1 // Copyright 2011 the V8 project authors. All rights reserved. 2 // Redistribution and use in source and binary forms, with or without 3 // modification, are permitted provided that the following conditions are 4 // met: 5 // 6 // * Redistributions of source code must retain the above copyright 7 // notice, this list of conditions and the following disclaimer. 8 // * Redistributions in binary form must reproduce the above 9 // copyright notice, this list of conditions and the following 10 // disclaimer in the documentation and/or other materials provided 11 // with the distribution. 12 // * Neither the name of Google Inc. nor the names of its 13 // contributors may be used to endorse or promote products derived 14 // from this software without specific prior written permission. 15 // 16 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 17 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 18 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 19 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 20 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 21 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 22 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 23 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 24 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 25 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 26 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 27 28 // A Disassembler object is used to disassemble a block of code instruction by 29 // instruction. The default implementation of the NameConverter object can be 30 // overriden to modify register names or to do symbol lookup on addresses. 31 // 32 // The example below will disassemble a block of code and print it to stdout. 33 // 34 // NameConverter converter; 35 // Disassembler d(converter); 36 // for (byte* pc = begin; pc < end;) { 37 // v8::internal::EmbeddedVector<char, 256> buffer; 38 // byte* prev_pc = pc; 39 // pc += d.InstructionDecode(buffer, pc); 40 // printf("%p %08x %s\n", 41 // prev_pc, *reinterpret_cast<int32_t*>(prev_pc), buffer); 42 // } 43 // 44 // The Disassembler class also has a convenience method to disassemble a block 45 // of code into a FILE*, meaning that the above functionality could also be 46 // achieved by just calling Disassembler::Disassemble(stdout, begin, end); 47 48 49 #include <assert.h> 50 #include <stdio.h> 51 #include <stdarg.h> 52 #include <string.h> 53 #ifndef WIN32 54 #include <stdint.h> 55 #endif 56 57 #include "v8.h" 58 59 #if defined(V8_TARGET_ARCH_ARM) 60 61 #include "constants-arm.h" 62 #include "disasm.h" 63 #include "macro-assembler.h" 64 #include "platform.h" 65 66 67 namespace v8 { 68 namespace internal { 69 70 71 //------------------------------------------------------------------------------ 72 73 // Decoder decodes and disassembles instructions into an output buffer. 74 // It uses the converter to convert register names and call destinations into 75 // more informative description. 76 class Decoder { 77 public: 78 Decoder(const disasm::NameConverter& converter, 79 Vector<char> out_buffer) 80 : converter_(converter), 81 out_buffer_(out_buffer), 82 out_buffer_pos_(0) { 83 out_buffer_[out_buffer_pos_] = '\0'; 84 } 85 86 ~Decoder() {} 87 88 // Writes one disassembled instruction into 'buffer' (0-terminated). 89 // Returns the length of the disassembled machine instruction in bytes. 90 int InstructionDecode(byte* instruction); 91 92 static bool IsConstantPoolAt(byte* instr_ptr); 93 static int ConstantPoolSizeAt(byte* instr_ptr); 94 95 private: 96 // Bottleneck functions to print into the out_buffer. 97 void PrintChar(const char ch); 98 void Print(const char* str); 99 100 // Printing of common values. 