assembler-x64.h revision 3100271588b61cbc1dc472a3f2f105d2eed8497f 
1a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Copyright (c) 1994-2006 Sun Microsystems Inc.
2a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// All Rights Reserved.
3a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
4a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Redistribution and use in source and binary forms, with or without
5a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// modification, are permitted provided that the following conditions are
6a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// met:
7a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
8a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// - Redistributions of source code must retain the above copyright notice,
9a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// this list of conditions and the following disclaimer.
10a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
11a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// - Redistribution in binary form must reproduce the above copyright
12a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// notice, this list of conditions and the following disclaimer in the
13a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// documentation and/or other materials provided with the distribution.
14a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
15a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// - Neither the name of Sun Microsystems or the names of contributors may
16a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// be used to endorse or promote products derived from this software without
17a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// specific prior written permission.
18a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
19a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
20a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
21a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
23a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
24a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
25a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
26a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
27a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
28a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
29a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
30a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
31a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// The original source code covered by the above license above has been
32a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// modified significantly by Google Inc.
33a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Copyright 2006-2009 the V8 project authors. All rights reserved.
34a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
35a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// A lightweight X64 Assembler.
36a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
37a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#ifndef V8_X64_ASSEMBLER_X64_H_
38a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#define V8_X64_ASSEMBLER_X64_H_
39a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
40d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block#include "serialize.h"
41d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
42a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blocknamespace v8 {
43a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blocknamespace internal {
44a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
45a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Utility functions
46a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
47a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Test whether a 64-bit value is in a specific range.
48a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstatic inline bool is_uint32(int64_t x) {
49a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const int64_t kUInt32Mask = V8_INT64_C(0xffffffff);
50a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  return x == (x & kUInt32Mask);
51a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
52a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
53a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstatic inline bool is_int32(int64_t x) {
54a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const int64_t kMinIntValue = V8_INT64_C(-0x80000000);
55a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  return is_uint32(x - kMinIntValue);
56a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
57a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
58a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstatic inline bool uint_is_int32(uint64_t x) {
59a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const uint64_t kMaxIntValue = V8_UINT64_C(0x80000000);
60a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  return x < kMaxIntValue;
61a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
62a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
63a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstatic inline bool is_uint32(uint64_t x) {
64a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const uint64_t kMaxUIntValue = V8_UINT64_C(0x100000000);
65a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  return x < kMaxUIntValue;
66a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
67a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
68a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// CPU Registers.
69a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
70a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// 1) We would prefer to use an enum, but enum values are assignment-
71a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// compatible with int, which has caused code-generation bugs.
72a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
73a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// 2) We would prefer to use a class instead of a struct but we don't like
74a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// the register initialization to depend on the particular initialization
75a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// order (which appears to be different on OS X, Linux, and Windows for the
76a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// installed versions of C++ we tried). Using a struct permits C-style
77a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// "initialization". Also, the Register objects cannot be const as this
78a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// forces initialization stubs in MSVC, making us dependent on initialization
79a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// order.
80a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
81a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// 3) By not using an enum, we are possibly preventing the compiler from
82a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// doing certain constant folds, which may significantly reduce the
83a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// code generated for some assembly instructions (because they boil down
84a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// to a few constants). If this is a problem, we could change the code
85a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// such that we use an enum in optimized mode, and the struct in debug
86a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// mode. This way we get the compile-time error checking in debug mode
87a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// and best performance in optimized code.
88a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//
89a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
90a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstruct Register {
91a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static Register toRegister(int code) {
92a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    Register r = { code };
93a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return r;
94a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
95a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  bool is_valid() const  { return 0 <= code_ && code_ < 16; }
96a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  bool is(Register reg) const  { return code_ == reg.code_; }
97a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code() const  {
98a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ASSERT(is_valid());
99a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_;
100a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
101a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int bit() const  {
102a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return 1 << code_;
103a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
104a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
105a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Return the high bit of the register code as a 0 or 1.  Used often
106a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // when constructing the REX prefix byte.
107a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int high_bit() const {
108a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_ >> 3;
109a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
110a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Return the 3 low bits of the register code.  Used when encoding registers
111a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // in modR/M, SIB, and opcode bytes.
112a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int low_bits() const {
113a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_ & 0x7;
114a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
115a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1163100271588b61cbc1dc472a3f2f105d2eed8497fAndrei Popescu  // Unfortunately we can't make this private in a struct when initializing
1173100271588b61cbc1dc472a3f2f105d2eed8497fAndrei Popescu  // by assignment.
118a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code_;
119a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
120a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
121a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rax;
122a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rcx;
123a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rdx;
124a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rbx;
125a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rsp;
126a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rbp;
127a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rsi;
128a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register rdi;
129a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r8;
130a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r9;
131a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r10;
132a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r11;
133a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r12;
134a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r13;
135a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r14;
136a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register r15;
137a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern Register no_reg;
138a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
139a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
140a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstruct MMXRegister {
141a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  bool is_valid() const  { return 0 <= code_ && code_ < 2; }
142a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code() const  {
143a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ASSERT(is_valid());
144a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_;
145a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
146a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
147a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code_;
148a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
149a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
150a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm0;
151a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm1;
152a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm2;
153a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm3;
154a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm4;
155a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm5;
156a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm6;
157a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm7;
158a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm8;
159a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm9;
160a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm10;
161a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm11;
162a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm12;
163a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm13;
164a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm14;
165a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern MMXRegister mm15;
166a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
167a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
168a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockstruct XMMRegister {
169a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  bool is_valid() const  { return 0 <= code_ && code_ < 16; }
170a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code() const  {
171a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ASSERT(is_valid());
172a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_;
173a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
174a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
175a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Return the high bit of the register code as a 0 or 1.  Used often
176a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // when constructing the REX prefix byte.
177a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int high_bit() const {
178a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_ >> 3;
179a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
180a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Return the 3 low bits of the register code.  Used when encoding registers
181a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // in modR/M, SIB, and opcode bytes.
