/src/capstonenext/arch/X86/X86Disassembler.c
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1 | | //===-- X86Disassembler.cpp - Disassembler for x86 and x86_64 -------------===// |
2 | | // |
3 | | // The LLVM Compiler Infrastructure |
4 | | // |
5 | | // This file is distributed under the University of Illinois Open Source |
6 | | // License. See LICENSE.TXT for details. |
7 | | // |
8 | | //===----------------------------------------------------------------------===// |
9 | | // |
10 | | // This file is part of the X86 Disassembler. |
11 | | // It contains code to translate the data produced by the decoder into |
12 | | // MCInsts. |
13 | | // |
14 | | // The X86 disassembler is a table-driven disassembler for the 16-, 32-, and |
15 | | // 64-bit X86 instruction sets. The main decode sequence for an assembly |
16 | | // instruction in this disassembler is: |
17 | | // |
18 | | // 1. Read the prefix bytes and determine the attributes of the instruction. |
19 | | // These attributes, recorded in enum attributeBits |
20 | | // (X86DisassemblerDecoderCommon.h), form a bitmask. The table CONTEXTS_SYM |
21 | | // provides a mapping from bitmasks to contexts, which are represented by |
22 | | // enum InstructionContext (ibid.). |
23 | | // |
24 | | // 2. Read the opcode, and determine what kind of opcode it is. The |
25 | | // disassembler distinguishes four kinds of opcodes, which are enumerated in |
26 | | // OpcodeType (X86DisassemblerDecoderCommon.h): one-byte (0xnn), two-byte |
27 | | // (0x0f 0xnn), three-byte-38 (0x0f 0x38 0xnn), or three-byte-3a |
28 | | // (0x0f 0x3a 0xnn). Mandatory prefixes are treated as part of the context. |
29 | | // |
30 | | // 3. Depending on the opcode type, look in one of four ClassDecision structures |
31 | | // (X86DisassemblerDecoderCommon.h). Use the opcode class to determine which |
32 | | // OpcodeDecision (ibid.) to look the opcode in. Look up the opcode, to get |
33 | | // a ModRMDecision (ibid.). |
34 | | // |
35 | | // 4. Some instructions, such as escape opcodes or extended opcodes, or even |
36 | | // instructions that have ModRM*Reg / ModRM*Mem forms in LLVM, need the |
37 | | // ModR/M byte to complete decode. The ModRMDecision's type is an entry from |
38 | | // ModRMDecisionType (X86DisassemblerDecoderCommon.h) that indicates if the |
39 | | // ModR/M byte is required and how to interpret it. |
40 | | // |
41 | | // 5. After resolving the ModRMDecision, the disassembler has a unique ID |
42 | | // of type InstrUID (X86DisassemblerDecoderCommon.h). Looking this ID up in |
43 | | // INSTRUCTIONS_SYM yields the name of the instruction and the encodings and |
44 | | // meanings of its operands. |
45 | | // |
46 | | // 6. For each operand, its encoding is an entry from OperandEncoding |
47 | | // (X86DisassemblerDecoderCommon.h) and its type is an entry from |
48 | | // OperandType (ibid.). The encoding indicates how to read it from the |
49 | | // instruction; the type indicates how to interpret the value once it has |
50 | | // been read. For example, a register operand could be stored in the R/M |
51 | | // field of the ModR/M byte, the REG field of the ModR/M byte, or added to |
52 | | // the main opcode. This is orthogonal from its meaning (an GPR or an XMM |
53 | | // register, for instance). Given this information, the operands can be |
54 | | // extracted and interpreted. |
55 | | // |
56 | | // 7. As the last step, the disassembler translates the instruction information |
57 | | // and operands into a format understandable by the client - in this case, an |
58 | | // MCInst for use by the MC infrastructure. |
59 | | // |
60 | | // The disassembler is broken broadly into two parts: the table emitter that |
61 | | // emits the instruction decode tables discussed above during compilation, and |
62 | | // the disassembler itself. The table emitter is documented in more detail in |
63 | | // utils/TableGen/X86DisassemblerEmitter.h. |
64 | | // |
65 | | // X86Disassembler.cpp contains the code responsible for step 7, and for |
66 | | // invoking the decoder to execute steps 1-6. |
67 | | // X86DisassemblerDecoderCommon.h contains the definitions needed by both the |
68 | | // table emitter and the disassembler. |
69 | | // X86DisassemblerDecoder.h contains the public interface of the decoder, |
70 | | // factored out into C for possible use by other projects. |
71 | | // X86DisassemblerDecoder.c contains the source code of the decoder, which is |
72 | | // responsible for steps 1-6. |
73 | | // |
74 | | //===----------------------------------------------------------------------===// |
75 | | |
76 | | /* Capstone Disassembly Engine */ |
77 | | /* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2019 */ |
78 | | |
79 | | #ifdef CAPSTONE_HAS_X86 |
80 | | |
81 | | #ifdef _MSC_VER |
82 | | // disable MSVC's warning on strncpy() |
83 | | #pragma warning(disable : 4996) |
84 | | // disable MSVC's warning on strncpy() |
85 | | #pragma warning(disable : 28719) |
86 | | #endif |
87 | | |
88 | | #include <capstone/platform.h> |
89 | | |
90 | | #if defined(CAPSTONE_HAS_OSXKERNEL) |
91 | | #include <Availability.h> |
92 | | #endif |
93 | | |
94 | | #include <string.h> |
95 | | |
96 | | #include "../../cs_priv.h" |
97 | | |
98 | | #include "X86BaseInfo.h" |
99 | | #include "X86Disassembler.h" |
100 | | #include "X86DisassemblerDecoderCommon.h" |
101 | | #include "X86DisassemblerDecoder.h" |
102 | | #include "../../MCInst.h" |
103 | | #include "../../utils.h" |
104 | | #include "X86Mapping.h" |
105 | | |
106 | | #define GET_REGINFO_ENUM |
107 | | #define GET_REGINFO_MC_DESC |
108 | | #include "X86GenRegisterInfo.inc" |
109 | | |
110 | | #define GET_INSTRINFO_ENUM |
111 | | #ifdef CAPSTONE_X86_REDUCE |
112 | | #include "X86GenInstrInfo_reduce.inc" |
113 | | #else |
114 | | #include "X86GenInstrInfo.inc" |
115 | | #endif |
116 | | |
117 | | // Fill-ins to make the compiler happy. These constants are never actually |
118 | | // assigned; they are just filler to make an automatically-generated switch |
119 | | // statement work. |
120 | | enum { |
121 | | X86_BX_SI = 500, |
122 | | X86_BX_DI = 501, |
123 | | X86_BP_SI = 502, |
124 | | X86_BP_DI = 503, |
125 | | X86_sib = 504, |
126 | | X86_sib64 = 505 |
127 | | }; |
128 | | |
129 | | // |
130 | | // Private code that translates from struct InternalInstructions to MCInsts. |
131 | | // |
132 | | |
133 | | /// translateRegister - Translates an internal register to the appropriate LLVM |
134 | | /// register, and appends it as an operand to an MCInst. |
135 | | /// |
136 | | /// @param mcInst - The MCInst to append to. |
