110 
add32(RegisterID src,Address dest)111     void add32(RegisterID src, Address dest)
112     {
113         m_assembler.addl_rm(src, dest.offset, dest.base);
114     }
115 
and32(RegisterID src,RegisterID dest)116     void and32(RegisterID src, RegisterID dest)
117     {
118         m_assembler.andl_rr(src, dest);
119     }
120 
and32(Imm32 imm,RegisterID dest)121     void and32(Imm32 imm, RegisterID dest)
122     {
123         m_assembler.andl_ir(imm.m_value, dest);
124     }
125 
and32(RegisterID src,Address dest)126     void and32(RegisterID src, Address dest)
127     {
128         m_assembler.andl_rm(src, dest.offset, dest.base);
129     }
130 
and32(Address src,RegisterID dest)131     void and32(Address src, RegisterID dest)
132     {
133         m_assembler.andl_mr(src.offset, src.base, dest);
134     }
135 
and32(Imm32 imm,Address address)136     void and32(Imm32 imm, Address address)
137     {
138         m_assembler.andl_im(imm.m_value, address.offset, address.base);
139     }
140 
lshift32(Imm32 imm,RegisterID dest)141     void lshift32(Imm32 imm, RegisterID dest)
142     {
143         m_assembler.shll_i8r(imm.m_value, dest);
144     }
145 
lshift32(RegisterID shift_amount,RegisterID dest)146     void lshift32(RegisterID shift_amount, RegisterID dest)
147     {
148         // On x86 we can only shift by ecx; if asked to shift by another register we'll
149         // need rejig the shift amount into ecx first, and restore the registers afterwards.
150         if (shift_amount != X86Registers::ecx) {
151             swap(shift_amount, X86Registers::ecx);
152 
153             // E.g. transform "shll %eax, %eax" -> "xchgl %eax, %ecx; shll %ecx, %ecx; xchgl %eax, %ecx"
154             if (dest == shift_amount)
155                 m_assembler.shll_CLr(X86Registers::ecx);
156             // E.g. transform "shll %eax, %ecx" -> "xchgl %eax, %ecx; shll %ecx, %eax; xchgl %eax, %ecx"
157             else if (dest == X86Registers::ecx)
158                 m_assembler.shll_CLr(shift_amount);
159             // E.g. transform "shll %eax, %ebx" -> "xchgl %eax, %ecx; shll %ecx, %ebx; xchgl %eax, %ecx"
160             else
161                 m_assembler.shll_CLr(dest);
162 
163             swap(shift_amount, X86Registers::ecx);
164         } else
165             m_assembler.shll_CLr(dest);
166     }
167 
mul32(RegisterID src,RegisterID dest)168     void mul32(RegisterID src, RegisterID dest)
169     {
170         m_assembler.imull_rr(src, dest);
171     }
172 
mul32(Address src,RegisterID dest)173     void mul32(Address src, RegisterID dest)
174     {
175         m_assembler.imull_mr(src.offset, src.base, dest);
176     }
177 
mul32(Imm32 imm,RegisterID src,RegisterID dest)178     void mul32(Imm32 imm, RegisterID src, RegisterID dest)
179     {
180         m_assembler.imull_i32r(src, imm.m_value, dest);
181     }
182 
neg32(RegisterID srcDest)183     void neg32(RegisterID srcDest)
184     {
185         m_assembler.negl_r(srcDest);
186     }
187 
neg32(Address srcDest)188     void neg32(Address srcDest)
189     {
190         m_assembler.negl_m(srcDest.offset, srcDest.base);
191     }
192 
not32(RegisterID srcDest)193     void not32(RegisterID srcDest)
194     {
195         m_assembler.notl_r(srcDest);
196     }
197 
not32(Address srcDest)198     void not32(Address srcDest)
199     {
200         m_assembler.notl_m(srcDest.offset, srcDest.base);
201     }
202 
or32(RegisterID src,RegisterID dest)203     void or32(RegisterID src, RegisterID dest)
204     {
205         m_assembler.orl_rr(src, dest);
206     }
207 
or32(Imm32 imm,RegisterID dest)208     void or32(Imm32 imm, RegisterID dest)
209     {
210         m_assembler.orl_ir(imm.m_value, dest);
211     }
212 
or32(RegisterID src,Address dest)213     void or32(RegisterID src, Address dest)
214     {
215         m_assembler.orl_rm(src, dest.offset, dest.base);
216     }
217 
or32(Address src,RegisterID dest)218     void or32(Address src, RegisterID dest)
219     {
220         m_assembler.orl_mr(src.offset, src.base, dest);
221     }
222 
or32(Imm32 imm,Address address)223     void or32(Imm32 imm, Address address)
224     {
225         m_assembler.orl_im(imm.m_value, address.offset, address.base);
226     }
227 
rshift32(RegisterID shift_amount,RegisterID dest)228     void rshift32(RegisterID shift_amount, RegisterID dest)
229     {
230         // On x86 we can only shift by ecx; if asked to shift by another register we'll
231         // need rejig the shift amount into ecx first, and restore the registers afterwards.