182a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int low_bits() const {
183a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return code_ & 0x7;
184a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
185a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
186a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int code_;
187a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
188a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
189a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm0;
190a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm1;
191a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm2;
192a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm3;
193a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm4;
194a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm5;
195a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm6;
196a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm7;
197a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm8;
198a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm9;
199a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm10;
200a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm11;
201a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm12;
202a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm13;
203a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm14;
204a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockextern XMMRegister xmm15;
205a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
206a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockenum Condition {
207a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // any value < 0 is considered no_condition
208a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  no_condition  = -1,
209a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
210a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  overflow      =  0,
211a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  no_overflow   =  1,
212a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  below         =  2,
213a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  above_equal   =  3,
214a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  equal         =  4,
215a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  not_equal     =  5,
216a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  below_equal   =  6,
217a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  above         =  7,
218a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  negative      =  8,
219a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  positive      =  9,
220a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  parity_even   = 10,
221a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  parity_odd    = 11,
222a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  less          = 12,
223a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  greater_equal = 13,
224a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  less_equal    = 14,
225a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  greater       = 15,
226a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
2273ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Fake conditions that are handled by the
2283ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // opcodes using them.
2293ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  always        = 16,
2303ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  never         = 17,
231a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // aliases
232a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  carry         = below,
233a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  not_carry     = above_equal,
234a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  zero          = equal,
235a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  not_zero      = not_equal,
236a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  sign          = negative,
2373ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  not_sign      = positive,
2383ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  last_condition = greater
239a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
240a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
241a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
242a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Returns the equivalent of !cc.
243a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Negation of the default no_condition (-1) results in a non-default
244a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// no_condition value (-2). As long as tests for no_condition check
245a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// for condition < 0, this will work as expected.
246a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockinline Condition NegateCondition(Condition cc);
247a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
248a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Corresponds to transposing the operands of a comparison.
249a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockinline Condition ReverseCondition(Condition cc) {
250a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  switch (cc) {
251a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case below:
252a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return above;
253a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case above:
254a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return below;
255a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case above_equal:
256a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return below_equal;
257a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case below_equal:
258a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return above_equal;
259a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case less:
260a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return greater;
261a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case greater:
262a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return less;
263a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case greater_equal:
264a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return less_equal;
265a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    case less_equal:
266a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return greater_equal;
267a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    default:
268a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      return cc;
269a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  };
270a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
271a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
272a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockenum Hint {
273a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  no_hint = 0,
274a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  not_taken = 0x2e,
275a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  taken = 0x3e
276a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
277a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
278a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// The result of negating a hint is as if the corresponding condition
279a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// were negated by NegateCondition.  That is, no_hint is mapped to
280a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// itself and not_taken and taken are mapped to each other.
281a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockinline Hint NegateHint(Hint hint) {
282a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  return (hint == no_hint)
283a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      ? no_hint
284a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      : ((hint == not_taken) ? taken : not_taken);
285a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block}
286a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
287a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
288a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// -----------------------------------------------------------------------------
289a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Machine instruction Immediates
290a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
291a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockclass Immediate BASE_EMBEDDED {
292a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block public:
293a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  explicit Immediate(int32_t value) : value_(value) {}
294a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
295a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
296a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int32_t value_;
297a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
298a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  friend class Assembler;
299a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
300a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
301a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
302a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// -----------------------------------------------------------------------------
303a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Machine instruction Operands
304a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
305a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockenum ScaleFactor {
306a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_1 = 0,
307a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_2 = 1,
308a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_4 = 2,
309a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_8 = 3,
310a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_int_size = times_4,
311a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_half_pointer_size = times_4,
312a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  times_pointer_size = times_8
313a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
314a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
315a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
316a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockclass Operand BASE_EMBEDDED {
317a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block public:
318a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // [base + disp/r]
319a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  Operand(Register base, int32_t disp);
320a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
321a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // [base + index*scale + disp/r]
322a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  Operand(Register base,
323a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block          Register index,
324a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block          ScaleFactor scale,
325a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block          int32_t disp);
326a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
327a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // [index*scale + disp/r]
328a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  Operand(Register index,
329a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block          ScaleFactor scale,
330a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block          int32_t disp);
331a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
332a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
333a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte rex_;
334a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte buf_[10];
335a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The number of bytes in buf_.
336a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  unsigned int len_;
337a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  RelocInfo::Mode rmode_;
338a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
339a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Set the ModR/M byte without an encoded 'reg' register. The
340a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // register is encoded later as part of the emit_operand operation.
341a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // set_modrm can be called before or after set_sib and set_disp*.
342a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void set_modrm(int mod, Register rm);
343a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
344a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Set the SIB byte if one is needed. Sets the length to 2 rather than 1.
345a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void set_sib(ScaleFactor scale, Register index, Register base);
346a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
347a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Adds operand displacement fields (offsets added to the memory address).
348a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Needs to be called after set_sib, not before it.
349a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void set_disp8(int disp);
350a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void set_disp32(int disp);
351a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
352a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  friend class Assembler;
353a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
354a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
355a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
356a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// CpuFeatures keeps track of which features are supported by the target CPU.
357a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Supported features must be enabled by a Scope before use.
358a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Example:
359a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//   if (CpuFeatures::IsSupported(SSE3)) {
360a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//     CpuFeatures::Scope fscope(SSE3);
361a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//     // Generate SSE3 floating point code.
362a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//   } else {
363a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//     // Generate standard x87 or SSE2 floating point code.
364a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block//   }
365a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockclass CpuFeatures : public AllStatic {
366a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block public:
367a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Detect features of the target CPU. Set safe defaults if the serializer
368a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is enabled (snapshots must be portable).
369a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static void Probe();
370a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Check whether a feature is supported by the target CPU.
371d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static bool IsSupported(CpuFeature f) {
3723ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    if (f == SSE2 && !FLAG_enable_sse2) return false;
3733ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    if (f == SSE3 && !FLAG_enable_sse3) return false;
3743ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    if (f == CMOV && !FLAG_enable_cmov) return false;
3753ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    if (f == RDTSC && !FLAG_enable_rdtsc) return false;
3763ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    if (f == SAHF && !FLAG_enable_sahf) return false;
377a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return (supported_ & (V8_UINT64_C(1) << f)) != 0;
378a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
379a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Check whether a feature is currently enabled.
380d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static bool IsEnabled(CpuFeature f) {
381a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return (enabled_ & (V8_UINT64_C(1) << f)) != 0;
382a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
383a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Enable a specified feature within a scope.
384a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  class Scope BASE_EMBEDDED {
385a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#ifdef DEBUG
386a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block   public:
387d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    explicit Scope(CpuFeature f) {
388d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block      uint64_t mask = (V8_UINT64_C(1) << f);
389a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      ASSERT(CpuFeatures::IsSupported(f));
390d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block      ASSERT(!Serializer::enabled() || (found_by_runtime_probing_ & mask) == 0);
391a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      old_enabled_ = CpuFeatures::enabled_;
392d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block      CpuFeatures::enabled_ |= mask;
393a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    }
394a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ~Scope() { CpuFeatures::enabled_ = old_enabled_; }
395a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block   private:
396a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    uint64_t old_enabled_;
397a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#else
398a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block   public:
399d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    explicit Scope(CpuFeature f) {}
400a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#endif
401a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  };
402a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
403a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Safe defaults include SSE2 and CMOV for X64. It is always available, if
404a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // anyone checks, but they shouldn't need to check.