137 | | /// @param reg - The Reg to append. |
138 | | static void translateRegister(MCInst *mcInst, Reg reg) |
139 | 62.4k | { |
140 | 13.9M | #define ENTRY(x) X86_##x, |
141 | 62.4k | static const uint16_t llvmRegnums[] = { ALL_REGS 0 }; |
142 | 62.4k | #undef ENTRY |
143 | | |
144 | 62.4k | uint16_t llvmRegnum = llvmRegnums[reg]; |
145 | 62.4k | MCOperand_CreateReg0(mcInst, llvmRegnum); |
146 | 62.4k | } |
147 | | |
148 | | static const uint8_t segmentRegnums[SEG_OVERRIDE_max] = { |
149 | | 0, // SEG_OVERRIDE_NONE |
150 | | X86_CS, X86_SS, X86_DS, X86_ES, X86_FS, X86_GS |
151 | | }; |
152 | | |
153 | | /// translateSrcIndex - Appends a source index operand to an MCInst. |
154 | | /// |
155 | | /// @param mcInst - The MCInst to append to. |
156 | | /// @param insn - The internal instruction. |
157 | | static bool translateSrcIndex(MCInst *mcInst, InternalInstruction *insn) |
158 | 4.42k | { |
159 | 4.42k | unsigned baseRegNo; |
160 | | |
161 | 4.42k | if (insn->mode == MODE_64BIT) |
162 | 1.72k | baseRegNo = insn->hasAdSize ? X86_ESI : X86_RSI; |
163 | 2.69k | else if (insn->mode == MODE_32BIT) |
164 | 687 | baseRegNo = insn->hasAdSize ? X86_SI : X86_ESI; |
165 | 2.00k | else { |
166 | | // assert(insn->mode == MODE_16BIT); |
167 | 2.00k | baseRegNo = insn->hasAdSize ? X86_ESI : X86_SI; |
168 | 2.00k | } |
169 | | |
170 | 4.42k | MCOperand_CreateReg0(mcInst, baseRegNo); |
171 | | |
172 | 4.42k | MCOperand_CreateReg0(mcInst, segmentRegnums[insn->segmentOverride]); |
173 | | |
174 | 4.42k | return false; |
175 | 4.42k | } |
176 | | |
177 | | /// translateDstIndex - Appends a destination index operand to an MCInst. |
178 | | /// |
179 | | /// @param mcInst - The MCInst to append to. |
180 | | /// @param insn - The internal instruction. |
181 | | static bool translateDstIndex(MCInst *mcInst, InternalInstruction *insn) |
182 | 4.95k | { |
183 | 4.95k | unsigned baseRegNo; |
184 | | |
185 | 4.95k | if (insn->mode == MODE_64BIT) |
186 | 1.83k | baseRegNo = insn->hasAdSize ? X86_EDI : X86_RDI; |
187 | 3.11k | else if (insn->mode == MODE_32BIT) |
188 | 1.24k | baseRegNo = insn->hasAdSize ? X86_DI : X86_EDI; |
189 | 1.87k | else { |
190 | | // assert(insn->mode == MODE_16BIT); |
191 | 1.87k | baseRegNo = insn->hasAdSize ? X86_EDI : X86_DI; |
192 | 1.87k | } |
193 | | |
194 | 4.95k | MCOperand_CreateReg0(mcInst, baseRegNo); |
195 | | |
196 | 4.95k | return false; |
197 | 4.95k | } |
198 | | |
199 | | /// translateImmediate - Appends an immediate operand to an MCInst. |
200 | | /// |
201 | | /// @param mcInst - The MCInst to append to. |
202 | | /// @param immediate - The immediate value to append. |
203 | | /// @param operand - The operand, as stored in the descriptor table. |
204 | | /// @param insn - The internal instruction. |
205 | | static void translateImmediate(MCInst *mcInst, uint64_t immediate, |
206 | | const OperandSpecifier *operand, |
207 | | InternalInstruction *insn) |
208 | 24.0k | { |
209 | 24.0k | OperandType type; |
210 | | |
211 | 24.0k | type = (OperandType)operand->type; |
212 | 24.0k | if (type == TYPE_REL) { |
213 | | //isBranch = true; |
214 | | //pcrel = insn->startLocation + insn->immediateOffset + insn->immediateSize; |
215 | 5.75k | switch (operand->encoding) { |
216 | 0 | default: |
217 | 0 | break; |
218 | 125 | case ENCODING_Iv: |
219 | 125 | switch (insn->displacementSize) { |
220 | 0 | default: |
221 | 0 | break; |
222 | 0 | case 1: |
223 | 0 | if (immediate & 0x80) |
224 | 0 | immediate |= ~(0xffull); |
225 | 0 | break; |
226 | 9 | case 2: |
227 | 9 | if (immediate & 0x8000) |
228 | 7 | immediate |= ~(0xffffull); |
229 | 9 | break; |
230 | 116 | case 4: |
231 | 116 | if (immediate & 0x80000000) |
232 | 74 | immediate |= ~(0xffffffffull); |
233 | 116 | break; |
234 | 0 | case 8: |
235 | 0 | break; |
236 | 125 | } |
237 | 125 | break; |
238 | 5.49k | case ENCODING_IB: |
239 | 5.49k | if (immediate & 0x80) |
240 | 1.73k | immediate |= ~(0xffull); |
241 | 5.49k | break; |
242 | 42 | case ENCODING_IW: |
243 | 42 | if (immediate & 0x8000) |
244 | 8 | immediate |= ~(0xffffull); |
245 | 42 | break; |
246 | 94 | case ENCODING_ID: |
247 | 94 | if (immediate & 0x80000000) |
248 | 44 | immediate |= ~(0xffffffffull); |
249 | 94 | break; |
250 | 5.75k | } |
251 | 5.75k | } // By default sign-extend all X86 immediates based on their encoding. |
252 | 18.3k | else if (type == TYPE_IMM) { |
253 | 9.32k | switch (operand->encoding) { |
254 | 2.38k | default: |
255 | 2.38k | break; |
256 | 5.58k | case ENCODING_IB: |
257 | 5.58k | if (immediate & 0x80) |
258 | 1.44k | immediate |= ~(0xffull); |
259 | 5.58k | break; |
260 | 1.00k | case ENCODING_IW: |
261 | 1.00k | if (immediate & 0x8000) |
262 | 494 | immediate |= ~(0xffffull); |
263 | 1.00k | break; |
264 | 195 | case ENCODING_ID: |
265 | 195 | if (immediate & 0x80000000) |
266 | 117 | immediate |= ~(0xffffffffull); |
267 | 195 | break; |
268 | 155 | case ENCODING_IO: |
269 | 155 | break; |
270 | 9.32k | } |
271 | 9.32k | } else if (type == TYPE_IMM3) { |
272 | 1.38k | #ifndef CAPSTONE_X86_REDUCE |
273 | | // Check for immediates that printSSECC can't handle. |
274 | 1.38k | if (immediate >= 8) { |
275 | 651 | unsigned NewOpc = 0; |
276 | | |
277 | 651 | switch (MCInst_getOpcode(mcInst)) { |
278 | 0 | default: |
279 | 0 | break; // never reach |
280 | 0 | case X86_CMPPDrmi: |
281 | 0 | NewOpc = X86_CMPPDrmi_alt; |
282 | 0 | break; |
283 | 0 | case X86_CMPPDrri: |
284 | 0 | NewOpc = X86_CMPPDrri_alt; |
285 | 0 | break; |
286 | 40 | case X86_CMPPSrmi: |
287 | 40 | NewOpc = X86_CMPPSrmi_alt; |
288 | 40 | break; |
289 | 24 | case X86_CMPPSrri: |
290 | 24 | NewOpc = X86_CMPPSrri_alt; |
291 | 24 | break; |
292 | 13 | case X86_CMPSDrm: |
293 | 13 | NewOpc = X86_CMPSDrm_alt; |
294 | 13 | break; |
295 | 14 | case X86_CMPSDrr: |
296 | 14 | NewOpc = X86_CMPSDrr_alt; |
297 | 14 | break; |
298 | 58 | case X86_CMPSSrm: |
299 | 58 | NewOpc = X86_CMPSSrm_alt; |
300 | 58 | break; |
301 | 71 | case X86_CMPSSrr: |
302 | 71 | NewOpc = X86_CMPSSrr_alt; |
303 | 71 | break; |
304 | 17 | case X86_VPCOMBri: |
305 | 17 | NewOpc = X86_VPCOMBri_alt; |
306 | 17 | break; |
307 | 1 | case X86_VPCOMBmi: |
308 | 1 | NewOpc = X86_VPCOMBmi_alt; |
309 | 1 | break; |
310 | 41 | case X86_VPCOMWri: |
311 | 41 | NewOpc = X86_VPCOMWri_alt; |
312 | 41 | break; |
313 | 5 | case X86_VPCOMWmi: |
314 | 5 | NewOpc = X86_VPCOMWmi_alt; |
315 | 5 | break; |
316 | 5 | case X86_VPCOMDri: |
317 | 5 | NewOpc = X86_VPCOMDri_alt; |
318 | 5 | break; |
319 | 30 | case X86_VPCOMDmi: |
320 | 30 | NewOpc = X86_VPCOMDmi_alt; |
321 | 30 | break; |
322 | 1 | case X86_VPCOMQri: |