232         if (shift_amount != X86Registers::ecx) {
233             swap(shift_amount, X86Registers::ecx);
234 
235             // E.g. transform "shll %eax, %eax" -> "xchgl %eax, %ecx; shll %ecx, %ecx; xchgl %eax, %ecx"
236             if (dest == shift_amount)
237                 m_assembler.sarl_CLr(X86Registers::ecx);
238             // E.g. transform "shll %eax, %ecx" -> "xchgl %eax, %ecx; shll %ecx, %eax; xchgl %eax, %ecx"
239             else if (dest == X86Registers::ecx)
240                 m_assembler.sarl_CLr(shift_amount);
241             // E.g. transform "shll %eax, %ebx" -> "xchgl %eax, %ecx; shll %ecx, %ebx; xchgl %eax, %ecx"
242             else
243                 m_assembler.sarl_CLr(dest);
244 
245             swap(shift_amount, X86Registers::ecx);
246         } else
247             m_assembler.sarl_CLr(dest);
248     }
249 
rshift32(Imm32 imm,RegisterID dest)250     void rshift32(Imm32 imm, RegisterID dest)
251     {
252         m_assembler.sarl_i8r(imm.m_value, dest);
253     }
254 
sub32(RegisterID src,RegisterID dest)255     void sub32(RegisterID src, RegisterID dest)
256     {
257         m_assembler.subl_rr(src, dest);
258     }
259 
sub32(Imm32 imm,RegisterID dest)260     void sub32(Imm32 imm, RegisterID dest)
261     {
262         m_assembler.subl_ir(imm.m_value, dest);
263     }
264 
sub32(Imm32 imm,Address address)265     void sub32(Imm32 imm, Address address)
266     {
267         m_assembler.subl_im(imm.m_value, address.offset, address.base);
268     }
269 
sub32(Address src,RegisterID dest)270     void sub32(Address src, RegisterID dest)
271     {
272         m_assembler.subl_mr(src.offset, src.base, dest);
273     }
274 
sub32(RegisterID src,Address dest)275     void sub32(RegisterID src, Address dest)
276     {
277         m_assembler.subl_rm(src, dest.offset, dest.base);
278     }
279 
280 
xor32(RegisterID src,RegisterID dest)281     void xor32(RegisterID src, RegisterID dest)
282     {
283         m_assembler.xorl_rr(src, dest);
284     }
285 
xor32(Imm32 imm,Address dest)286     void xor32(Imm32 imm, Address dest)
287     {
288         m_assembler.xorl_im(imm.m_value, dest.offset, dest.base);
289     }
290 
xor32(Imm32 imm,RegisterID dest)291     void xor32(Imm32 imm, RegisterID dest)
292     {
293         m_assembler.xorl_ir(imm.m_value, dest);
294     }
295 
xor32(RegisterID src,Address dest)296     void xor32(RegisterID src, Address dest)
297     {
298         m_assembler.xorl_rm(src, dest.offset, dest.base);
299     }
300 
xor32(Address src,RegisterID dest)301     void xor32(Address src, RegisterID dest)
302     {
303         m_assembler.xorl_mr(src.offset, src.base, dest);
304     }
305 
306 
307     // Memory access operations:
308     //
309     // Loads are of the form load(address, destination) and stores of the form
310     // store(source, address).  The source for a store may be an Imm32.  Address
311     // operand objects to loads and store will be implicitly constructed if a
312     // register is passed.