405d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static const uint64_t kDefaultCpuFeatures = (1 << SSE2 | 1 << CMOV);
406a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static uint64_t supported_;
407a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static uint64_t enabled_;
408d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static uint64_t found_by_runtime_probing_;
409a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
410a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
411a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
412a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockclass Assembler : public Malloced {
413a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
414a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // We check before assembling an instruction that there is sufficient
415a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // space to write an instruction and its relocation information.
416a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The relocation writer's position must be kGap bytes above the end of
417a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the generated instructions. This leaves enough space for the
418a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // longest possible x64 instruction, 15 bytes, and the longest possible
419a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // relocation information encoding, RelocInfoWriter::kMaxLength == 16.
420a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // (There is a 15 byte limit on x64 instruction length that rules out some
421a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // otherwise valid instructions.)
422a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // This allows for a single, fast space check per instruction.
423a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const int kGap = 32;
424a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
425a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block public:
426a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Create an assembler. Instructions and relocation information are emitted
427a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // into a buffer, with the instructions starting from the beginning and the
428a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // relocation information starting from the end of the buffer. See CodeDesc
429a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // for a detailed comment on the layout (globals.h).
430a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
431a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // If the provided buffer is NULL, the assembler allocates and grows its own
432a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // buffer, and buffer_size determines the initial buffer size. The buffer is
433a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // owned by the assembler and deallocated upon destruction of the assembler.
434a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
435a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // If the provided buffer is not NULL, the assembler uses the provided buffer
436a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // for code generation and assumes its size to be buffer_size. If the buffer
437a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is too small, a fatal error occurs. No deallocation of the buffer is done
438a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // upon destruction of the assembler.
439a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  Assembler(void* buffer, int buffer_size);
440a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  ~Assembler();
441a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
442a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // GetCode emits any pending (non-emitted) code and fills the descriptor
443a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // desc. GetCode() is idempotent; it returns the same result if no other
444a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Assembler functions are invoked in between GetCode() calls.
445a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void GetCode(CodeDesc* desc);
446a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
4473ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Read/Modify the code target in the relative branch/call instruction at pc.
4483ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // On the x64 architecture, we use relative jumps with a 32-bit displacement
4493ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // to jump to other Code objects in the Code space in the heap.
4503ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Jumps to C functions are done indirectly through a 64-bit register holding
4513ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // the absolute address of the target.
4523ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // These functions convert between absolute Addresses of Code objects and
4533ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // the relative displacements stored in the code.
454a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static inline Address target_address_at(Address pc);
455a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static inline void set_target_address_at(Address pc, Address target);
456d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
457d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // This sets the branch destination (which is in the instruction on x64).
458d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // This is for calls and branches within generated code.
459d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  inline static void set_target_at(Address instruction_payload,
460d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block                                   Address target) {
461d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    set_target_address_at(instruction_payload, target);
462d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  }
463d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
464d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // This sets the branch destination (which is a load instruction on x64).
465d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // This is for calls and branches to runtime code.
466d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  inline static void set_external_target_at(Address instruction_payload,
467d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block                                            Address target) {
468d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    *reinterpret_cast<Address*>(instruction_payload) = target;
469d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  }
470d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
4713ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  inline Handle<Object> code_target_object_handle_at(Address pc);
472d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // Number of bytes taken up by the branch target in the code.
473d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static const int kCallTargetSize = 4;      // Use 32-bit displacement.
474d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static const int kExternalTargetSize = 8;  // Use 64-bit absolute.
475a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Distance between the address of the code target in the call instruction
4763ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // and the return address pushed on the stack.
4773ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  static const int kCallTargetAddressOffset = 4;  // Use 32-bit displacement.
4783ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Distance between the start of the JS return sequence and where the
4793ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // 32-bit displacement of a near call would be, relative to the pushed
4803ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // return address.  TODO: Use return sequence length instead.
4813ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Should equal Debug::kX64JSReturnSequenceLength - kCallTargetAddressOffset;
4823ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  static const int kPatchReturnSequenceAddressOffset = 13 - 4;
4833ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // TODO(X64): Rename this, removing the "Real", after changing the above.
4843ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  static const int kRealPatchReturnSequenceAddressOffset = 2;
485d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
486d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // The x64 JS return sequence is padded with int3 to make it large
487d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  // enough to hold a call instruction when the debugger patches it.
488d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static const int kCallInstructionLength = 13;
489d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  static const int kJSReturnSequenceLength = 13;
490d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block
491a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // ---------------------------------------------------------------------------
492a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Code generation
493a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
494a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Function names correspond one-to-one to x64 instruction mnemonics.
495a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Unless specified otherwise, instructions operate on 64-bit operands.
496a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
497a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // If we need versions of an assembly instruction that operate on different
498a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // width arguments, we add a single-letter suffix specifying the width.
499a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // This is done for the following instructions: mov, cmp, inc, dec,
500a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // add, sub, and test.
501a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // There are no versions of these instructions without the suffix.
502a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // - Instructions on 8-bit (byte) operands/registers have a trailing 'b'.
503a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // - Instructions on 16-bit (word) operands/registers have a trailing 'w'.
504a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // - Instructions on 32-bit (doubleword) operands/registers use 'l'.
505a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // - Instructions on 64-bit (quadword) operands/registers use 'q'.
506a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
507a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Some mnemonics, such as "and", are the same as C++ keywords.
508a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Naming conflicts with C++ keywords are resolved by adding a trailing '_'.
509a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
510a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Insert the smallest number of nop instructions
511a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // possible to align the pc offset to a multiple
512a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // of m. m must be a power of 2.
513a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void Align(int m);
514a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
515a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Stack
516a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void pushfq();
517a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void popfq();
518a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
519a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void push(Immediate value);
520a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void push(Register src);
521a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void push(const Operand& src);
522a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void push(Label* label, RelocInfo::Mode relocation_mode);
523a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
524a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void pop(Register dst);
525a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void pop(const Operand& dst);
526a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
527a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void enter(Immediate size);
528a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void leave();
529a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
530a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Moves
531a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movb(Register dst, const Operand& src);
532a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movb(Register dst, Immediate imm);
533a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movb(const Operand& dst, Register src);
534a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
5353ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Move the low 16 bits of a 64-bit register value to a 16-bit
5363ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // memory location.