323 | 1 | NewOpc = X86_VPCOMQri_alt; |
324 | 1 | break; |
325 | 9 | case X86_VPCOMQmi: |
326 | 9 | NewOpc = X86_VPCOMQmi_alt; |
327 | 9 | break; |
328 | 36 | case X86_VPCOMUBri: |
329 | 36 | NewOpc = X86_VPCOMUBri_alt; |
330 | 36 | break; |
331 | 50 | case X86_VPCOMUBmi: |
332 | 50 | NewOpc = X86_VPCOMUBmi_alt; |
333 | 50 | break; |
334 | 35 | case X86_VPCOMUWri: |
335 | 35 | NewOpc = X86_VPCOMUWri_alt; |
336 | 35 | break; |
337 | 26 | case X86_VPCOMUWmi: |
338 | 26 | NewOpc = X86_VPCOMUWmi_alt; |
339 | 26 | break; |
340 | 9 | case X86_VPCOMUDri: |
341 | 9 | NewOpc = X86_VPCOMUDri_alt; |
342 | 9 | break; |
343 | 37 | case X86_VPCOMUDmi: |
344 | 37 | NewOpc = X86_VPCOMUDmi_alt; |
345 | 37 | break; |
346 | 82 | case X86_VPCOMUQri: |
347 | 82 | NewOpc = X86_VPCOMUQri_alt; |
348 | 82 | break; |
349 | 47 | case X86_VPCOMUQmi: |
350 | 47 | NewOpc = X86_VPCOMUQmi_alt; |
351 | 47 | break; |
352 | 651 | } |
353 | | |
354 | | // Switch opcode to the one that doesn't get special printing. |
355 | 651 | if (NewOpc != 0) { |
356 | 651 | MCInst_setOpcode(mcInst, NewOpc); |
357 | 651 | } |
358 | 651 | } |
359 | 1.38k | #endif |
360 | 7.62k | } else if (type == TYPE_IMM5) { |
361 | 1.76k | #ifndef CAPSTONE_X86_REDUCE |
362 | | // Check for immediates that printAVXCC can't handle. |
363 | 1.76k | if (immediate >= 32) { |
364 | 1.41k | unsigned NewOpc = 0; |
365 | | |
366 | 1.41k | switch (MCInst_getOpcode(mcInst)) { |
367 | 364 | default: |
368 | 364 | break; // unexpected opcode |
369 | 364 | case X86_VCMPPDrmi: |
370 | 0 | NewOpc = X86_VCMPPDrmi_alt; |
371 | 0 | break; |
372 | 0 | case X86_VCMPPDrri: |
373 | 0 | NewOpc = X86_VCMPPDrri_alt; |
374 | 0 | break; |
375 | 0 | case X86_VCMPPSrmi: |
376 | 0 | NewOpc = X86_VCMPPSrmi_alt; |
377 | 0 | break; |
378 | 3 | case X86_VCMPPSrri: |
379 | 3 | NewOpc = X86_VCMPPSrri_alt; |
380 | 3 | break; |
381 | 0 | case X86_VCMPSDrm: |
382 | 0 | NewOpc = X86_VCMPSDrm_alt; |
383 | 0 | break; |
384 | 0 | case X86_VCMPSDrr: |
385 | 0 | NewOpc = X86_VCMPSDrr_alt; |
386 | 0 | break; |
387 | 1 | case X86_VCMPSSrm: |
388 | 1 | NewOpc = X86_VCMPSSrm_alt; |
389 | 1 | break; |
390 | 11 | case X86_VCMPSSrr: |
391 | 11 | NewOpc = X86_VCMPSSrr_alt; |
392 | 11 | break; |
393 | 32 | case X86_VCMPPDYrmi: |
394 | 32 | NewOpc = X86_VCMPPDYrmi_alt; |
395 | 32 | break; |
396 | 38 | case X86_VCMPPDYrri: |
397 | 38 | NewOpc = X86_VCMPPDYrri_alt; |
398 | 38 | break; |
399 | 8 | case X86_VCMPPSYrmi: |
400 | 8 | NewOpc = X86_VCMPPSYrmi_alt; |
401 | 8 | break; |
402 | 0 | case X86_VCMPPSYrri: |
403 | 0 | NewOpc = X86_VCMPPSYrri_alt; |
404 | 0 | break; |
405 | 0 | case X86_VCMPPDZrmi: |
406 | 0 | NewOpc = X86_VCMPPDZrmi_alt; |
407 | 0 | break; |
408 | 5 | case X86_VCMPPDZrri: |
409 | 5 | NewOpc = X86_VCMPPDZrri_alt; |
410 | 5 | break; |
411 | 5 | case X86_VCMPPDZrrib: |
412 | 5 | NewOpc = X86_VCMPPDZrrib_alt; |
413 | 5 | break; |
414 | 16 | case X86_VCMPPSZrmi: |
415 | 16 | NewOpc = X86_VCMPPSZrmi_alt; |
416 | 16 | break; |
417 | 123 | case X86_VCMPPSZrri: |
418 | 123 | NewOpc = X86_VCMPPSZrri_alt; |
419 | 123 | break; |
420 | 79 | case X86_VCMPPSZrrib: |
421 | 79 | NewOpc = X86_VCMPPSZrrib_alt; |
422 | 79 | break; |
423 | 16 | case X86_VCMPPDZ128rmi: |
424 | 16 | NewOpc = X86_VCMPPDZ128rmi_alt; |
425 | 16 | break; |
426 | 6 | case X86_VCMPPDZ128rri: |
427 | 6 | NewOpc = X86_VCMPPDZ128rri_alt; |
428 | 6 | break; |
429 | 9 | case X86_VCMPPSZ128rmi: |
430 | 9 | NewOpc = X86_VCMPPSZ128rmi_alt; |
431 | 9 | break; |
432 | 164 | case X86_VCMPPSZ128rri: |
433 | 164 | NewOpc = X86_VCMPPSZ128rri_alt; |
434 | 164 | break; |
435 | 128 | case X86_VCMPPDZ256rmi: |
436 | 128 | NewOpc = X86_VCMPPDZ256rmi_alt; |
437 | 128 | break; |
438 | 1 | case X86_VCMPPDZ256rri: |
439 | 1 | NewOpc = X86_VCMPPDZ256rri_alt; |
440 | 1 | break; |
441 | 60 | case X86_VCMPPSZ256rmi: |
442 | 60 | NewOpc = X86_VCMPPSZ256rmi_alt; |
443 | 60 | break; |
444 | 128 | case X86_VCMPPSZ256rri: |
445 | 128 | NewOpc = X86_VCMPPSZ256rri_alt; |
446 | 128 | break; |
447 | 8 | case X86_VCMPSDZrm_Int: |
448 | 8 | NewOpc = X86_VCMPSDZrmi_alt; |
449 | 8 | break; |
450 | 56 | case X86_VCMPSDZrr_Int: |
451 | 56 | NewOpc = X86_VCMPSDZrri_alt; |
452 | 56 | break; |
453 | 2 | case X86_VCMPSDZrrb_Int: |
454 | 2 | NewOpc = X86_VCMPSDZrrb_alt; |
455 | 2 | break; |
456 | 20 | case X86_VCMPSSZrm_Int: |
457 | 20 | NewOpc = X86_VCMPSSZrmi_alt; |
458 | 20 | break; |
459 | 128 | case X86_VCMPSSZrr_Int: |
460 | 128 | NewOpc = X86_VCMPSSZrri_alt; |
461 | 128 | break; |
462 | 7 | case X86_VCMPSSZrrb_Int: |
463 | 7 | NewOpc = X86_VCMPSSZrrb_alt; |
464 | 7 | break; |
465 | 1.41k | } |
466 | | |
467 | | // Switch opcode to the one that doesn't get special printing. |
468 | 1.41k | if (NewOpc != 0) { |
469 | 1.05k | MCInst_setOpcode(mcInst, NewOpc); |
470 | 1.05k | } |
471 | 1.41k | } |
472 | 1.76k | #endif |
473 | 5.85k | } else if (type == TYPE_AVX512ICC) { |
474 | 804 | #ifndef CAPSTONE_X86_REDUCE |
475 | 804 | if (immediate >= 8 || ((immediate & 0x3) == 3)) { |
476 | 458 | unsigned NewOpc = 0; |
477 | 458 | switch (MCInst_getOpcode(mcInst)) { |
478 | 0 | default: // llvm_unreachable("unexpected opcode"); |
479 | 127 | case X86_VPCMPBZ128rmi: |
480 | 127 | NewOpc = X86_VPCMPBZ128rmi_alt; |
481 | 127 | break; |
482 | 3 | case X86_VPCMPBZ128rmik: |
483 | 3 | NewOpc = X86_VPCMPBZ128rmik_alt; |
484 | 3 | break; |
485 | 12 | case X86_VPCMPBZ128rri: |
486 | 12 | NewOpc = X86_VPCMPBZ128rri_alt; |
487 | 12 | break; |
488 | 28 | case X86_VPCMPBZ128rrik: |
489 | 28 | NewOpc = X86_VPCMPBZ128rrik_alt; |
490 | 28 | break; |
491 | 0 | case X86_VPCMPBZ256rmi: |
492 | 0 | NewOpc = X86_VPCMPBZ256rmi_alt; |
493 | 0 | break; |
494 | 0 | case X86_VPCMPBZ256rmik: |
495 | 0 | NewOpc = X86_VPCMPBZ256rmik_alt; |
496 | 0 | break; |
497 | 0 | case X86_VPCMPBZ256rri: |
498 | 0 | NewOpc = X86_VPCMPBZ256rri_alt; |
499 | 0 | break; |
500 | 0 | case X86_VPCMPBZ256rrik: |
501 | 0 | NewOpc = X86_VPCMPBZ256rrik_alt; |
502 | 0 | break; |
503 | 0 | case X86_VPCMPBZrmi: |
504 | 0 | NewOpc = X86_VPCMPBZrmi_alt; |
505 | 0 | break; |
506 | 2 | case X86_VPCMPBZrmik: |
507 | 2 | NewOpc = X86_VPCMPBZrmik_alt; |
508 | 2 | break; |
509 | 8 | case X86_VPCMPBZrri: |
510 | 8 | NewOpc = X86_VPCMPBZrri_alt; |
511 | 8 | break; |
512 | 6 | case X86_VPCMPBZrrik: |
513 | 6 | NewOpc = X86_VPCMPBZrrik_alt; |
514 | 6 | break; |
515 | 0 | case X86_VPCMPDZ128rmi: |
516 | 0 | NewOpc = X86_VPCMPDZ128rmi_alt; |
517 | 0 | break; |
518 | 0 | case X86_VPCMPDZ128rmib: |
519 | 0 | NewOpc = X86_VPCMPDZ128rmib_alt; |
520 | 0 | break; |
521 | 0 | case X86_VPCMPDZ128rmibk: |
522 | 0 | NewOpc = X86_VPCMPDZ128rmibk_alt; |
523 | 0 | break; |