313 
load32(ImplicitAddress address,RegisterID dest)314     void load32(ImplicitAddress address, RegisterID dest)
315     {
316         m_assembler.movl_mr(address.offset, address.base, dest);
317     }
318 
load32(BaseIndex address,RegisterID dest)319     void load32(BaseIndex address, RegisterID dest)
320     {
321         m_assembler.movl_mr(address.offset, address.base, address.index, address.scale, dest);
322     }
323 
load32WithUnalignedHalfWords(BaseIndex address,RegisterID dest)324     void load32WithUnalignedHalfWords(BaseIndex address, RegisterID dest)
325     {
326         load32(address, dest);
327     }
328 
load32WithAddressOffsetPatch(Address address,RegisterID dest)329     DataLabel32 load32WithAddressOffsetPatch(Address address, RegisterID dest)
330     {
331         m_assembler.movl_mr_disp32(address.offset, address.base, dest);
332         return DataLabel32(this);
333     }
334 
load16(BaseIndex address,RegisterID dest)335     void load16(BaseIndex address, RegisterID dest)
336     {
337         m_assembler.movzwl_mr(address.offset, address.base, address.index, address.scale, dest);
338     }
339 
store32WithAddressOffsetPatch(RegisterID src,Address address)340     DataLabel32 store32WithAddressOffsetPatch(RegisterID src, Address address)
341     {
342         m_assembler.movl_rm_disp32(src, address.offset, address.base);
343         return DataLabel32(this);
344     }
345 
store32(RegisterID src,ImplicitAddress address)346     void store32(RegisterID src, ImplicitAddress address)
347     {
348         m_assembler.movl_rm(src, address.offset, address.base);
349     }
350 
store32(RegisterID src,BaseIndex address)351     void store32(RegisterID src, BaseIndex address)
352     {
353         m_assembler.movl_rm(src, address.offset, address.base, address.index, address.scale);
354     }
355 
store32(Imm32 imm,ImplicitAddress address)356     void store32(Imm32 imm, ImplicitAddress address)
357     {
358         m_assembler.movl_i32m(imm.m_value, address.offset, address.base);
359     }
360 
361 
362     // Floating-point operation:
363     //
364     // Presently only supports SSE, not x87 floating point.
365 
loadDouble(ImplicitAddress address,FPRegisterID dest)366     void loadDouble(ImplicitAddress address, FPRegisterID dest)
367     {
368         ASSERT(isSSE2Present());
369         m_assembler.movsd_mr(address.offset, address.base, dest);
370     }
371 
storeDouble(FPRegisterID src,ImplicitAddress address)372     void storeDouble(FPRegisterID src, ImplicitAddress address)
373     {
374         ASSERT(isSSE2Present());
375         m_assembler.movsd_rm(src, address.offset, address.base);
376     }
377 
addDouble(FPRegisterID src,FPRegisterID dest)378     void addDouble(FPRegisterID src, FPRegisterID dest)
379     {
380         ASSERT(isSSE2Present());
381         m_assembler.addsd_rr(src, dest);
382     }
383 
addDouble(Address src,FPRegisterID dest)384     void addDouble(Address src, FPRegisterID dest)
385     {
386         ASSERT(isSSE2Present());
387         m_assembler.addsd_mr(src.offset, src.base, dest);
388     }
389 
divDouble(FPRegisterID src,FPRegisterID dest)390     void divDouble(FPRegisterID src, FPRegisterID dest)
391     {
392         ASSERT(isSSE2Present());
393         m_assembler.divsd_rr(src, dest);
394     }
395 
divDouble(Address src,FPRegisterID dest)396     void divDouble(Address src, FPRegisterID dest)
397     {
398         ASSERT(isSSE2Present());
399         m_assembler.divsd_mr(src.offset, src.base, dest);
400     }
401 
subDouble(FPRegisterID src,FPRegisterID dest)402     void subDouble(FPRegisterID src, FPRegisterID dest)
403     {
404         ASSERT(isSSE2Present());
405         m_assembler.subsd_rr(src, dest);
406     }
407 
subDouble(Address src,FPRegisterID dest)408     void subDouble(Address src, FPRegisterID dest)
409     {
410         ASSERT(isSSE2Present());
411         m_assembler.subsd_mr(src.offset, src.base, dest);
412     }
413 
mulDouble(FPRegisterID src,FPRegisterID dest)414     void mulDouble(FPRegisterID src, FPRegisterID dest)
415     {
416         ASSERT(isSSE2Present());
417         m_assembler.mulsd_rr(src, dest);
418     }
419 
mulDouble(Address src,FPRegisterID dest)420     void mulDouble(Address src, FPRegisterID dest)
421     {
422         ASSERT(isSSE2Present());
423         m_assembler.mulsd_mr(src.offset, src.base, dest);
424     }
425 
convertInt32ToDouble(RegisterID src,FPRegisterID dest)426     void convertInt32ToDouble(RegisterID src, FPRegisterID dest)
427     {
428         ASSERT(isSSE2Present());
429         m_assembler.cvtsi2sd_rr(src, dest);
430     }
431 
convertInt32ToDouble(Address src,FPRegisterID dest)432     void convertInt32ToDouble(Address src, FPRegisterID dest)
433     {
434         ASSERT(isSSE2Present());
435         m_assembler.cvtsi2sd_mr(src.offset, src.base, dest);
436     }
437 
branchDouble(DoubleCondition cond,FPRegisterID left,FPRegisterID right)438     Jump branchDouble(DoubleCondition cond, FPRegisterID left, FPRegisterID right)
439     {
440         ASSERT(isSSE2Present());
441 
442         if (cond & DoubleConditionBitInvert)
443             m_assembler.ucomisd_rr(left, right);
444         else
445             m_assembler.ucomisd_rr(right, left);
446 
447         if (cond == DoubleEqual) {
448             Jump isUnordered(m_assembler.jp());
449             Jump result = Jump(m_assembler.je());
450             isUnordered.link(this);
451             return result;
452         } else if (cond == DoubleNotEqualOrUnordered) {
453             Jump isUnordered(m_assembler.jp());
454             Jump isEqual(m_assembler.je());
455             isUnordered.link(this);
456             Jump result = jump();
457             isEqual.link(this);
458             return result;
459         }
460 
461         ASSERT(!(cond & DoubleConditionBitSpecial));
462         return Jump(m_assembler.jCC(static_cast<X86Assembler::Condition>(cond & ~DoubleConditionBits)));
463     }
464 
465     // Truncates 'src' to an integer, and places the resulting 'dest'.