5373ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void movw(const Operand& dst, Register src);
5383ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
539a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(Register dst, Register src);
540a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(Register dst, const Operand& src);
541a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(const Operand& dst, Register src);
542a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(const Operand& dst, Immediate imm);
543a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Load a 32-bit immediate value, zero-extended to 64 bits.
544a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(Register dst, Immediate imm32);
545a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
546a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Move 64 bit register value to 64-bit memory location.
547a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(const Operand& dst, Register src);
548a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Move 64 bit memory location to 64-bit register value.
549a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, const Operand& src);
550a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, Register src);
551a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Sign extends immediate 32-bit value to 64 bits.
552a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, Immediate x);
553a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Move the offset of the label location relative to the current
554a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // position (after the move) to the destination.
555a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movl(const Operand& dst, Label* src);
556a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
557a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Move sign extended immediate to memory location.
558a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(const Operand& dst, Immediate value);
559a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // New x64 instructions to load a 64-bit immediate into a register.
560a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // All 64-bit immediates must have a relocation mode.
561a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, void* ptr, RelocInfo::Mode rmode);
562a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, int64_t value, RelocInfo::Mode rmode);
563a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, const char* s, RelocInfo::Mode rmode);
564a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Moves the address of the external reference into the register.
565a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, ExternalReference ext);
566a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movq(Register dst, Handle<Object> handle, RelocInfo::Mode rmode);
567a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
5683ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void movsxbq(Register dst, const Operand& src);
5693ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void movsxwq(Register dst, const Operand& src);
570a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movsxlq(Register dst, Register src);
571a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movsxlq(Register dst, const Operand& src);
572a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movzxbq(Register dst, const Operand& src);
573a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movzxbl(Register dst, const Operand& src);
5743ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void movzxwq(Register dst, const Operand& src);
575a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movzxwl(Register dst, const Operand& src);
576a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
577d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  // Repeated moves.
578d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke
579d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  void repmovsb();
580d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  void repmovsw();
581d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  void repmovsl();
582d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  void repmovsq();
583d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke
584a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // New x64 instruction to load from an immediate 64-bit pointer into RAX.
585a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void load_rax(void* ptr, RelocInfo::Mode rmode);
586a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void load_rax(ExternalReference ext);
587a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
588a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Conditional moves.
589a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmovq(Condition cc, Register dst, Register src);
590a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmovq(Condition cc, Register dst, const Operand& src);
591a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmovl(Condition cc, Register dst, Register src);
592a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmovl(Condition cc, Register dst, const Operand& src);
593a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
594a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Exchange two registers
595a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xchg(Register dst, Register src);
596a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
597a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Arithmetics
598a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addl(Register dst, Register src) {
599a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    if (dst.low_bits() == 4) {  // Forces SIB byte.
600a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      arithmetic_op_32(0x01, src, dst);
601a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    } else {
602a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block      arithmetic_op_32(0x03, dst, src);
603a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    }
604a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
605a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
606a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addl(Register dst, Immediate src) {
607a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x0, dst, src);
608a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
609a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
610a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addl(Register dst, const Operand& src) {
611a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x03, dst, src);
612a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
613a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
614a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addl(const Operand& dst, Immediate src) {
615a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x0, dst, src);
616a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
617a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
618a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addq(Register dst, Register src) {
619a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x03, dst, src);
620a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
621a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
622a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addq(Register dst, const Operand& src) {
623a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x03, dst, src);
624a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
625a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
626a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addq(const Operand& dst, Register src) {
627a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x01, src, dst);
628a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
629a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
630a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addq(Register dst, Immediate src) {
631a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x0, dst, src);
632a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
633a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
634a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addq(const Operand& dst, Immediate src) {
635a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x0, dst, src);
636a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
637a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
638a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb(Register dst, Immediate src) {
639a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_8(0x7, dst, src);
640a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
641a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
642a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb_al(Immediate src);
643a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
644a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb(Register dst, Register src) {
645a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x3A, dst, src);
646a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
647a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
648a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb(Register dst, const Operand& src) {
649a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x3A, dst, src);
650a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
651a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
652a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb(const Operand& dst, Register src) {
653a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x38, src, dst);
654a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
655a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
656a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpb(const Operand& dst, Immediate src) {
657a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_8(0x7, dst, src);
658a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
659a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
660a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpw(const Operand& dst, Immediate src) {
661a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_16(0x7, dst, src);
662a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
663a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
664a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpw(Register dst, Immediate src) {
665a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_16(0x7, dst, src);
666a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
667a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
668a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpw(Register dst, const Operand& src) {
669a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_16(0x3B, dst, src);
670a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
671a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
672a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpw(Register dst, Register src) {
673a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_16(0x3B, dst, src);
674a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
675a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
676a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpw(const Operand& dst, Register src) {
677a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_16(0x39, src, dst);
678a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
679a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
680a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpl(Register dst, Register src) {
681a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x3B, dst, src);
682a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
683a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
684a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpl(Register dst, const Operand& src) {
685a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x3B, dst, src);
686a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
687a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
688a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpl(const Operand& dst, Register src) {
689a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x39, src, dst);
690a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
691a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
692a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpl(Register dst, Immediate src) {
693a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x7, dst, src);
694a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
695a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
696a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpl(const Operand& dst, Immediate src) {
697a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x7, dst, src);
698a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
699a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
700a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpq(Register dst, Register src) {
701a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x3B, dst, src);
702a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
703a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
704a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpq(Register dst, const Operand& src) {
705a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x3B, dst, src);
706a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
707a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
708a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpq(const Operand& dst, Register src) {
709a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x39, src, dst);
710a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
711a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
712a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpq(Register dst, Immediate src) {
713a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x7, dst, src);
714a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
715a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
716a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cmpq(const Operand& dst, Immediate src) {
717a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x7, dst, src);
718a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
719a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
720a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void and_(Register dst, Register src) {
721a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x23, dst, src);
722a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
723a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
724a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void and_(Register dst, const Operand& src) {
725a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x23, dst, src);
726a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
727a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
728a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void and_(const Operand& dst, Register src) {
729a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x21, src, dst);
730a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
731a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
732a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void and_(Register dst, Immediate src) {
733a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x4, dst, src);
734a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
735a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
736a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void and_(const Operand& dst, Immediate src) {
737a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x4, dst, src);
738a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
739a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
740a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void andl(Register dst, Immediate src) {
741a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x4, dst, src);
742a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
743a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
7443ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void andl(Register dst, Register src) {
7453ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    arithmetic_op_32(0x23, dst, src);
7463ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
7473ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
7484515c472dc3e5ed2448a564600976759e569a0a8Leon Clarke  void andb(Register dst, Immediate src) {
7494515c472dc3e5ed2448a564600976759e569a0a8Leon Clarke    immediate_arithmetic_op_8(0x4, dst, src);
7504515c472dc3e5ed2448a564600976759e569a0a8Leon Clarke  }
7513ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
752a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void decq(Register dst);
753a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void decq(const Operand& dst);
754a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void decl(Register dst);
755a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void decl(const Operand& dst);
7563ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void decb(Register dst);
7573ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void decb(const Operand& dst);
758a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
759a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Sign-extends rax into rdx:rax.