101 void PrintRegister(int reg); 102 void PrintSRegister(int reg); 103 void PrintDRegister(int reg); 104 int FormatVFPRegister(Instruction* instr, const char* format); 105 void PrintMovwMovt(Instruction* instr); 106 int FormatVFPinstruction(Instruction* instr, const char* format); 107 void PrintCondition(Instruction* instr); 108 void PrintShiftRm(Instruction* instr); 109 void PrintShiftImm(Instruction* instr); 110 void PrintShiftSat(Instruction* instr); 111 void PrintPU(Instruction* instr); 112 void PrintSoftwareInterrupt(SoftwareInterruptCodes svc); 113 114 // Handle formatting of instructions and their options. 115 int FormatRegister(Instruction* instr, const char* option); 116 int FormatOption(Instruction* instr, const char* option); 117 void Format(Instruction* instr, const char* format); 118 void Unknown(Instruction* instr); 119 120 // Each of these functions decodes one particular instruction type, a 3-bit 121 // field in the instruction encoding. 122 // Types 0 and 1 are combined as they are largely the same except for the way 123 // they interpret the shifter operand. 124 void DecodeType01(Instruction* instr); 125 void DecodeType2(Instruction* instr); 126 void DecodeType3(Instruction* instr); 127 void DecodeType4(Instruction* instr); 128 void DecodeType5(Instruction* instr); 129 void DecodeType6(Instruction* instr); 130 // Type 7 includes special Debugger instructions. 131 int DecodeType7(Instruction* instr); 132 // For VFP support. 133 void DecodeTypeVFP(Instruction* instr); 134 void DecodeType6CoprocessorIns(Instruction* instr); 135 136 void DecodeVMOVBetweenCoreAndSinglePrecisionRegisters(Instruction* instr); 137 void DecodeVCMP(Instruction* instr); 138 void DecodeVCVTBetweenDoubleAndSingle(Instruction* instr); 139 void DecodeVCVTBetweenFloatingPointAndInteger(Instruction* instr); 140 141 const disasm::NameConverter& converter_; 142 Vector<char> out_buffer_; 143 int out_buffer_pos_; 144 145 DISALLOW_COPY_AND_ASSIGN(Decoder); 146 }; 147 148 149 // Support for assertions in the Decoder formatting functions. 150 #define STRING_STARTS_WITH(string, compare_string) \ 151 (strncmp(string, compare_string, strlen(compare_string)) == 0) 152 153 154 // Append the ch to the output buffer. 155 void Decoder::PrintChar(const char ch) { 156 out_buffer_[out_buffer_pos_++] = ch; 157 } 158 159 160 // Append the str to the output buffer. 161 void Decoder::Print(const char* str) { 162 char cur = *str++; 163 while (cur != '\0' && (out_buffer_pos_ < (out_buffer_.length() - 1))) { 164 PrintChar(cur); 165 cur = *str++; 166 } 167 out_buffer_[out_buffer_pos_] = 0; 168 } 169 170 171 // These condition names are defined in a way to match the native disassembler 172 // formatting. See for example the command "objdump -d <binary file>". 173 static const char* cond_names[kNumberOfConditions] = { 174 "eq", "ne", "cs" , "cc" , "mi" , "pl" , "vs" , "vc" , 175 "hi", "ls", "ge", "lt", "gt", "le", "", "invalid", 176 }; 177 178 179 // Print the condition guarding the instruction. 180 void Decoder::PrintCondition(Instruction* instr) { 181 Print(cond_names[instr->ConditionValue()]); 182 } 183 184 185 // Print the register name according to the active name converter. 186 void Decoder::PrintRegister(int reg) { 187 Print(converter_.NameOfCPURegister(reg)); 188 } 189 190 // Print the VFP S register name according to the active name converter. 191 void Decoder::PrintSRegister(int reg) { 192 Print(VFPRegisters::Name(reg, false)); 193 } 194 195 // Print the VFP D register name according to the active name converter. 196 void Decoder::PrintDRegister(int reg) { 197 Print(VFPRegisters::Name(reg, true)); 198 } 199 200 201 // These shift names are defined in a way to match the native disassembler 202 // formatting. See for example the command "objdump -d <binary file>". 203 static const char* const shift_names[kNumberOfShifts] = { 204 "lsl", "lsr", "asr", "ror" 205 }; 206 207 208 // Print the register shift operands for the instruction. Generally used for 209 // data processing instructions. 