524 | 103 | case X86_VPCMPDZ128rmik: |
525 | 103 | NewOpc = X86_VPCMPDZ128rmik_alt; |
526 | 103 | break; |
527 | 0 | case X86_VPCMPDZ128rri: |
528 | 0 | NewOpc = X86_VPCMPDZ128rri_alt; |
529 | 0 | break; |
530 | 7 | case X86_VPCMPDZ128rrik: |
531 | 7 | NewOpc = X86_VPCMPDZ128rrik_alt; |
532 | 7 | break; |
533 | 0 | case X86_VPCMPDZ256rmi: |
534 | 0 | NewOpc = X86_VPCMPDZ256rmi_alt; |
535 | 0 | break; |
536 | 0 | case X86_VPCMPDZ256rmib: |
537 | 0 | NewOpc = X86_VPCMPDZ256rmib_alt; |
538 | 0 | break; |
539 | 9 | case X86_VPCMPDZ256rmibk: |
540 | 9 | NewOpc = X86_VPCMPDZ256rmibk_alt; |
541 | 9 | break; |
542 | 0 | case X86_VPCMPDZ256rmik: |
543 | 0 | NewOpc = X86_VPCMPDZ256rmik_alt; |
544 | 0 | break; |
545 | 0 | case X86_VPCMPDZ256rri: |
546 | 0 | NewOpc = X86_VPCMPDZ256rri_alt; |
547 | 0 | break; |
548 | 0 | case X86_VPCMPDZ256rrik: |
549 | 0 | NewOpc = X86_VPCMPDZ256rrik_alt; |
550 | 0 | break; |
551 | 1 | case X86_VPCMPDZrmi: |
552 | 1 | NewOpc = X86_VPCMPDZrmi_alt; |
553 | 1 | break; |
554 | 0 | case X86_VPCMPDZrmib: |
555 | 0 | NewOpc = X86_VPCMPDZrmib_alt; |
556 | 0 | break; |
557 | 16 | case X86_VPCMPDZrmibk: |
558 | 16 | NewOpc = X86_VPCMPDZrmibk_alt; |
559 | 16 | break; |
560 | 0 | case X86_VPCMPDZrmik: |
561 | 0 | NewOpc = X86_VPCMPDZrmik_alt; |
562 | 0 | break; |
563 | 0 | case X86_VPCMPDZrri: |
564 | 0 | NewOpc = X86_VPCMPDZrri_alt; |
565 | 0 | break; |
566 | 0 | case X86_VPCMPDZrrik: |
567 | 0 | NewOpc = X86_VPCMPDZrrik_alt; |
568 | 0 | break; |
569 | 0 | case X86_VPCMPQZ128rmi: |
570 | 0 | NewOpc = X86_VPCMPQZ128rmi_alt; |
571 | 0 | break; |
572 | 0 | case X86_VPCMPQZ128rmib: |
573 | 0 | NewOpc = X86_VPCMPQZ128rmib_alt; |
574 | 0 | break; |
575 | 0 | case X86_VPCMPQZ128rmibk: |
576 | 0 | NewOpc = X86_VPCMPQZ128rmibk_alt; |
577 | 0 | break; |
578 | 0 | case X86_VPCMPQZ128rmik: |
579 | 0 | NewOpc = X86_VPCMPQZ128rmik_alt; |
580 | 0 | break; |
581 | 0 | case X86_VPCMPQZ128rri: |
582 | 0 | NewOpc = X86_VPCMPQZ128rri_alt; |
583 | 0 | break; |
584 | 0 | case X86_VPCMPQZ128rrik: |
585 | 0 | NewOpc = X86_VPCMPQZ128rrik_alt; |
586 | 0 | break; |
587 | 1 | case X86_VPCMPQZ256rmi: |
588 | 1 | NewOpc = X86_VPCMPQZ256rmi_alt; |
589 | 1 | break; |
590 | 0 | case X86_VPCMPQZ256rmib: |
591 | 0 | NewOpc = X86_VPCMPQZ256rmib_alt; |
592 | 0 | break; |
593 | 0 | case X86_VPCMPQZ256rmibk: |
594 | 0 | NewOpc = X86_VPCMPQZ256rmibk_alt; |
595 | 0 | break; |
596 | 0 | case X86_VPCMPQZ256rmik: |
597 | 0 | NewOpc = X86_VPCMPQZ256rmik_alt; |
598 | 0 | break; |
599 | 0 | case X86_VPCMPQZ256rri: |
600 | 0 | NewOpc = X86_VPCMPQZ256rri_alt; |
601 | 0 | break; |
602 | 0 | case X86_VPCMPQZ256rrik: |
603 | 0 | NewOpc = X86_VPCMPQZ256rrik_alt; |
604 | 0 | break; |
605 | 0 | case X86_VPCMPQZrmi: |
606 | 0 | NewOpc = X86_VPCMPQZrmi_alt; |
607 | 0 | break; |
608 | 0 | case X86_VPCMPQZrmib: |
609 | 0 | NewOpc = X86_VPCMPQZrmib_alt; |
610 | 0 | break; |
611 | 0 | case X86_VPCMPQZrmibk: |
612 | 0 | NewOpc = X86_VPCMPQZrmibk_alt; |
613 | 0 | break; |
614 | 0 | case X86_VPCMPQZrmik: |
615 | 0 | NewOpc = X86_VPCMPQZrmik_alt; |
616 | 0 | break; |
617 | 0 | case X86_VPCMPQZrri: |
618 | 0 | NewOpc = X86_VPCMPQZrri_alt; |
619 | 0 | break; |
620 | 0 | case X86_VPCMPQZrrik: |
621 | 0 | NewOpc = X86_VPCMPQZrrik_alt; |
622 | 0 | break; |
623 | 0 | case X86_VPCMPUBZ128rmi: |
624 | 0 | NewOpc = X86_VPCMPUBZ128rmi_alt; |
625 | 0 | break; |
626 | 0 | case X86_VPCMPUBZ128rmik: |
627 | 0 | NewOpc = X86_VPCMPUBZ128rmik_alt; |
628 | 0 | break; |
629 | 2 | case X86_VPCMPUBZ128rri: |
630 | 2 | NewOpc = X86_VPCMPUBZ128rri_alt; |
631 | 2 | break; |
632 | 2 | case X86_VPCMPUBZ128rrik: |
633 | 2 | NewOpc = X86_VPCMPUBZ128rrik_alt; |
634 | 2 | break; |
635 | 0 | case X86_VPCMPUBZ256rmi: |
636 | 0 | NewOpc = X86_VPCMPUBZ256rmi_alt; |
637 | 0 | break; |
638 | 0 | case X86_VPCMPUBZ256rmik: |
639 | 0 | NewOpc = X86_VPCMPUBZ256rmik_alt; |
640 | 0 | break; |
641 | 0 | case X86_VPCMPUBZ256rri: |
642 | 0 | NewOpc = X86_VPCMPUBZ256rri_alt; |
643 | 0 | break; |
644 | 0 | case X86_VPCMPUBZ256rrik: |
645 | 0 | NewOpc = X86_VPCMPUBZ256rrik_alt; |
646 | 0 | break; |
647 | 0 | case X86_VPCMPUBZrmi: |
648 | 0 | NewOpc = X86_VPCMPUBZrmi_alt; |
649 | 0 | break; |
650 | 0 | case X86_VPCMPUBZrmik: |
651 | 0 | NewOpc = X86_VPCMPUBZrmik_alt; |
652 | 0 | break; |
653 | 0 | case X86_VPCMPUBZrri: |
654 | 0 | NewOpc = X86_VPCMPUBZrri_alt; |
655 | 0 | break; |
656 | 0 | case X86_VPCMPUBZrrik: |
657 | 0 | NewOpc = X86_VPCMPUBZrrik_alt; |
658 | 0 | break; |
659 | 0 | case X86_VPCMPUDZ128rmi: |
660 | 0 | NewOpc = X86_VPCMPUDZ128rmi_alt; |
661 | 0 | break; |
662 | 0 | case X86_VPCMPUDZ128rmib: |
663 | 0 | NewOpc = X86_VPCMPUDZ128rmib_alt; |
664 | 0 | break; |
665 | 0 | case X86_VPCMPUDZ128rmibk: |
666 | 0 | NewOpc = X86_VPCMPUDZ128rmibk_alt; |
667 | 0 | break; |
668 | 0 | case X86_VPCMPUDZ128rmik: |
669 | 0 | NewOpc = X86_VPCMPUDZ128rmik_alt; |
670 | 0 | break; |
671 | 0 | case X86_VPCMPUDZ128rri: |
672 | 0 | NewOpc = X86_VPCMPUDZ128rri_alt; |
673 | 0 | break; |
674 | 6 | case X86_VPCMPUDZ128rrik: |
675 | 6 | NewOpc = X86_VPCMPUDZ128rrik_alt; |
676 | 6 | break; |
677 | 0 | case X86_VPCMPUDZ256rmi: |
678 | 0 | NewOpc = X86_VPCMPUDZ256rmi_alt; |
679 | 0 | break; |
680 | 0 | case X86_VPCMPUDZ256rmib: |
681 | 0 | NewOpc = X86_VPCMPUDZ256rmib_alt; |
682 | 0 | break; |
683 | 9 | case X86_VPCMPUDZ256rmibk: |
684 | 9 | NewOpc = X86_VPCMPUDZ256rmibk_alt; |
685 | 9 | break; |
686 | 0 | case X86_VPCMPUDZ256rmik: |
687 | 0 | NewOpc = X86_VPCMPUDZ256rmik_alt; |
688 | 0 | break; |
689 | 0 | case X86_VPCMPUDZ256rri: |
690 | 0 | NewOpc = X86_VPCMPUDZ256rri_alt; |
691 | 0 | break; |
692 | 0 | case X86_VPCMPUDZ256rrik: |
693 | 0 | NewOpc = X86_VPCMPUDZ256rrik_alt; |
694 | 0 | break; |
695 | 0 | case X86_VPCMPUDZrmi: |
696 | 0 | NewOpc = X86_VPCMPUDZrmi_alt; |
697 | 0 | break; |
698 | 3 | case X86_VPCMPUDZrmib: |
699 | 3 | NewOpc = X86_VPCMPUDZrmib_alt; |
700 | 3 | break; |
701 | 0 | case X86_VPCMPUDZrmibk: |
702 | 0 | NewOpc = X86_VPCMPUDZrmibk_alt; |
703 | 0 | break; |
704 | 32 | case X86_VPCMPUDZrmik: |
705 | 32 | NewOpc = X86_VPCMPUDZrmik_alt; |
706 | 32 | break; |
707 | 0 | case X86_VPCMPUDZrri: |
708 | 0 | NewOpc = X86_VPCMPUDZrri_alt; |
709 | 0 | break; |
710 | 5 | case X86_VPCMPUDZrrik: |
711 | 5 | NewOpc = X86_VPCMPUDZrrik_alt; |
712 | 5 | break; |
713 | 0 | case X86_VPCMPUQZ128rmi: |
714 | 0 | NewOpc = X86_VPCMPUQZ128rmi_alt; |
715 | 0 | break; |
716 | 0 | case X86_VPCMPUQZ128rmib: |
717 | 0 | NewOpc = X86_VPCMPUQZ128rmib_alt; |
718 | 0 | break; |
719 | 2 | case X86_VPCMPUQZ128rmibk: |
720 | 2 | NewOpc = X86_VPCMPUQZ128rmibk_alt; |
721 | 2 | break; |
722 | 0 | case X86_VPCMPUQZ128rmik: |