466     // If the result is not representable as a 32 bit value, branch.
467     // May also branch for some values that are representable in 32 bits
468     // (specifically, in this case, INT_MIN).
branchTruncateDoubleToInt32(FPRegisterID src,RegisterID dest)469     Jump branchTruncateDoubleToInt32(FPRegisterID src, RegisterID dest)
470     {
471         ASSERT(isSSE2Present());
472         m_assembler.cvttsd2si_rr(src, dest);
473         return branch32(Equal, dest, Imm32(0x80000000));
474     }
475 
476     // Convert 'src' to an integer, and places the resulting 'dest'.
477     // If the result is not representable as a 32 bit value, branch.
478     // May also branch for some values that are representable in 32 bits
479     // (specifically, in this case, 0).
branchConvertDoubleToInt32(FPRegisterID src,RegisterID dest,JumpList & failureCases,FPRegisterID fpTemp)480     void branchConvertDoubleToInt32(FPRegisterID src, RegisterID dest, JumpList& failureCases, FPRegisterID fpTemp)
481     {
482         ASSERT(isSSE2Present());
483         m_assembler.cvttsd2si_rr(src, dest);
484 
485         // If the result is zero, it might have been -0.0, and the double comparison won't catch this!
486         failureCases.append(branchTest32(Zero, dest));
487 
488         // Convert the integer result back to float & compare to the original value - if not equal or unordered (NaN) then jump.
489         convertInt32ToDouble(dest, fpTemp);
490         m_assembler.ucomisd_rr(fpTemp, src);
491         failureCases.append(m_assembler.jp());
492         failureCases.append(m_assembler.jne());
493     }
494 
zeroDouble(FPRegisterID srcDest)495     void zeroDouble(FPRegisterID srcDest)
496     {
497         ASSERT(isSSE2Present());
498         m_assembler.xorpd_rr(srcDest, srcDest);
499     }
500 
501 
502     // Stack manipulation operations:
503     //
504     // The ABI is assumed to provide a stack abstraction to memory,
505     // containing machine word sized units of data.  Push and pop
506     // operations add and remove a single register sized unit of data
507     // to or from the stack.  Peek and poke operations read or write
508     // values on the stack, without moving the current stack position.
509 
pop(RegisterID dest)510     void pop(RegisterID dest)
511     {
512         m_assembler.pop_r(dest);
513     }
514 
push(RegisterID src)515     void push(RegisterID src)
516     {
517         m_assembler.push_r(src);
518     }
519 
push(Address address)520     void push(Address address)
521     {
522         m_assembler.push_m(address.offset, address.base);
523     }
524 
push(Imm32 imm)525     void push(Imm32 imm)
526     {
527         m_assembler.push_i32(imm.m_value);
528     }
529 
530 
531     // Register move operations:
532     //
533     // Move values in registers.
534 
move(Imm32 imm,RegisterID dest)535     void move(Imm32 imm, RegisterID dest)
536     {
537         // Note: on 64-bit the Imm32 value is zero extended into the register, it
538         // may be useful to have a separate version that sign extends the value?
539         if (!imm.m_value)
540             m_assembler.xorl_rr(dest, dest);
541         else
542             m_assembler.movl_i32r(imm.m_value, dest);
543     }
544 
545 #if CPU(X86_64)
move(RegisterID src,RegisterID dest)546     void move(RegisterID src, RegisterID dest)
547     {
548         // Note: on 64-bit this is is a full register move; perhaps it would be
549         // useful to have separate move32 & movePtr, with move32 zero extending?