210 void Decoder::PrintShiftRm(Instruction* instr) { 211 ShiftOp shift = instr->ShiftField(); 212 int shift_index = instr->ShiftValue(); 213 int shift_amount = instr->ShiftAmountValue(); 214 int rm = instr->RmValue(); 215 216 PrintRegister(rm); 217 218 if ((instr->RegShiftValue() == 0) && (shift == LSL) && (shift_amount == 0)) { 219 // Special case for using rm only. 220 return; 221 } 222 if (instr->RegShiftValue() == 0) { 223 // by immediate 224 if ((shift == ROR) && (shift_amount == 0)) { 225 Print(", RRX"); 226 return; 227 } else if (((shift == LSR) || (shift == ASR)) && (shift_amount == 0)) { 228 shift_amount = 32; 229 } 230 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 231 ", %s #%d", 232 shift_names[shift_index], 233 shift_amount); 234 } else { 235 // by register 236 int rs = instr->RsValue(); 237 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 238 ", %s ", shift_names[shift_index]); 239 PrintRegister(rs); 240 } 241 } 242 243 244 // Print the immediate operand for the instruction. Generally used for data 245 // processing instructions. 246 void Decoder::PrintShiftImm(Instruction* instr) { 247 int rotate = instr->RotateValue() * 2; 248 int immed8 = instr->Immed8Value(); 249 int imm = (immed8 >> rotate) | (immed8 << (32 - rotate)); 250 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 251 "#%d", imm); 252 } 253 254 255 // Print the optional shift and immediate used by saturating instructions. 256 void Decoder::PrintShiftSat(Instruction* instr) { 257 int shift = instr->Bits(11, 7); 258 if (shift > 0) { 259 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 260 ", %s #%d", 261 shift_names[instr->Bit(6) * 2], 262 instr->Bits(11, 7)); 263 } 264 } 265 266 267 // Print PU formatting to reduce complexity of FormatOption. 268 void Decoder::PrintPU(Instruction* instr) { 269 switch (instr->PUField()) { 270 case da_x: { 271 Print("da"); 272 break; 273 } 274 case ia_x: { 275 Print("ia"); 276 break; 277 } 278 case db_x: { 279 Print("db"); 280 break; 281 } 282 case ib_x: { 283 Print("ib"); 284 break; 285 } 286 default: { 287 UNREACHABLE(); 288 break; 289 } 290 } 291 } 292 293 294 // Print SoftwareInterrupt codes. Factoring this out reduces the complexity of 295 // the FormatOption method. 296 void Decoder::PrintSoftwareInterrupt(SoftwareInterruptCodes svc) { 297 switch (svc) { 298 case kCallRtRedirected: 299 Print("call rt redirected"); 300 return; 301 case kBreakpoint: 302 Print("breakpoint"); 303 return; 304 default: 305 if (svc >= kStopCode) { 306 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 307 "%d - 0x%x", 308 svc & kStopCodeMask, 309 svc & kStopCodeMask); 310 } else { 311 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 312 "%d", 313 svc); 314 } 315 return; 316 } 317 } 318 319 320 // Handle all register based formatting in this function to reduce the 321 // complexity of FormatOption. 322 int Decoder::FormatRegister(Instruction* instr, const char* format) { 323 ASSERT(format[0] == 'r'); 324 if (format[1] == 'n') { // 'rn: Rn register 325 int reg = instr->RnValue(); 326 PrintRegister(reg); 327 return 2; 328 } else if (format[1] == 'd') { // 'rd: Rd register 329 int reg = instr->RdValue(); 330 PrintRegister(reg); 331 return 2; 332 } else if (format[1] == 's') { // 'rs: Rs register 333 int reg = instr->RsValue(); 334 PrintRegister(reg); 335 return 2; 336 } else if (format[1] == 'm') { // 'rm: Rm register 337 int reg = instr->RmValue(); 338 PrintRegister(reg); 339 return 2; 340 } else if (format[1] == 't') { // 'rt: Rt register 341 int reg = instr->RtValue(); 342 PrintRegister(reg); 343 return 2; 344 } else if (format[1] == 'l') { 345 // 'rlist: register list for load and store multiple instructions 346 ASSERT(STRING_STARTS_WITH(format, "rlist")); 347 int rlist = instr->RlistValue(); 348 int reg = 0; 349 Print("{"); 350 // Print register list in ascending order, by scanning the bit mask. 351 while (rlist != 0) { 352 if ((rlist & 1) != 0) { 353 PrintRegister(reg); 354 if ((rlist >> 1) != 0) { 355 Print(", "); 356 } 357 } 358 reg++; 359 rlist >>= 1; 360 } 361 Print("}"); 362 return 5; 363 } 364 UNREACHABLE(); 365 return -1; 366 } 367 368 369 // Handle all VFP register based formatting in this function to reduce the 370 // complexity of FormatOption. 