723 | 0 | NewOpc = X86_VPCMPUQZ128rmik_alt; |
724 | 0 | break; |
725 | 0 | case X86_VPCMPUQZ128rri: |
726 | 0 | NewOpc = X86_VPCMPUQZ128rri_alt; |
727 | 0 | break; |
728 | 0 | case X86_VPCMPUQZ128rrik: |
729 | 0 | NewOpc = X86_VPCMPUQZ128rrik_alt; |
730 | 0 | break; |
731 | 0 | case X86_VPCMPUQZ256rmi: |
732 | 0 | NewOpc = X86_VPCMPUQZ256rmi_alt; |
733 | 0 | break; |
734 | 0 | case X86_VPCMPUQZ256rmib: |
735 | 0 | NewOpc = X86_VPCMPUQZ256rmib_alt; |
736 | 0 | break; |
737 | 0 | case X86_VPCMPUQZ256rmibk: |
738 | 0 | NewOpc = X86_VPCMPUQZ256rmibk_alt; |
739 | 0 | break; |
740 | 1 | case X86_VPCMPUQZ256rmik: |
741 | 1 | NewOpc = X86_VPCMPUQZ256rmik_alt; |
742 | 1 | break; |
743 | 0 | case X86_VPCMPUQZ256rri: |
744 | 0 | NewOpc = X86_VPCMPUQZ256rri_alt; |
745 | 0 | break; |
746 | 16 | case X86_VPCMPUQZ256rrik: |
747 | 16 | NewOpc = X86_VPCMPUQZ256rrik_alt; |
748 | 16 | break; |
749 | 0 | case X86_VPCMPUQZrmi: |
750 | 0 | NewOpc = X86_VPCMPUQZrmi_alt; |
751 | 0 | break; |
752 | 0 | case X86_VPCMPUQZrmib: |
753 | 0 | NewOpc = X86_VPCMPUQZrmib_alt; |
754 | 0 | break; |
755 | 0 | case X86_VPCMPUQZrmibk: |
756 | 0 | NewOpc = X86_VPCMPUQZrmibk_alt; |
757 | 0 | break; |
758 | 0 | case X86_VPCMPUQZrmik: |
759 | 0 | NewOpc = X86_VPCMPUQZrmik_alt; |
760 | 0 | break; |
761 | 17 | case X86_VPCMPUQZrri: |
762 | 17 | NewOpc = X86_VPCMPUQZrri_alt; |
763 | 17 | break; |
764 | 0 | case X86_VPCMPUQZrrik: |
765 | 0 | NewOpc = X86_VPCMPUQZrrik_alt; |
766 | 0 | break; |
767 | 1 | case X86_VPCMPUWZ128rmi: |
768 | 1 | NewOpc = X86_VPCMPUWZ128rmi_alt; |
769 | 1 | break; |
770 | 0 | case X86_VPCMPUWZ128rmik: |
771 | 0 | NewOpc = X86_VPCMPUWZ128rmik_alt; |
772 | 0 | break; |
773 | 8 | case X86_VPCMPUWZ128rri: |
774 | 8 | NewOpc = X86_VPCMPUWZ128rri_alt; |
775 | 8 | break; |
776 | 1 | case X86_VPCMPUWZ128rrik: |
777 | 1 | NewOpc = X86_VPCMPUWZ128rrik_alt; |
778 | 1 | break; |
779 | 0 | case X86_VPCMPUWZ256rmi: |
780 | 0 | NewOpc = X86_VPCMPUWZ256rmi_alt; |
781 | 0 | break; |
782 | 0 | case X86_VPCMPUWZ256rmik: |
783 | 0 | NewOpc = X86_VPCMPUWZ256rmik_alt; |
784 | 0 | break; |
785 | 0 | case X86_VPCMPUWZ256rri: |
786 | 0 | NewOpc = X86_VPCMPUWZ256rri_alt; |
787 | 0 | break; |
788 | 0 | case X86_VPCMPUWZ256rrik: |
789 | 0 | NewOpc = X86_VPCMPUWZ256rrik_alt; |
790 | 0 | break; |
791 | 0 | case X86_VPCMPUWZrmi: |
792 | 0 | NewOpc = X86_VPCMPUWZrmi_alt; |
793 | 0 | break; |
794 | 0 | case X86_VPCMPUWZrmik: |
795 | 0 | NewOpc = X86_VPCMPUWZrmik_alt; |
796 | 0 | break; |
797 | 8 | case X86_VPCMPUWZrri: |
798 | 8 | NewOpc = X86_VPCMPUWZrri_alt; |
799 | 8 | break; |
800 | 0 | case X86_VPCMPUWZrrik: |
801 | 0 | NewOpc = X86_VPCMPUWZrrik_alt; |
802 | 0 | break; |
803 | 0 | case X86_VPCMPWZ128rmi: |
804 | 0 | NewOpc = X86_VPCMPWZ128rmi_alt; |
805 | 0 | break; |
806 | 0 | case X86_VPCMPWZ128rmik: |
807 | 0 | NewOpc = X86_VPCMPWZ128rmik_alt; |
808 | 0 | break; |
809 | 0 | case X86_VPCMPWZ128rri: |
810 | 0 | NewOpc = X86_VPCMPWZ128rri_alt; |
811 | 0 | break; |
812 | 0 | case X86_VPCMPWZ128rrik: |
813 | 0 | NewOpc = X86_VPCMPWZ128rrik_alt; |
814 | 0 | break; |
815 | 19 | case X86_VPCMPWZ256rmi: |
816 | 19 | NewOpc = X86_VPCMPWZ256rmi_alt; |
817 | 19 | break; |
818 | 1 | case X86_VPCMPWZ256rmik: |
819 | 1 | NewOpc = X86_VPCMPWZ256rmik_alt; |
820 | 1 | break; |
821 | 0 | case X86_VPCMPWZ256rri: |
822 | 0 | NewOpc = X86_VPCMPWZ256rri_alt; |
823 | 0 | break; |
824 | 2 | case X86_VPCMPWZ256rrik: |
825 | 2 | NewOpc = X86_VPCMPWZ256rrik_alt; |
826 | 2 | break; |
827 | 0 | case X86_VPCMPWZrmi: |
828 | 0 | NewOpc = X86_VPCMPWZrmi_alt; |
829 | 0 | break; |
830 | 0 | case X86_VPCMPWZrmik: |
831 | 0 | NewOpc = X86_VPCMPWZrmik_alt; |
832 | 0 | break; |
833 | 0 | case X86_VPCMPWZrri: |
834 | 0 | NewOpc = X86_VPCMPWZrri_alt; |
835 | 0 | break; |
836 | 0 | case X86_VPCMPWZrrik: |
837 | 0 | NewOpc = X86_VPCMPWZrrik_alt; |
838 | 0 | break; |
839 | 458 | } |
840 | | |
841 | | // Switch opcode to the one that doesn't get special printing. |
842 | 458 | if (NewOpc != 0) { |
843 | 458 | MCInst_setOpcode(mcInst, NewOpc); |
844 | 458 | } |
845 | 458 | } |
846 | 804 | #endif |
847 | 804 | } |
848 | | |
849 | 24.0k | switch (type) { |
850 | 211 | case TYPE_XMM: |
851 | 211 | MCOperand_CreateReg0(mcInst, |
852 | 211 | X86_XMM0 + ((uint32_t)immediate >> 4)); |
853 | 211 | return; |
854 | 13 | case TYPE_YMM: |
855 | 13 | MCOperand_CreateReg0(mcInst, |
856 | 13 | X86_YMM0 + ((uint32_t)immediate >> 4)); |
857 | 13 | return; |
858 | 0 | case TYPE_ZMM: |
859 | 0 | MCOperand_CreateReg0(mcInst, |
860 | 0 | X86_ZMM0 + ((uint32_t)immediate >> 4)); |
861 | 0 | return; |
862 | 23.8k | default: |
863 | | // operand is 64 bits wide. Do nothing. |
864 | 23.8k | break; |
865 | 24.0k | } |
866 | | |
867 | 23.8k | MCOperand_CreateImm0(mcInst, immediate); |
868 | | |
869 | 23.8k | if (type == TYPE_MOFFS) { |
870 | 841 | MCOperand_CreateReg0(mcInst, |
871 | 841 | segmentRegnums[insn->segmentOverride]); |
872 | 841 | } |
873 | 23.8k | } |
874 | | |
875 | | /// translateRMRegister - Translates a register stored in the R/M field of the |
876 | | /// ModR/M byte to its LLVM equivalent and appends it to an MCInst. |
877 | | /// @param mcInst - The MCInst to append to. |
878 | | /// @param insn - The internal instruction to extract the R/M field |
879 | | /// from. |
880 | | /// @return - 0 on success; -1 otherwise |
881 | | static bool translateRMRegister(MCInst *mcInst, InternalInstruction *insn) |
882 | 17.6k | { |
883 | 17.6k | if (insn->eaBase == EA_BASE_sib || insn->eaBase == EA_BASE_sib64) { |
884 | | //debug("A R/M register operand may not have a SIB byte"); |
885 | 0 | return true; |
886 | 0 | } |
887 | | |
888 | 17.6k | switch (insn->eaBase) { |
889 | 0 | case EA_BASE_NONE: |
890 | | //debug("EA_BASE_NONE for ModR/M base"); |
891 | 0 | return true; |
892 | 0 | #define ENTRY(x) case EA_BASE_##x: |
893 | 0 | ALL_EA_BASES |
894 | 0 | #undef ENTRY |
895 | | //debug("A R/M register operand may not have a base; " |
896 | | // "the operand must be a register."); |
897 | 0 | return true; |
898 | 0 | #define ENTRY(x) \ |
899 | 17.6k | case EA_REG_##x: \ |
900 | 17.6k | MCOperand_CreateReg0(mcInst, X86_##x); \ |
901 | 17.6k | break; |
902 | 0 | ALL_REGS |
903 | 0 | #undef ENTRY |
904 | 0 | default: |
905 | | //debug("Unexpected EA base register"); |
906 | 0 | return true; |
907 | 17.6k | } |
908 | | |
909 | 17.6k | return false; |
910 | 17.6k | } |
911 | | |
912 | | /// translateRMMemory - Translates a memory operand stored in the Mod and R/M |
913 | | /// fields of an internal instruction (and possibly its SIB byte) to a memory |
914 | | /// operand in LLVM's format, and appends it to an MCInst. |