550         if (src != dest)
551             m_assembler.movq_rr(src, dest);
552     }
553 
move(ImmPtr imm,RegisterID dest)554     void move(ImmPtr imm, RegisterID dest)
555     {
556         m_assembler.movq_i64r(imm.asIntptr(), dest);
557     }
558 
swap(RegisterID reg1,RegisterID reg2)559     void swap(RegisterID reg1, RegisterID reg2)
560     {
561         if (reg1 != reg2)
562             m_assembler.xchgq_rr(reg1, reg2);
563     }
564 
signExtend32ToPtr(RegisterID src,RegisterID dest)565     void signExtend32ToPtr(RegisterID src, RegisterID dest)
566     {
567         m_assembler.movsxd_rr(src, dest);
568     }
569 
zeroExtend32ToPtr(RegisterID src,RegisterID dest)570     void zeroExtend32ToPtr(RegisterID src, RegisterID dest)
571     {
572         m_assembler.movl_rr(src, dest);
573     }
574 #else
move(RegisterID src,RegisterID dest)575     void move(RegisterID src, RegisterID dest)
576     {
577         if (src != dest)
578             m_assembler.movl_rr(src, dest);
579     }
580 
move(ImmPtr imm,RegisterID dest)581     void move(ImmPtr imm, RegisterID dest)
582     {
583         m_assembler.movl_i32r(imm.asIntptr(), dest);
584     }
585 
swap(RegisterID reg1,RegisterID reg2)586     void swap(RegisterID reg1, RegisterID reg2)
587     {
588         if (reg1 != reg2)
589             m_assembler.xchgl_rr(reg1, reg2);
590     }
591 
signExtend32ToPtr(RegisterID src,RegisterID dest)592     void signExtend32ToPtr(RegisterID src, RegisterID dest)
593     {
594         move(src, dest);
595     }
596 
zeroExtend32ToPtr(RegisterID src,RegisterID dest)597     void zeroExtend32ToPtr(RegisterID src, RegisterID dest)
598     {
599         move(src, dest);
600     }
601 #endif
602 
603 
604     // Forwards / external control flow operations:
605     //
606     // This set of jump and conditional branch operations return a Jump
607     // object which may linked at a later point, allow forwards jump,
608     // or jumps that will require external linkage (after the code has been
609     // relocated).
610     //
611     // For branches, signed <, >, <= and >= are denoted as l, g, le, and ge
612     // respecitvely, for unsigned comparisons the names b, a, be, and ae are
613     // used (representing the names 'below' and 'above').
614     //
615     // Operands to the comparision are provided in the expected order, e.g.
616     // jle32(reg1, Imm32(5)) will branch if the value held in reg1, when
617     // treated as a signed 32bit value, is less than or equal to 5.
618     //
619     // jz and jnz test whether the first operand is equal to zero, and take
620     // an optional second operand of a mask under which to perform the test.
621 
622 public:
branch32(Condition cond,RegisterID left,RegisterID right)623     Jump branch32(Condition cond, RegisterID left, RegisterID right)
624     {
625         m_assembler.cmpl_rr(right, left);
626         return Jump(m_assembler.jCC(x86Condition(cond)));
627     }
628 
branch32(Condition cond,RegisterID left,Imm32 right)629     Jump branch32(Condition cond, RegisterID left, Imm32 right)
630     {
631         if (((cond == Equal) || (cond == NotEqual)) && !right.m_value)
632             m_assembler.testl_rr(left, left);
633         else
634             m_assembler.cmpl_ir(right.m_value, left);
635         return Jump(m_assembler.jCC(x86Condition(cond)));
636     }
637 
branch32(Condition cond,RegisterID left,Address right)638     Jump branch32(Condition cond, RegisterID left, Address right)
639     {
640         m_assembler.cmpl_mr(right.offset, right.base, left);
641         return Jump(m_assembler.jCC(x86Condition(cond)));
642     }
643 
branch32(Condition cond,Address left,RegisterID right)644     Jump branch32(Condition cond, Address left, RegisterID right)
645     {
646         m_assembler.cmpl_rm(right, left.offset, left.base);
647         return Jump(m_assembler.jCC(x86Condition(cond)));
648     }
649 
branch32(Condition cond,Address left,Imm32 right)650     Jump branch32(Condition cond, Address left, Imm32 right)
651     {