760a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cqo();
761a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Sign-extends eax into edx:eax.
762a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cdq();
763a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
764a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Divide rdx:rax by src.  Quotient in rax, remainder in rdx.
765a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void idivq(Register src);
766a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Divide edx:eax by lower 32 bits of src.  Quotient in eax, rem. in edx.
767a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void idivl(Register src);
768a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
769a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Signed multiply instructions.
770a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void imul(Register src);                               // rdx:rax = rax * src.
771a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void imul(Register dst, Register src);                 // dst = dst * src.
772a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void imul(Register dst, const Operand& src);           // dst = dst * src.
773a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void imul(Register dst, Register src, Immediate imm);  // dst = src * imm.
774a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Multiply 32 bit registers
775a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void imull(Register dst, Register src);                // dst = dst * src.
776a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
777a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void incq(Register dst);
778a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void incq(const Operand& dst);
779a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void incl(const Operand& dst);
780a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
781a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void lea(Register dst, const Operand& src);
782a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
783a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Multiply rax by src, put the result in rdx:rax.
784a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void mul(Register src);
785a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
786a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void neg(Register dst);
787a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void neg(const Operand& dst);
788a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void negl(Register dst);
789a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
790a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void not_(Register dst);
791a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void not_(const Operand& dst);
792a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
793a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void or_(Register dst, Register src) {
794a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x0B, dst, src);
795a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
796a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
797a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void orl(Register dst, Register src) {
798a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x0B, dst, src);
799a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
800a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
801a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void or_(Register dst, const Operand& src) {
802a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x0B, dst, src);
803a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
804a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
805a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void or_(const Operand& dst, Register src) {
806a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x09, src, dst);
807a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
808a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
809a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void or_(Register dst, Immediate src) {
810a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x1, dst, src);
811a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
812a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
8133ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void orl(Register dst, Immediate src) {
8143ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    immediate_arithmetic_op_32(0x1, dst, src);
8153ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
8163ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
817a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void or_(const Operand& dst, Immediate src) {
818a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x1, dst, src);
819a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
820a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
8213ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void orl(const Operand& dst, Immediate src) {
8223ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    immediate_arithmetic_op_32(0x1, dst, src);
8233ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
8243ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
825a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
8263ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void rcl(Register dst, Immediate imm8) {
8273ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    shift(dst, imm8, 0x2);
8283ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
8293ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
8303ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void rol(Register dst, Immediate imm8) {
8313ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    shift(dst, imm8, 0x0);
8323ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
8333ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
8343ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void rcr(Register dst, Immediate imm8) {
8353ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    shift(dst, imm8, 0x3);
8363ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
8373ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
8383ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void ror(Register dst, Immediate imm8) {
8393ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block    shift(dst, imm8, 0x1);
8403ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  }
841a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
842a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts dst:src left by cl bits, affecting only dst.
843a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shld(Register dst, Register src);
844a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
845a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts src:dst right by cl bits, affecting only dst.
846a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shrd(Register dst, Register src);
847a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
848a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts dst right, duplicating sign bit, by shift_amount bits.
849a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifting by 1 is handled efficiently.
850a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void sar(Register dst, Immediate shift_amount) {
851a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, shift_amount, 0x7);
852a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
853a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
854a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts dst right, duplicating sign bit, by shift_amount bits.
855a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifting by 1 is handled efficiently.
856a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void sarl(Register dst, Immediate shift_amount) {
857a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, shift_amount, 0x7);
858a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
859a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
860a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts dst right, duplicating sign bit, by cl % 64 bits.
861d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void sar_cl(Register dst) {
862a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, 0x7);
863a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
864a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
865a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shifts dst right, duplicating sign bit, by cl % 64 bits.
866d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void sarl_cl(Register dst) {
867a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, 0x7);
868a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
869a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
870a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shl(Register dst, Immediate shift_amount) {
871a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, shift_amount, 0x4);
872a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
873a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
874d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void shl_cl(Register dst) {
875a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, 0x4);
876a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
877a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
878d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void shll_cl(Register dst) {
879a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, 0x4);
880a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
881a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
882a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shll(Register dst, Immediate shift_amount) {
883a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, shift_amount, 0x4);
884a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
885a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
886a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shr(Register dst, Immediate shift_amount) {
887a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, shift_amount, 0x5);
888a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
889a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
890d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void shr_cl(Register dst) {
891a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift(dst, 0x5);
892a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
893a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
894d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  void shrl_cl(Register dst) {
895a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, 0x5);
896a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
897a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
898a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shrl(Register dst, Immediate shift_amount) {
899a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    shift_32(dst, shift_amount, 0x5);
900a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
901a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
902a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void store_rax(void* dst, RelocInfo::Mode mode);
903a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void store_rax(ExternalReference ref);
904a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
905a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subq(Register dst, Register src) {
906a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x2B, dst, src);
907a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
908a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
909a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subq(Register dst, const Operand& src) {
910a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x2B, dst, src);
911a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
912a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
913a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subq(const Operand& dst, Register src) {
914a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x29, src, dst);
915a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
916a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
917a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subq(Register dst, Immediate src) {
918a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x5, dst, src);
919a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
920a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
921a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subq(const Operand& dst, Immediate src) {
922a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x5, dst, src);
923a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
924a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
925a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subl(Register dst, Register src) {
926a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x2B, dst, src);
927a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
928a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
929e46be819fca9468a0cd4e74859ce0f778eb8ca60Leon Clarke  void subl(Register dst, const Operand& src) {
930e46be819fca9468a0cd4e74859ce0f778eb8ca60Leon Clarke    arithmetic_op_32(0x2B, dst, src);
931e46be819fca9468a0cd4e74859ce0f778eb8ca60Leon Clarke  }
932e46be819fca9468a0cd4e74859ce0f778eb8ca60Leon Clarke
933a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subl(const Operand& dst, Immediate src) {
934a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x5, dst, src);
935a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
936a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
937a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subl(Register dst, Immediate src) {
938a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_32(0x5, dst, src);
939a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
940a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
941a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subb(Register dst, Immediate src) {
942a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op_8(0x5, dst, src);
943a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
944a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
9453ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void testb(Register dst, Register src);
946a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testb(Register reg, Immediate mask);
947a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testb(const Operand& op, Immediate mask);
948e46be819fca9468a0cd4e74859ce0f778eb8ca60Leon Clarke  void testb(const Operand& op, Register reg);
949a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testl(Register dst, Register src);
950a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testl(Register reg, Immediate mask);
951a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testl(const Operand& op, Immediate mask);
952a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testq(const Operand& op, Register reg);
953a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testq(Register dst, Register src);
954a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void testq(Register dst, Immediate mask);
955a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
956a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xor_(Register dst, Register src) {
957d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    if (dst.code() == src.code()) {
958d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block      arithmetic_op_32(0x33, dst, src);
959d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    } else {
960d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block      arithmetic_op(0x33, dst, src);
961d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    }
962a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
963a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
964a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xorl(Register dst, Register src) {
965a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op_32(0x33, dst, src);
966a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
967a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
968a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xor_(Register dst, const Operand& src) {
969a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x33, dst, src);
970a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
971a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
972a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xor_(const Operand& dst, Register src) {
973a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    arithmetic_op(0x31, src, dst);
974a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
975a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
976a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xor_(Register dst, Immediate src) {
977a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x6, dst, src);
978a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
979a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
980a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void xor_(const Operand& dst, Immediate src) {
981a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    immediate_arithmetic_op(0x6, dst, src);
982a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
983a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
984a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Bit operations.