915 | | /// |
916 | | /// @param mcInst - The MCInst to append to. |
917 | | /// @param insn - The instruction to extract Mod, R/M, and SIB fields |
918 | | /// from. |
919 | | /// @return - 0 on success; nonzero otherwise |
920 | | static bool translateRMMemory(MCInst *mcInst, InternalInstruction *insn) |
921 | 32.6k | { |
922 | | // Addresses in an MCInst are represented as five operands: |
923 | | // 1. basereg (register) The R/M base, or (if there is a SIB) the |
924 | | // SIB base |
925 | | // 2. scaleamount (immediate) 1, or (if there is a SIB) the specified |
926 | | // scale amount |
927 | | // 3. indexreg (register) x86_registerNONE, or (if there is a SIB) |
928 | | // the index (which is multiplied by the |
929 | | // scale amount) |
930 | | // 4. displacement (immediate) 0, or the displacement if there is one |
931 | | // 5. segmentreg (register) x86_registerNONE for now, but could be set |
932 | | // if we have segment overrides |
933 | 32.6k | int scaleAmount, indexReg; |
934 | | |
935 | 32.6k | if (insn->eaBase == EA_BASE_sib || insn->eaBase == EA_BASE_sib64) { |
936 | 2.16k | if (insn->sibBase != SIB_BASE_NONE) { |
937 | 2.10k | switch (insn->sibBase) { |
938 | 0 | #define ENTRY(x) \ |
939 | 2.10k | case SIB_BASE_##x: \ |
940 | 2.10k | MCOperand_CreateReg0(mcInst, X86_##x); \ |
941 | 2.10k | break; |
942 | 0 | ALL_SIB_BASES |
943 | 0 | #undef ENTRY |
944 | 0 | default: |
945 | | //debug("Unexpected sibBase"); |
946 | 0 | return true; |
947 | 2.10k | } |
948 | 2.10k | } else { |
949 | 66 | MCOperand_CreateReg0(mcInst, 0); |
950 | 66 | } |
951 | | |
952 | 2.16k | if (insn->sibIndex != SIB_INDEX_NONE) { |
953 | 1.86k | switch (insn->sibIndex) { |
954 | 0 | default: |
955 | | //debug("Unexpected sibIndex"); |
956 | 0 | return true; |
957 | 0 | #define ENTRY(x) \ |
958 | 1.86k | case SIB_INDEX_##x: \ |
959 | 1.86k | indexReg = X86_##x; \ |
960 | 1.86k | break; |
961 | 0 | EA_BASES_32BIT |
962 | 55 | EA_BASES_64BIT |
963 | 16 | REGS_XMM |
964 | 0 | REGS_YMM |
965 | 1.86k | REGS_ZMM |
966 | 1.86k | #undef ENTRY |
967 | 1.86k | } |
968 | 1.86k | } else { |
969 | | // Use EIZ/RIZ for a few ambiguous cases where the SIB byte is present, |
970 | | // but no index is used and modrm alone should have been enough. |
971 | | // -No base register in 32-bit mode. In 64-bit mode this is used to |
972 | | // avoid rip-relative addressing. |
973 | | // -Any base register used other than ESP/RSP/R12D/R12. Using these as a |
974 | | // base always requires a SIB byte. |
975 | | // -A scale other than 1 is used. |
976 | 308 | if (insn->sibScale != 1 || |
977 | 254 | (insn->sibBase == SIB_BASE_NONE && |
978 | 9 | insn->mode != MODE_64BIT) || |
979 | 250 | (insn->sibBase != SIB_BASE_NONE && |
980 | 245 | insn->sibBase != SIB_BASE_ESP && |
981 | 227 | insn->sibBase != SIB_BASE_RSP && |
982 | 191 | insn->sibBase != SIB_BASE_R12D && |
983 | 191 | insn->sibBase != SIB_BASE_R12)) { |
984 | 124 | indexReg = insn->addressSize == 4 ? X86_EIZ : |
985 | 124 | X86_RIZ; |
986 | 124 | } else |
987 | 184 | indexReg = 0; |
988 | 308 | } |
989 | | |
990 | 2.16k | scaleAmount = insn->sibScale; |
991 | 30.4k | } else { |
992 | 30.4k | switch (insn->eaBase) { |
993 | 787 | case EA_BASE_NONE: |
994 | 787 | if (insn->eaDisplacement == EA_DISP_NONE) { |
995 | | //debug("EA_BASE_NONE and EA_DISP_NONE for ModR/M base"); |
996 | 0 | return true; |
997 | 0 | } |
998 | 787 | if (insn->mode == MODE_64BIT) { |
999 | 302 | if (insn->prefix3 == |
1000 | 302 | 0x67) // address-size prefix overrides RIP relative addressing |
1001 | 129 | MCOperand_CreateReg0(mcInst, X86_EIP); |
1002 | 173 | else |
1003 | | // Section 2.2.1.6 |
1004 | 173 | MCOperand_CreateReg0( |
1005 | 173 | mcInst, insn->addressSize == 4 ? |
1006 | 0 | X86_EIP : |
1007 | 173 | X86_RIP); |
1008 | 485 | } else { |
1009 | 485 | MCOperand_CreateReg0(mcInst, 0); |
1010 | 485 | } |
1011 | | |
1012 | 787 | indexReg = 0; |
1013 | 787 | break; |
1014 | 4.12k | case EA_BASE_BX_SI: |
1015 | 4.12k | MCOperand_CreateReg0(mcInst, X86_BX); |
1016 | 4.12k | indexReg = X86_SI; |
1017 | 4.12k | break; |
1018 | 1.53k | case EA_BASE_BX_DI: |
1019 | 1.53k | MCOperand_CreateReg0(mcInst, X86_BX); |
1020 | 1.53k | indexReg = X86_DI; |
1021 | 1.53k | break; |
1022 | 1.02k | case EA_BASE_BP_SI: |
1023 | 1.02k | MCOperand_CreateReg0(mcInst, X86_BP); |
1024 | 1.02k | indexReg = X86_SI; |
1025 | 1.02k | break; |
1026 | 848 | case EA_BASE_BP_DI: |
1027 | 848 | MCOperand_CreateReg0(mcInst, X86_BP); |
1028 | 848 | indexReg = X86_DI; |
1029 | 848 | break; |
1030 | 22.1k | default: |
1031 | 22.1k | indexReg = 0; |
1032 | 22.1k | switch (insn->eaBase) { |
1033 | 0 | default: |
1034 | | //debug("Unexpected eaBase"); |
1035 | 0 | return true; |
1036 | | // Here, we will use the fill-ins defined above. However, |
1037 | | // BX_SI, BX_DI, BP_SI, and BP_DI are all handled above and |
1038 | | // sib and sib64 were handled in the top-level if, so they're only |
1039 | | // placeholders to keep the compiler happy. |
1040 | 0 | #define ENTRY(x) \ |
1041 | 22.1k | case EA_BASE_##x: \ |
1042 | 22.1k | MCOperand_CreateReg0(mcInst, X86_##x); \ |
1043 | 22.1k | break; |
1044 | 0 | ALL_EA_BASES |
1045 | 0 | #undef ENTRY |
1046 | 396 | #define ENTRY(x) case EA_REG_##x: |
1047 | 132 | ALL_REGS |
1048 | 0 | #undef ENTRY |
1049 | | //debug("A R/M memory operand may not be a register; " |
1050 | | // "the base field must be a base."); |
1051 | 0 | return true; |
1052 | 22.1k | } |
1053 | 30.4k | } |
1054 | | |
1055 | 30.4k | scaleAmount = 1; |
1056 | 30.4k | } |
1057 | | |
1058 | 32.6k | MCOperand_CreateImm0(mcInst, scaleAmount); |
1059 | 32.6k | MCOperand_CreateReg0(mcInst, indexReg); |
1060 | 32.6k | MCOperand_CreateImm0(mcInst, insn->displacement); |
1061 | | |
1062 | 32.6k | MCOperand_CreateReg0(mcInst, segmentRegnums[insn->segmentOverride]); |
1063 | | |
1064 | 32.6k | return false; |
1065 | 32.6k | } |
1066 | | |
1067 | | /// translateRM - Translates an operand stored in the R/M (and possibly SIB) |
1068 | | /// byte of an instruction to LLVM form, and appends it to an MCInst. |
1069 | | /// |
1070 | | /// @param mcInst - The MCInst to append to. |
1071 | | /// @param operand - The operand, as stored in the descriptor table. |
1072 | | /// @param insn - The instruction to extract Mod, R/M, and SIB fields |
1073 | | /// from. |
1074 | | /// @return - 0 on success; nonzero otherwise |
1075 | | static bool translateRM(MCInst *mcInst, const OperandSpecifier *operand, |
1076 | | InternalInstruction *insn) |
1077 | 50.2k | { |
1078 | 50.2k | switch (operand->type) { |
1079 | 0 | default: |