652         m_assembler.cmpl_im(right.m_value, left.offset, left.base);
653         return Jump(m_assembler.jCC(x86Condition(cond)));
654     }
655 
branch32(Condition cond,BaseIndex left,Imm32 right)656     Jump branch32(Condition cond, BaseIndex left, Imm32 right)
657     {
658         m_assembler.cmpl_im(right.m_value, left.offset, left.base, left.index, left.scale);
659         return Jump(m_assembler.jCC(x86Condition(cond)));
660     }
661 
branch32WithUnalignedHalfWords(Condition cond,BaseIndex left,Imm32 right)662     Jump branch32WithUnalignedHalfWords(Condition cond, BaseIndex left, Imm32 right)
663     {
664         return branch32(cond, left, right);
665     }
666 
branch16(Condition cond,BaseIndex left,RegisterID right)667     Jump branch16(Condition cond, BaseIndex left, RegisterID right)
668     {
669         m_assembler.cmpw_rm(right, left.offset, left.base, left.index, left.scale);
670         return Jump(m_assembler.jCC(x86Condition(cond)));
671     }
672 
branch16(Condition cond,BaseIndex left,Imm32 right)673     Jump branch16(Condition cond, BaseIndex left, Imm32 right)
674     {
675         ASSERT(!(right.m_value & 0xFFFF0000));
676 
677         m_assembler.cmpw_im(right.m_value, left.offset, left.base, left.index, left.scale);
678         return Jump(m_assembler.jCC(x86Condition(cond)));
679     }
680 
branchTest32(Condition cond,RegisterID reg,RegisterID mask)681     Jump branchTest32(Condition cond, RegisterID reg, RegisterID mask)
682     {
683         ASSERT((cond == Zero) || (cond == NonZero));
684         m_assembler.testl_rr(reg, mask);
685         return Jump(m_assembler.jCC(x86Condition(cond)));
686     }
687 
688     Jump branchTest32(Condition cond, RegisterID reg, Imm32 mask = Imm32(-1))
689     {
690         ASSERT((cond == Zero) || (cond == NonZero));
691         // if we are only interested in the low seven bits, this can be tested with a testb
692         if (mask.m_value == -1)
693             m_assembler.testl_rr(reg, reg);
694         else if ((mask.m_value & ~0x7f) == 0)
695             m_assembler.testb_i8r(mask.m_value, reg);
696         else
697             m_assembler.testl_i32r(mask.m_value, reg);
698         return Jump(m_assembler.jCC(x86Condition(cond)));
699     }
700 
701     Jump branchTest32(Condition cond, Address address, Imm32 mask = Imm32(-1))
702     {
703         ASSERT((cond == Zero) || (cond == NonZero));
704         if (mask.m_value == -1)
705             m_assembler.cmpl_im(0, address.offset, address.base);
706         else
707             m_assembler.testl_i32m(mask.m_value, address.offset, address.base);
708         return Jump(m_assembler.jCC(x86Condition(cond)));
709     }
710 
711     Jump branchTest32(Condition cond, BaseIndex address, Imm32 mask = Imm32(-1))
712     {
713         ASSERT((cond == Zero) || (cond == NonZero));
714         if (mask.m_value == -1)
715             m_assembler.cmpl_im(0, address.offset, address.base, address.index, address.scale);
716         else
717             m_assembler.testl_i32m(mask.m_value, address.offset, address.base, address.index, address.scale);
718         return Jump(m_assembler.jCC(x86Condition(cond)));
719     }
720 
jump()721     Jump jump()
722     {
723         return Jump(m_assembler.jmp());
724     }
725 
jump(RegisterID target)726     void jump(RegisterID target)
727     {
728         m_assembler.jmp_r(target);
729     }
730 
731     // Address is a memory location containing the address to jump to
jump(Address address)732     void jump(Address address)
733     {
734         m_assembler.jmp_m(address.offset, address.base);
735     }
736 
737 
738     // Arithmetic control flow operations:
739     //
740     // This set of conditional branch operations branch based
741     // on the result of an arithmetic operation.  The operation
742     // is performed as normal, storing the result.
743     //
744     // * jz operations branch if the result is zero.
745     // * jo operations branch if the (signed) arithmetic
746     //   operation caused an overflow to occur.