985a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void bt(const Operand& dst, Register src);
986a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void bts(const Operand& dst, Register src);
987a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
988a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Miscellaneous
9893ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void clc();
990a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cpuid();
991a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void hlt();
992a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void int3();
993a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void nop();
994a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void nop(int n);
995a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void rdtsc();
996a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void ret(int imm16);
997a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void setcc(Condition cc, Register reg);
998a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
999a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Label operations & relative jumps (PPUM Appendix D)
1000a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
1001a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Takes a branch opcode (cc) and a label (L) and generates
1002a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // either a backward branch or a forward branch and links it
1003a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // to the label fixup chain. Usage:
1004a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
1005a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Label L;    // unbound label
1006a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // j(cc, &L);  // forward branch to unbound label
1007a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // bind(&L);   // bind label to the current pc
1008a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // j(cc, &L);  // backward branch to bound label
1009a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // bind(&L);   // illegal: a label may be bound only once
1010a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  //
1011a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Note: The same Label can be used for forward and backward branches
1012a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // but it may be bound only once.
1013a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1014a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void bind(Label* L);  // binds an unbound label L to the current code position
1015a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1016a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Calls
1017a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Call near relative 32-bit displacement, relative to next instruction.
1018a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void call(Label* L);
10193ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void call(Handle<Code> target, RelocInfo::Mode rmode);
1020a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1021a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Call near absolute indirect, address in register
1022a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void call(Register adr);
1023a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1024a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Call near indirect
1025a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void call(const Operand& operand);
1026a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1027a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Jumps
1028a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Jump short or near relative.
10293ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  // Use a 32-bit signed displacement.
1030a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void jmp(Label* L);  // unconditional jump to L
10313ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void jmp(Handle<Code> target, RelocInfo::Mode rmode);
1032a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1033a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Jump near absolute indirect (r64)
1034a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void jmp(Register adr);
1035a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1036a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Jump near absolute indirect (m64)
1037a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void jmp(const Operand& src);
1038a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1039a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Conditional jumps
1040a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void j(Condition cc, Label* L);
10413ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void j(Condition cc, Handle<Code> target, RelocInfo::Mode rmode);
1042a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1043a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Floating-point operations
1044a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fld(int i);
1045a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1046a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fld1();
1047a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fldz();
1048a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1049a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fld_s(const Operand& adr);
1050a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fld_d(const Operand& adr);
1051a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1052a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fstp_s(const Operand& adr);
1053a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fstp_d(const Operand& adr);
10543ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void fstp(int index);
1055a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1056a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fild_s(const Operand& adr);
1057a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fild_d(const Operand& adr);
1058a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1059a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fist_s(const Operand& adr);
1060a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1061a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fistp_s(const Operand& adr);
1062a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fistp_d(const Operand& adr);
1063a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1064a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fisttp_s(const Operand& adr);
1065d91b9f7d46489a9ee00f9cb415630299c76a502bLeon Clarke  void fisttp_d(const Operand& adr);
1066a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1067a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fabs();
1068a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fchs();
1069a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1070a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fadd(int i);
1071a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fsub(int i);
1072a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fmul(int i);
1073a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fdiv(int i);
1074a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1075a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fisub_s(const Operand& adr);
1076a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1077a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void faddp(int i = 1);
1078a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fsubp(int i = 1);
1079a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fsubrp(int i = 1);
1080a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fmulp(int i = 1);
1081a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fdivp(int i = 1);
1082a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fprem();
1083a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fprem1();
1084a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1085a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fxch(int i = 1);
1086a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fincstp();
1087a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void ffree(int i = 0);
1088a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1089a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void ftst();
1090a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fucomp(int i);
1091a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fucompp();
10923ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void fucomi(int i);
10933ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void fucomip();
10943ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block
1095a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fcompp();
1096a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fnstsw_ax();
1097a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fwait();
1098a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fnclex();
1099a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1100a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fsin();
1101a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void fcos();
1102a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1103a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void frndint();
1104a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1105a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void sahf();
1106a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1107a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // SSE2 instructions
1108a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movsd(const Operand& dst, XMMRegister src);
11093ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  void movsd(XMMRegister src, XMMRegister dst);
1110a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void movsd(XMMRegister src, const Operand& dst);
1111a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1112a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvttss2si(Register dst, const Operand& src);
1113a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvttsd2si(Register dst, const Operand& src);
1114a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1115a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvtlsi2sd(XMMRegister dst, const Operand& src);
1116a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvtlsi2sd(XMMRegister dst, Register src);
1117a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvtqsi2sd(XMMRegister dst, const Operand& src);
1118a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void cvtqsi2sd(XMMRegister dst, Register src);
1119a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1120a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void addsd(XMMRegister dst, XMMRegister src);
1121a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void subsd(XMMRegister dst, XMMRegister src);
1122a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void mulsd(XMMRegister dst, XMMRegister src);
1123a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void divsd(XMMRegister dst, XMMRegister src);
1124a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1125a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1126a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_sse_operand(XMMRegister dst, XMMRegister src);
1127a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_sse_operand(XMMRegister reg, const Operand& adr);
1128a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_sse_operand(XMMRegister dst, Register src);
1129a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1130a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Use either movsd or movlpd.