1080 | | //debug("Unexpected type for a R/M operand"); |
1081 | 0 | return true; |
1082 | 4.52k | case TYPE_R8: |
1083 | 4.52k | case TYPE_R16: |
1084 | 4.63k | case TYPE_R32: |
1085 | 5.54k | case TYPE_R64: |
1086 | 11.8k | case TYPE_Rv: |
1087 | 11.9k | case TYPE_MM64: |
1088 | 14.8k | case TYPE_XMM: |
1089 | 15.6k | case TYPE_YMM: |
1090 | 17.3k | case TYPE_ZMM: |
1091 | 17.4k | case TYPE_VK: |
1092 | 17.4k | case TYPE_DEBUGREG: |
1093 | 17.4k | case TYPE_CONTROLREG: |
1094 | 17.6k | case TYPE_BNDR: |
1095 | 17.6k | return translateRMRegister(mcInst, insn); |
1096 | 32.1k | case TYPE_M: |
1097 | 32.4k | case TYPE_MVSIBX: |
1098 | 32.4k | case TYPE_MVSIBY: |
1099 | 32.6k | case TYPE_MVSIBZ: |
1100 | 32.6k | return translateRMMemory(mcInst, insn); |
1101 | 50.2k | } |
1102 | 50.2k | } |
1103 | | |
1104 | | /// translateFPRegister - Translates a stack position on the FPU stack to its |
1105 | | /// LLVM form, and appends it to an MCInst. |
1106 | | /// |
1107 | | /// @param mcInst - The MCInst to append to. |
1108 | | /// @param stackPos - The stack position to translate. |
1109 | | static void translateFPRegister(MCInst *mcInst, uint8_t stackPos) |
1110 | 296 | { |
1111 | 296 | MCOperand_CreateReg0(mcInst, X86_ST0 + stackPos); |
1112 | 296 | } |
1113 | | |
1114 | | /// translateMaskRegister - Translates a 3-bit mask register number to |
1115 | | /// LLVM form, and appends it to an MCInst. |
1116 | | /// |
1117 | | /// @param mcInst - The MCInst to append to. |
1118 | | /// @param maskRegNum - Number of mask register from 0 to 7. |
1119 | | /// @return - false on success; true otherwise. |
1120 | | static bool translateMaskRegister(MCInst *mcInst, uint8_t maskRegNum) |
1121 | 5.30k | { |
1122 | 5.30k | if (maskRegNum >= 8) { |
1123 | | // debug("Invalid mask register number"); |
1124 | 0 | return true; |
1125 | 0 | } |
1126 | | |
1127 | 5.30k | MCOperand_CreateReg0(mcInst, X86_K0 + maskRegNum); |
1128 | | |
1129 | 5.30k | return false; |
1130 | 5.30k | } |
1131 | | |
1132 | | /// translateOperand - Translates an operand stored in an internal instruction |
1133 | | /// to LLVM's format and appends it to an MCInst. |
1134 | | /// |
1135 | | /// @param mcInst - The MCInst to append to. |
1136 | | /// @param operand - The operand, as stored in the descriptor table. |
1137 | | /// @param insn - The internal instruction. |
1138 | | /// @return - false on success; true otherwise. |
1139 | | static bool translateOperand(MCInst *mcInst, const OperandSpecifier *operand, |
1140 | | InternalInstruction *insn) |
1141 | 170k | { |
1142 | 170k | switch (operand->encoding) { |
1143 | 43.4k | case ENCODING_REG: |
1144 | 43.4k | translateRegister(mcInst, insn->reg); |
1145 | 43.4k | return false; |
1146 | 5.30k | case ENCODING_WRITEMASK: |
1147 | 5.30k | return translateMaskRegister(mcInst, insn->writemask); |
1148 | 320k | CASE_ENCODING_RM: |
1149 | 320k | CASE_ENCODING_VSIB: |
1150 | 50.2k | return translateRM(mcInst, operand, insn); |
1151 | 19.2k | case ENCODING_IB: |
1152 | 20.2k | case ENCODING_IW: |
1153 | 20.5k | case ENCODING_ID: |
1154 | 20.7k | case ENCODING_IO: |
1155 | 23.2k | case ENCODING_Iv: |
1156 | 24.0k | case ENCODING_Ia: |
1157 | 24.0k | translateImmediate( |
1158 | 24.0k | mcInst, |
1159 | 24.0k | insn->immediates[insn->numImmediatesTranslated++], |
1160 | 24.0k | operand, insn); |
1161 | 24.0k | return false; |
1162 | 474 | case ENCODING_IRC: |
1163 | 474 | MCOperand_CreateImm0(mcInst, insn->RC); |
1164 | 474 | return false; |
1165 | 4.42k | case ENCODING_SI: |
1166 | 4.42k | return translateSrcIndex(mcInst, insn); |
1167 | 4.95k | case ENCODING_DI: |
1168 | 4.95k | return translateDstIndex(mcInst, insn); |
1169 | 943 | case ENCODING_RB: |
1170 | 943 | case ENCODING_RW: |
1171 | 943 | case ENCODING_RD: |
1172 | 2.65k | case ENCODING_RO: |
1173 | 12.0k | case ENCODING_Rv: |
1174 | 12.0k | translateRegister(mcInst, insn->opcodeRegister); |
1175 | 12.0k | return false; |
1176 | 296 | case ENCODING_FP: |
1177 | 296 | translateFPRegister(mcInst, insn->modRM & 7); |
1178 | 296 | return false; |
1179 | 6.98k | case ENCODING_VVVV: |
1180 | 6.98k | translateRegister(mcInst, insn->vvvv); |
1181 | 6.98k | return false; |
1182 | 18.5k | case ENCODING_DUP: |
1183 | 18.5k | return translateOperand( |
1184 | 18.5k | mcInst, &insn->operands[operand->type - TYPE_DUP0], |
1185 | 18.5k | insn); |
1186 | 0 | default: |
1187 | | //debug("Unhandled operand encoding during translation"); |
1188 | 0 | return true; |
1189 | 170k | } |
1190 | 170k | } |
1191 | | |
1192 | | static bool translateInstruction(MCInst *mcInst, InternalInstruction *insn) |
1193 | 81.8k | { |
1194 | 81.8k | int index; |
1195 | | |
1196 | 81.8k | if (!insn->spec) { |
1197 | | //debug("Instruction has no specification"); |
1198 | 0 | return true; |
1199 | 0 | } |
1200 | | |
1201 | 81.8k | MCInst_clear(mcInst); |
1202 | 81.8k | MCInst_setOpcode(mcInst, insn->instructionID); |
1203 | | |
1204 | | // If when reading the prefix bytes we determined the overlapping 0xf2 or 0xf3 |
1205 | | // prefix bytes should be disassembled as xrelease and xacquire then set the |
1206 | | // opcode to those instead of the rep and repne opcodes. |
1207 | 81.8k | #ifndef CAPSTONE_X86_REDUCE |
1208 | 81.8k | if (insn->xAcquireRelease) { |
1209 | 409 | if (MCInst_getOpcode(mcInst) == X86_REP_PREFIX) |
1210 | 0 | MCInst_setOpcode(mcInst, X86_XRELEASE_PREFIX); |
1211 | 409 | else if (MCInst_getOpcode(mcInst) == X86_REPNE_PREFIX) |
1212 | 0 | MCInst_setOpcode(mcInst, X86_XACQUIRE_PREFIX); |
1213 | 409 | } |
1214 | 81.8k | #endif |
1215 | | |
1216 | 81.8k | insn->numImmediatesTranslated = 0; |
1217 | | |
1218 | 572k | for (index = 0; index < X86_MAX_OPERANDS; ++index) { |
1219 | 491k | if (insn->operands[index].encoding != ENCODING_NONE) { |
1220 | 152k | if (translateOperand(mcInst, &insn->operands[index], |
1221 | 152k | insn)) { |
1222 | 0 | return true; |
1223 | 0 | } |
1224 | 152k | } |
1225 | 491k | } |
1226 | | |
1227 | 81.8k | return false; |
1228 | 81.8k | } |
1229 | | |
1230 | | static int reader(const struct reader_info *info, uint8_t *byte, |
1231 | | uint64_t address) |
1232 | 398k | { |
1233 | 398k | if (address - info->offset >= info->size) |
1234 | | // out of buffer range |
1235 | 459 | return -1; |
1236 | | |
1237 | 398k | *byte = info->code[address - info->offset]; |
1238 | | |
1239 | 398k | return 0; |
1240 | 398k | } |
1241 | | |
1242 | | // copy x86 detail information from internal structure to public structure |
1243 | | static void update_pub_insn(cs_insn *pub, InternalInstruction *inter) |
1244 | 81.8k | { |
1245 | 81.8k | if (inter->vectorExtensionType != 0) { |