747 
branchAdd32(Condition cond,RegisterID src,RegisterID dest)748     Jump branchAdd32(Condition cond, RegisterID src, RegisterID dest)
749     {
750         ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
751         add32(src, dest);
752         return Jump(m_assembler.jCC(x86Condition(cond)));
753     }
754 
branchAdd32(Condition cond,Imm32 imm,RegisterID dest)755     Jump branchAdd32(Condition cond, Imm32 imm, RegisterID dest)
756     {
757         ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
758         add32(imm, dest);
759         return Jump(m_assembler.jCC(x86Condition(cond)));
760     }
761 
branchAdd32(Condition cond,Imm32 src,Address dest)762     Jump branchAdd32(Condition cond, Imm32 src, Address dest)
763     {
764         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
765         add32(src, dest);
766         return Jump(m_assembler.jCC(x86Condition(cond)));
767     }
768 
branchAdd32(Condition cond,RegisterID src,Address dest)769     Jump branchAdd32(Condition cond, RegisterID src, Address dest)
770     {
771         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
772         add32(src, dest);
773         return Jump(m_assembler.jCC(x86Condition(cond)));
774     }
775 
branchAdd32(Condition cond,Address src,RegisterID dest)776     Jump branchAdd32(Condition cond, Address src, RegisterID dest)
777     {
778         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
779         add32(src, dest);
780         return Jump(m_assembler.jCC(x86Condition(cond)));
781     }
782 
branchMul32(Condition cond,RegisterID src,RegisterID dest)783     Jump branchMul32(Condition cond, RegisterID src, RegisterID dest)
784     {
785         ASSERT(cond == Overflow);
786         mul32(src, dest);
787         return Jump(m_assembler.jCC(x86Condition(cond)));
788     }
789 
branchMul32(Condition cond,Address src,RegisterID dest)790     Jump branchMul32(Condition cond, Address src, RegisterID dest)
791     {
792         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
793         mul32(src, dest);
794         return Jump(m_assembler.jCC(x86Condition(cond)));
795     }
796 
branchMul32(Condition cond,Imm32 imm,RegisterID src,RegisterID dest)797     Jump branchMul32(Condition cond, Imm32 imm, RegisterID src, RegisterID dest)
798     {
799         ASSERT(cond == Overflow);
800         mul32(imm, src, dest);
801         return Jump(m_assembler.jCC(x86Condition(cond)));
802     }
803 
branchSub32(Condition cond,RegisterID src,RegisterID dest)804     Jump branchSub32(Condition cond, RegisterID src, RegisterID dest)
805     {
806         ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
807         sub32(src, dest);
808         return Jump(m_assembler.jCC(x86Condition(cond)));
809     }
810 
branchSub32(Condition cond,Imm32 imm,RegisterID dest)811     Jump branchSub32(Condition cond, Imm32 imm, RegisterID dest)
812     {
813         ASSERT((cond == Overflow) || (cond == Signed) || (cond == Zero) || (cond == NonZero));
814         sub32(imm, dest);
815         return Jump(m_assembler.jCC(x86Condition(cond)));
816     }
817 
branchSub32(Condition cond,Imm32 imm,Address dest)818     Jump branchSub32(Condition cond, Imm32 imm, Address dest)
819     {
820         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
821         sub32(imm, dest);
822         return Jump(m_assembler.jCC(x86Condition(cond)));
823     }
824 
branchSub32(Condition cond,RegisterID src,Address dest)825     Jump branchSub32(Condition cond, RegisterID src, Address dest)
826     {
827         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
828         sub32(src, dest);
829         return Jump(m_assembler.jCC(x86Condition(cond)));
830     }
831 
branchSub32(Condition cond,Address src,RegisterID dest)832     Jump branchSub32(Condition cond, Address src, RegisterID dest)
833     {
834         ASSERT((cond == Overflow) || (cond == Zero) || (cond == NonZero));
835         sub32(src, dest);
836         return Jump(m_assembler.jCC(x86Condition(cond)));
837     }
838 
branchOr32(Condition cond,RegisterID src,RegisterID dest)839     Jump branchOr32(Condition cond, RegisterID src, RegisterID dest)
840     {
841         ASSERT((cond == Signed) || (cond == Zero) || (cond == NonZero));
842         or32(src, dest);
843         return Jump(m_assembler.jCC(x86Condition(cond)));
844     }
845 
846 
847     // Miscellaneous operations:
848 
breakpoint()849     void breakpoint()
850     {
851         m_assembler.int3();
852     }
853 
nearCall()854     Call nearCall()
855     {
856         return Call(m_assembler.call(), Call::LinkableNear);
857     }
858 
call(RegisterID target)859     Call call(RegisterID target)
860     {
861         return Call(m_assembler.call(target), Call::None);
862     }
863 
call(Address address)864     void call(Address address)
865     {
866         m_assembler.call_m(address.offset, address.base);
867     }
868 
ret()869     void ret()
870     {
871         m_assembler.ret();
872     }
873 
set8(Condition cond,RegisterID left,RegisterID right,RegisterID dest)874     void set8(Condition cond, RegisterID left, RegisterID right, RegisterID dest)
875     {
876         m_assembler.cmpl_rr(right, left);
877         m_assembler.setCC_r(x86Condition(cond), dest);
878     }
879 
set8(Condition cond,Address left,RegisterID right,RegisterID dest)880     void set8(Condition cond, Address left, RegisterID right, RegisterID dest)
881     {
882         m_assembler.cmpl_mr(left.offset, left.base, right);
883         m_assembler.setCC_r(x86Condition(cond), dest);
884     }
885 
set8(Condition cond,RegisterID left,Imm32 right,RegisterID dest)886     void set8(Condition cond, RegisterID left, Imm32 right, RegisterID dest)
887     {
888         if (((cond == Equal) || (cond == NotEqual)) && !right.m_value)
889             m_assembler.testl_rr(left, left);
890         else
891             m_assembler.cmpl_ir(right.m_value, left);
892         m_assembler.setCC_r(x86Condition(cond), dest);
893     }
894 
set32(Condition cond,RegisterID left,RegisterID right,RegisterID dest)895     void set32(Condition cond, RegisterID left, RegisterID right, RegisterID dest)
896     {
897         m_assembler.cmpl_rr(right, left);
898         m_assembler.setCC_r(x86Condition(cond), dest);
899         m_assembler.movzbl_rr(dest, dest);
900     }
901 
set32(Condition cond,RegisterID left,Imm32 right,RegisterID dest)902     void set32(Condition cond, RegisterID left, Imm32 right, RegisterID dest)
903     {
904         if (((cond == Equal) || (cond == NotEqual)) && !right.m_value)
905             m_assembler.testl_rr(left, left);
906         else
907             m_assembler.cmpl_ir(right.m_value, left);
908         m_assembler.setCC_r(x86Condition(cond), dest);
909         m_assembler.movzbl_rr(dest, dest);
910     }
911 
912     // FIXME:
913     // The mask should be optional... paerhaps the argument order should be
914     // dest-src, operations always have a dest? ... possibly not true, considering
915     // asm ops like test, or pseudo ops like pop().