1131a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void movdbl(XMMRegister dst, const Operand& src);
1132a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void movdbl(const Operand& dst, XMMRegister src);
1133a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1134a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Debugging
1135a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void Print();
1136a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1137a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Check the code size generated from label to here.
1138a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int SizeOfCodeGeneratedSince(Label* l) { return pc_offset() - l->pos(); }
1139a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1140a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Mark address of the ExitJSFrame code.
1141a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void RecordJSReturn();
1142a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1143a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Record a comment relocation entry that can be used by a disassembler.
1144a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Use --debug_code to enable.
1145a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void RecordComment(const char* msg);
1146a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1147a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void RecordPosition(int pos);
1148a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void RecordStatementPosition(int pos);
1149a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void WriteRecordedPositions();
1150a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1151d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  int pc_offset() const  { return static_cast<int>(pc_ - buffer_); }
1152a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int current_statement_position() const { return current_statement_position_; }
1153a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int current_position() const  { return current_position_; }
1154a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1155a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Check if there is less than kGap bytes available in the buffer.
1156a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // If this is the case, we need to grow the buffer before emitting
1157a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // an instruction or relocation information.
1158a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline bool buffer_overflow() const {
1159a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return pc_ >= reloc_info_writer.pos() - kGap;
1160a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1161a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1162a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Get the number of bytes available in the buffer.
1163d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  inline int available_space() const {
1164d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block    return static_cast<int>(reloc_info_writer.pos() - pc_);
1165d0582a6c46733687d045e4188a1bcd0123c758a1Steve Block  }
1166a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1167a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Avoid overflows for displacements etc.
1168a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const int kMaximalBufferSize = 512*MB;
1169a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static const int kMinimalBufferSize = 4*KB;
1170a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1171a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block protected:
1172a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void movsd(XMMRegister dst, const Operand& src);
1173a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void movsd(const Operand& dst, XMMRegister src);
1174a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1175a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void emit_sse_operand(XMMRegister reg, const Operand& adr);
1176a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void emit_sse_operand(XMMRegister dst, XMMRegister src);
1177a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1178a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1179a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
1180a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte* addr_at(int pos)  { return buffer_ + pos; }
1181a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte byte_at(int pos)  { return buffer_[pos]; }
1182a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  uint32_t long_at(int pos)  {
1183a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    return *reinterpret_cast<uint32_t*>(addr_at(pos));
1184a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1185a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void long_at_put(int pos, uint32_t x)  {
1186a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    *reinterpret_cast<uint32_t*>(addr_at(pos)) = x;
1187a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1188a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1189a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // code emission
1190a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void GrowBuffer();
1191a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1192a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit(byte x) { *pc_++ = x; }
1193a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emitl(uint32_t x);
1194a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emitq(uint64_t x, RelocInfo::Mode rmode);
1195a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emitw(uint16_t x);
11963ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  inline void emit_code_target(Handle<Code> target, RelocInfo::Mode rmode);
1197a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit(Immediate x) { emitl(x.value_); }
1198a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1199a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emits a REX prefix that encodes a 64-bit operand size and
1200a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the top bit of both register codes.
1201a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // High bit of reg goes to REX.R, high bit of rm_reg goes to REX.B.
1202a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W is set.
1203a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(Register reg, Register rm_reg);
1204a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(XMMRegister reg, Register rm_reg);
1205a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1206a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emits a REX prefix that encodes a 64-bit operand size and
1207a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the top bit of the destination, index, and base register codes.
1208a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The high bit of reg is used for REX.R, the high bit of op's base
1209a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // register is used for REX.B, and the high bit of op's index register
1210a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is used for REX.X.  REX.W is set.
1211a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(Register reg, const Operand& op);
1212a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(XMMRegister reg, const Operand& op);
1213a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1214a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emits a REX prefix that encodes a 64-bit operand size and
1215a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the top bit of the register code.
1216a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The high bit of register is used for REX.B.
1217a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W is set and REX.R and REX.X are clear.
1218a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(Register rm_reg);
1219a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1220a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emits a REX prefix that encodes a 64-bit operand size and
1221a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the top bit of the index and base register codes.
1222a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The high bit of op's base register is used for REX.B, and the high
1223a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // bit of op's index register is used for REX.X.
1224a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W is set and REX.R clear.
1225a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_64(const Operand& op);
1226a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1227a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit a REX prefix that only sets REX.W to choose a 64-bit operand size.
1228a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_rex_64() { emit(0x48); }
1229a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1230a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // High bit of reg goes to REX.R, high bit of rm_reg goes to REX.B.
1231a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W is clear.
1232a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_32(Register reg, Register rm_reg);
1233a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1234a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The high bit of reg is used for REX.R, the high bit of op's base
1235a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // register is used for REX.B, and the high bit of op's index register
1236a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is used for REX.X.  REX.W is cleared.
1237a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_32(Register reg, const Operand& op);
1238a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1239a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // High bit of rm_reg goes to REX.B.
1240a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W, REX.R and REX.X are clear.
1241a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_32(Register rm_reg);
1242a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1243a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // High bit of base goes to REX.B and high bit of index to REX.X.
1244a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W and REX.R are clear.
1245a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_rex_32(const Operand& op);
1246a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1247a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // High bit of reg goes to REX.R, high bit of rm_reg goes to REX.B.
1248a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // REX.W is cleared.  If no REX bits are set, no byte is emitted.
1249a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(Register reg, Register rm_reg);
1250a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1251a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The high bit of reg is used for REX.R, the high bit of op's base
1252a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // register is used for REX.B, and the high bit of op's index register
1253a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is used for REX.X.  REX.W is cleared.  If no REX bits are set, nothing
1254a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // is emitted.
1255a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(Register reg, const Operand& op);
1256a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1257a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // As for emit_optional_rex_32(Register, Register), except that
1258a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the registers are XMM registers.
1259a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(XMMRegister reg, XMMRegister base);
1260a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1261a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // As for emit_optional_rex_32(Register, Register), except that
1262a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the registers are XMM registers.
1263a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(XMMRegister reg, Register base);
1264a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1265a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // As for emit_optional_rex_32(Register, const Operand&), except that
1266a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the register is an XMM register.