1246 | 9.23k | memcpy(pub->detail->x86.opcode, inter->vectorExtensionPrefix, |
1247 | 9.23k | sizeof(pub->detail->x86.opcode)); |
1248 | 72.6k | } else { |
1249 | 72.6k | if (inter->twoByteEscape) { |
1250 | 4.81k | if (inter->threeByteEscape) { |
1251 | 0 | pub->detail->x86.opcode[0] = |
1252 | 0 | inter->twoByteEscape; |
1253 | 0 | pub->detail->x86.opcode[1] = |
1254 | 0 | inter->threeByteEscape; |
1255 | 0 | pub->detail->x86.opcode[2] = inter->opcode; |
1256 | 4.81k | } else { |
1257 | 4.81k | pub->detail->x86.opcode[0] = |
1258 | 4.81k | inter->twoByteEscape; |
1259 | 4.81k | pub->detail->x86.opcode[1] = inter->opcode; |
1260 | 4.81k | } |
1261 | 67.8k | } else { |
1262 | 67.8k | pub->detail->x86.opcode[0] = inter->opcode; |
1263 | 67.8k | } |
1264 | 72.6k | } |
1265 | | |
1266 | 81.8k | pub->detail->x86.rex = inter->rexPrefix; |
1267 | | |
1268 | 81.8k | pub->detail->x86.addr_size = inter->addressSize; |
1269 | | |
1270 | 81.8k | pub->detail->x86.modrm = inter->orgModRM; |
1271 | 81.8k | pub->detail->x86.encoding.modrm_offset = inter->modRMOffset; |
1272 | | |
1273 | 81.8k | pub->detail->x86.sib = inter->sib; |
1274 | 81.8k | pub->detail->x86.sib_index = x86_map_sib_index(inter->sibIndex); |
1275 | 81.8k | pub->detail->x86.sib_scale = inter->sibScale; |
1276 | 81.8k | pub->detail->x86.sib_base = x86_map_sib_base(inter->sibBase); |
1277 | | |
1278 | 81.8k | pub->detail->x86.disp = inter->displacement; |
1279 | 81.8k | if (inter->consumedDisplacement) { |
1280 | 10.9k | pub->detail->x86.encoding.disp_offset = |
1281 | 10.9k | inter->displacementOffset; |
1282 | 10.9k | pub->detail->x86.encoding.disp_size = inter->displacementSize; |
1283 | 10.9k | } |
1284 | | |
1285 | 81.8k | pub->detail->x86.encoding.imm_offset = inter->immediateOffset; |
1286 | 81.8k | if (pub->detail->x86.encoding.imm_size == 0 && |
1287 | 81.8k | inter->immediateOffset != 0) |
1288 | 22.6k | pub->detail->x86.encoding.imm_size = inter->immediateSize; |
1289 | 81.8k | } |
1290 | | |
1291 | | void X86_init(MCRegisterInfo *MRI) |
1292 | 1.63k | { |
1293 | | // InitMCRegisterInfo(), X86GenRegisterInfo.inc |
1294 | | // RI->InitMCRegisterInfo(X86RegDesc, 277, |
1295 | | // RA, PC, |
1296 | | // X86MCRegisterClasses, 86, |
1297 | | // X86RegUnitRoots, 162, X86RegDiffLists, X86LaneMaskLists, X86RegStrings, |
1298 | | // X86RegClassStrings, |
1299 | | // X86SubRegIdxLists, 9, |
1300 | | // X86SubRegIdxRanges, X86RegEncodingTable); |
1301 | | /* |
1302 | | InitMCRegisterInfo(X86RegDesc, 234, |
1303 | | RA, PC, |
1304 | | X86MCRegisterClasses, 79, |
1305 | | X86RegUnitRoots, 119, X86RegDiffLists, X86RegStrings, |
1306 | | X86SubRegIdxLists, 7, |
1307 | | X86SubRegIdxRanges, X86RegEncodingTable); |
1308 | | */ |
1309 | | |
1310 | 1.63k | MCRegisterInfo_InitMCRegisterInfo(MRI, X86RegDesc, 277, 0, 0, |
1311 | 1.63k | X86MCRegisterClasses, 86, 0, 0, |
1312 | 1.63k | X86RegDiffLists, 0, X86SubRegIdxLists, |
1313 | 1.63k | 9, 0); |
1314 | 1.63k | } |
1315 | | |
1316 | | // Public interface for the disassembler |
1317 | | bool X86_getInstruction(csh ud, const uint8_t *code, size_t code_len, |
1318 | | MCInst *instr, uint16_t *size, uint64_t address, |
1319 | | void *_info) |
1320 | 82.4k | { |
1321 | 82.4k | cs_struct *handle = (cs_struct *)(uintptr_t)ud; |
1322 | 82.4k | InternalInstruction insn = { 0 }; |
1323 | 82.4k | struct reader_info info; |
1324 | 82.4k | int ret; |
1325 | 82.4k | bool result; |
1326 | | |
1327 | 82.4k | info.code = code; |
1328 | 82.4k | info.size = code_len; |
1329 | 82.4k | info.offset = address; |
1330 | | |
1331 | 82.4k | if (instr->flat_insn->detail) { |
1332 | | // instr->flat_insn->detail initialization: 3 alternatives |
1333 | | |
1334 | | // 1. The whole structure, this is how it's done in other arch disassemblers |
1335 | | // Probably overkill since cs_detail is huge because of the 36 operands of ARM |
1336 | | |
1337 | | //memset(instr->flat_insn->detail, 0, sizeof(cs_detail)); |
1338 | | |
1339 | | // 2. Only the part relevant to x86 |
1340 | 82.4k | memset(instr->flat_insn->detail, 0, |
1341 | 82.4k | offsetof(cs_detail, x86) + sizeof(cs_x86)); |
1342 | | |
1343 | | // 3. The relevant part except for x86.operands |
1344 | | // sizeof(cs_x86) is 0x1c0, sizeof(x86.operands) is 0x180 |
1345 | | // marginally faster, should be okay since x86.op_count is set to 0 |
1346 | | |
1347 | | //memset(instr->flat_insn->detail, 0, offsetof(cs_detail, x86)+offsetof(cs_x86, operands)); |
1348 | 82.4k | } |
1349 | | |
1350 | 82.4k | if (handle->mode & CS_MODE_16) |
1351 | 25.3k | ret = decodeInstruction(&insn, reader, &info, address, |
1352 | 25.3k | MODE_16BIT); |
1353 | 57.0k | else if (handle->mode & CS_MODE_32) |
1354 | 24.6k | ret = decodeInstruction(&insn, reader, &info, address, |
1355 | 24.6k | MODE_32BIT); |
1356 | 32.3k | else |
1357 | 32.3k | ret = decodeInstruction(&insn, reader, &info, address, |
1358 | 32.3k | MODE_64BIT); |
1359 | | |
1360 | 82.4k | if (ret) { |
1361 | | // *size = (uint16_t)(insn.readerCursor - address); |
1362 | 550 | return false; |
1363 | 81.8k | } else { |
1364 | 81.8k | *size = (uint16_t)insn.length; |
1365 | | |
1366 | 81.8k | result = (!translateInstruction(instr, &insn)) ? true : false; |
1367 | 81.8k | if (result) { |
1368 | 81.8k | unsigned Flags = X86_IP_NO_PREFIX; |
1369 | 81.8k | instr->imm_size = insn.immSize; |
1370 | | |
1371 | | // copy all prefixes |
1372 | 81.8k | instr->x86_prefix[0] = insn.prefix0; |
1373 | 81.8k | instr->x86_prefix[1] = insn.prefix1; |
1374 | 81.8k | instr->x86_prefix[2] = insn.prefix2; |
1375 | 81.8k | instr->x86_prefix[3] = insn.prefix3; |
1376 | 81.8k | instr->xAcquireRelease = insn.xAcquireRelease; |
1377 | | |
1378 | 81.8k | if (handle->detail_opt) { |
1379 | 81.8k | update_pub_insn(instr->flat_insn, &insn); |
1380 | 81.8k | } |
1381 | | |
1382 | 81.8k | if (insn.hasAdSize) |
1383 | 1.42k | Flags |= X86_IP_HAS_AD_SIZE; |
1384 | | |
1385 | 81.8k | if (!insn.mandatoryPrefix) { |
1386 | 79.6k | if (insn.hasOpSize) |
1387 | 2.01k | Flags |= X86_IP_HAS_OP_SIZE; |
1388 | | |
1389 | 79.6k | if (insn.repeatPrefix == 0xf2) |
1390 | 2.29k | Flags |= X86_IP_HAS_REPEAT_NE; |
1391 | 77.3k | else if (insn.repeatPrefix == 0xf3 && |
1392 | | // It should not be 'pause' f3 90 |
1393 | 1.94k | insn.opcode != 0x90) |
1394 | 1.94k | Flags |= X86_IP_HAS_REPEAT; |
1395 | 79.6k | if (insn.hasLockPrefix) |
1396 | 3.39k | Flags |= X86_IP_HAS_LOCK; |
1397 | 79.6k | } |
1398 | | |
1399 | 81.8k | instr->flags = Flags; |
1400 | 81.8k | } |
1401 | | |
1402 | 81.8k | return result; |
1403 | 81.8k | } |
1404 | 82.4k | } |
1405 | | |
1406 | | #endif |