916 
setTest8(Condition cond,Address address,Imm32 mask,RegisterID dest)917     void setTest8(Condition cond, Address address, Imm32 mask, RegisterID dest)
918     {
919         if (mask.m_value == -1)
920             m_assembler.cmpl_im(0, address.offset, address.base);
921         else
922             m_assembler.testl_i32m(mask.m_value, address.offset, address.base);
923         m_assembler.setCC_r(x86Condition(cond), dest);
924     }
925 
setTest32(Condition cond,Address address,Imm32 mask,RegisterID dest)926     void setTest32(Condition cond, Address address, Imm32 mask, RegisterID dest)
927     {
928         if (mask.m_value == -1)
929             m_assembler.cmpl_im(0, address.offset, address.base);
930         else
931             m_assembler.testl_i32m(mask.m_value, address.offset, address.base);
932         m_assembler.setCC_r(x86Condition(cond), dest);
933         m_assembler.movzbl_rr(dest, dest);
934     }
935 
936 protected:
x86Condition(Condition cond)937     X86Assembler::Condition x86Condition(Condition cond)
938     {
939         return static_cast<X86Assembler::Condition>(cond);
940     }
941 
942 private:
943     // Only MacroAssemblerX86 should be using the following method; SSE2 is always available on
944     // x86_64, and clients & subclasses of MacroAssembler should be using 'supportsFloatingPoint()'.
945     friend class MacroAssemblerX86;
946 
947 #if CPU(X86)
948 #if OS(MAC_OS_X)
949 
950     // All X86 Macs are guaranteed to support at least SSE2,
isSSE2Present()951     static bool isSSE2Present()
952     {
953         return true;
954     }
955 
956 #else // OS(MAC_OS_X)
957 
958     enum SSE2CheckState {
959         NotCheckedSSE2,
960         HasSSE2,
961         NoSSE2
962     };
963 
isSSE2Present()964     static bool isSSE2Present()
965     {
966         if (s_sse2CheckState == NotCheckedSSE2) {
967             // Default the flags value to zero; if the compiler is
968             // not MSVC or GCC we will read this as SSE2 not present.
969             int flags = 0;
970 #if COMPILER(MSVC)
971             _asm {
972                 mov eax, 1 // cpuid function 1 gives us the standard feature set
973                 cpuid;
974                 mov flags, edx;
975             }
976 #elif COMPILER(GCC)
977             asm (
978                  "movl $0x1, %%eax;"
979                  "pushl %%ebx;"
980                  "cpuid;"
981                  "popl %%ebx;"
982                  "movl %%edx, %0;"
983                  : "=g" (flags)
984                  :
985                  : "%eax", "%ecx", "%edx"
986                  );
987 #endif
988             static const int SSE2FeatureBit = 1 << 26;
989             s_sse2CheckState = (flags & SSE2FeatureBit) ? HasSSE2 : NoSSE2;
990         }
991         // Only check once.
992         ASSERT(s_sse2CheckState != NotCheckedSSE2);
993 
994         return s_sse2CheckState == HasSSE2;
995     }
996 
997     static SSE2CheckState s_sse2CheckState;
998 
999 #endif // OS(MAC_OS_X)
1000 #elif !defined(NDEBUG) // CPU(X86)
1001 
1002     // On x86-64 we should never be checking for SSE2 in a non-debug build,
1003     // but non debug add this method to keep the asserts above happy.
isSSE2Present()1004     static bool isSSE2Present()
1005     {
1006         return true;
1007     }
1008 
1009 #endif
1010 };
1011 
1012 } // namespace JSC
1013 
1014 #endif // ENABLE(ASSEMBLER)
1015 
1016 #endif // MacroAssemblerX86Common_h
1017