1267a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(XMMRegister reg, const Operand& op);
1268a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1269a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Optionally do as emit_rex_32(Register) if the register number has
1270a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the high bit set.
1271a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(Register rm_reg);
1272a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1273a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Optionally do as emit_rex_32(const Operand&) if the operand register
1274a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // numbers have a high bit set.
1275a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_optional_rex_32(const Operand& op);
1276a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1277a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1278a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit the ModR/M byte, and optionally the SIB byte and
1279a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // 1- or 4-byte offset for a memory operand.  Also encodes
1280a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // the second operand of the operation, a register or operation
1281a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // subcode, into the reg field of the ModR/M byte.
1282a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_operand(Register reg, const Operand& adr) {
1283a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    emit_operand(reg.low_bits(), adr);
1284a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1285a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1286a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit the ModR/M byte, and optionally the SIB byte and
1287a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // 1- or 4-byte offset for a memory operand.  Also used to encode
1288a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // a three-bit opcode extension into the ModR/M byte.
1289a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_operand(int rm, const Operand& adr);
1290a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1291a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit a ModR/M byte with registers coded in the reg and rm_reg fields.
1292a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_modrm(Register reg, Register rm_reg) {
1293a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    emit(0xC0 | reg.low_bits() << 3 | rm_reg.low_bits());
1294a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1295a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1296a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit a ModR/M byte with an operation subcode in the reg field and
1297a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // a register in the rm_reg field.
1298a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_modrm(int code, Register rm_reg) {
1299a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ASSERT(is_uint3(code));
1300a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    emit(0xC0 | code << 3 | rm_reg.low_bits());
1301a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1302a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1303a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit the code-object-relative offset of the label's position
1304a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  inline void emit_code_relative_offset(Label* label);
1305a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1306a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit machine code for one of the operations ADD, ADC, SUB, SBC,
1307a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // AND, OR, XOR, or CMP.  The encodings of these operations are all
1308a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // similar, differing just in the opcode or in the reg field of the
1309a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // ModR/M byte.
1310a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op_16(byte opcode, Register reg, Register rm_reg);
1311a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op_16(byte opcode, Register reg, const Operand& rm_reg);
1312a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op_32(byte opcode, Register reg, Register rm_reg);
1313a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op_32(byte opcode, Register reg, const Operand& rm_reg);
1314a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op(byte opcode, Register reg, Register rm_reg);
1315a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void arithmetic_op(byte opcode, Register reg, const Operand& rm_reg);
1316a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op(byte subcode, Register dst, Immediate src);
1317a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op(byte subcode, const Operand& dst, Immediate src);
1318a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Operate on a byte in memory or register.
1319a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_8(byte subcode,
1320a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                 Register dst,
1321a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                 Immediate src);
1322a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_8(byte subcode,
1323a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                 const Operand& dst,
1324a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                 Immediate src);
1325a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Operate on a word in memory or register.
1326a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_16(byte subcode,
1327a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Register dst,
1328a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Immediate src);
1329a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_16(byte subcode,
1330a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  const Operand& dst,
1331a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Immediate src);
1332a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Operate on a 32-bit word in memory or register.
1333a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_32(byte subcode,
1334a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Register dst,
1335a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Immediate src);
1336a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void immediate_arithmetic_op_32(byte subcode,
1337a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  const Operand& dst,
1338a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block                                  Immediate src);
1339a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1340a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Emit machine code for a shift operation.
1341a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shift(Register dst, Immediate shift_amount, int subcode);
1342a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shift_32(Register dst, Immediate shift_amount, int subcode);
1343a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Shift dst by cl % 64 bits.
1344a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shift(Register dst, int subcode);
1345a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void shift_32(Register dst, int subcode);
1346a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1347a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void emit_farith(int b1, int b2, int i);
1348a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1349a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // labels
1350a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // void print(Label* L);
1351a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void bind_to(Label* L, int pos);
1352a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void link_to(Label* L, Label* appendix);
1353a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1354a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // record reloc info for current pc_
1355a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  void RecordRelocInfo(RelocInfo::Mode rmode, intptr_t data = 0);
1356a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1357a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  friend class CodePatcher;
1358a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  friend class EnsureSpace;
1359a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  friend class RegExpMacroAssemblerX64;
1360a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1361a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // Code buffer:
1362a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // The buffer into which code and relocation info are generated.
1363a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte* buffer_;
1364a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int buffer_size_;
1365a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // True if the assembler owns the buffer, false if buffer is external.
1366a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  bool own_buffer_;
1367a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // A previously allocated buffer of kMinimalBufferSize bytes, or NULL.
1368a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  static byte* spare_buffer_;
1369a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1370a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // code generation
1371a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte* pc_;  // the program counter; moves forward
1372a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  RelocInfoWriter reloc_info_writer;
1373a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
13743ce2e2076e8e3e60cf1810eec160ea2d8557e9e7Steve Block  List< Handle<Code> > code_targets_;
1375a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // push-pop elimination
1376a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  byte* last_pc_;
1377a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1378a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  // source position information
1379a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int current_statement_position_;
1380a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int current_position_;
1381a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int written_statement_position_;
1382a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int written_position_;
1383a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
1384a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1385a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1386a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// Helper class that ensures that there is enough space for generating
1387a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// instructions and relocation information.  The constructor makes
1388a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// sure that there is enough space and (in debug mode) the destructor
1389a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block// checks that we did not generate too much.
1390a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Blockclass EnsureSpace BASE_EMBEDDED {
1391a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block public:
1392a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  explicit EnsureSpace(Assembler* assembler) : assembler_(assembler) {
1393a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    if (assembler_->buffer_overflow()) assembler_->GrowBuffer();
1394a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#ifdef DEBUG
1395a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    space_before_ = assembler_->available_space();
1396a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#endif
1397a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1398a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1399a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#ifdef DEBUG
1400a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  ~EnsureSpace() {
1401a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    int bytes_generated = space_before_ - assembler_->available_space();
1402a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block    ASSERT(bytes_generated < assembler_->kGap);
1403a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  }
1404a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#endif
1405a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1406a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block private:
1407a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  Assembler* assembler_;
1408a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#ifdef DEBUG
1409a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block  int space_before_;
1410a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#endif
1411a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block};
1412a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1413a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block} }  // namespace v8::internal
1414a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block
1415a7e24c173cf37484693b9abb38e494fa7bd7baebSteve Block#endif  // V8_X64_ASSEMBLER_X64_H_
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