371 int Decoder::FormatVFPRegister(Instruction* instr, const char* format) { 372 ASSERT((format[0] == 'S') || (format[0] == 'D')); 373 374 VFPRegPrecision precision = 375 format[0] == 'D' ? kDoublePrecision : kSinglePrecision; 376 377 int retval = 2; 378 int reg = -1; 379 if (format[1] == 'n') { 380 reg = instr->VFPNRegValue(precision); 381 } else if (format[1] == 'm') { 382 reg = instr->VFPMRegValue(precision); 383 } else if (format[1] == 'd') { 384 reg = instr->VFPDRegValue(precision); 385 if (format[2] == '+') { 386 int immed8 = instr->Immed8Value(); 387 if (format[0] == 'S') reg += immed8 - 1; 388 if (format[0] == 'D') reg += (immed8 / 2 - 1); 389 } 390 if (format[2] == '+') retval = 3; 391 } else { 392 UNREACHABLE(); 393 } 394 395 if (precision == kSinglePrecision) { 396 PrintSRegister(reg); 397 } else { 398 PrintDRegister(reg); 399 } 400 401 return retval; 402 } 403 404 405 int Decoder::FormatVFPinstruction(Instruction* instr, const char* format) { 406 Print(format); 407 return 0; 408 } 409 410 411 // Print the movw or movt instruction. 412 void Decoder::PrintMovwMovt(Instruction* instr) { 413 int imm = instr->ImmedMovwMovtValue(); 414 int rd = instr->RdValue(); 415 PrintRegister(rd); 416 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 417 ", #%d", imm); 418 } 419 420 421 // FormatOption takes a formatting string and interprets it based on 422 // the current instructions. The format string points to the first 423 // character of the option string (the option escape has already been 424 // consumed by the caller.) FormatOption returns the number of 425 // characters that were consumed from the formatting string. 426 int Decoder::FormatOption(Instruction* instr, const char* format) { 427 switch (format[0]) { 428 case 'a': { // 'a: accumulate multiplies 429 if (instr->Bit(21) == 0) { 430 Print("ul"); 431 } else { 432 Print("la"); 433 } 434 return 1; 435 } 436 case 'b': { // 'b: byte loads or stores 437 if (instr->HasB()) { 438 Print("b"); 439 } 440 return 1; 441 } 442 case 'c': { // 'cond: conditional execution 443 ASSERT(STRING_STARTS_WITH(format, "cond")); 444 PrintCondition(instr); 445 return 4; 446 } 447 case 'd': { // 'd: vmov double immediate. 448 double d = instr->DoubleImmedVmov(); 449 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 450 "#%g", d); 451 return 1; 452 } 453 case 'f': { // 'f: bitfield instructions - v7 and above. 454 uint32_t lsbit = instr->Bits(11, 7); 455 uint32_t width = instr->Bits(20, 16) + 1; 456 if (instr->Bit(21) == 0) { 457 // BFC/BFI: 458 // Bits 20-16 represent most-significant bit. Covert to width. 459 width -= lsbit; 460 ASSERT(width > 0); 461 } 462 ASSERT((width + lsbit) <= 32); 463 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 464 "#%d, #%d", lsbit, width); 465 return 1; 466 } 467 case 'h': { // 'h: halfword operation for extra loads and stores 468 if (instr->HasH()) { 469 Print("h"); 470 } else { 471 Print("b"); 472 } 473 return 1; 474 } 475 case 'i': { // 'i: immediate value from adjacent bits. 476 // Expects tokens in the form imm%02d@%02d, i.e. imm05@07, imm10@16 477 int width = (format[3] - '0') * 10 + (format[4] - '0'); 478 int lsb = (format[6] - '0') * 10 + (format[7] - '0'); 479 480 ASSERT((width >= 1) && (width <= 32)); 481 ASSERT((lsb >= 0) && (lsb <= 31)); 482 ASSERT((width + lsb) <= 32); 483 484 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 485 "%d", 486 instr->Bits(width + lsb - 1, lsb)); 487 return 8; 488 } 489 case 'l': { // 'l: branch and link 490 if (instr->HasLink()) { 491 Print("l"); 492 } 493 return 1; 494 } 495 case 'm': { 496 if (format[1] == 'w') { 497 // 'mw: movt/movw instructions. 498 PrintMovwMovt(instr); 499 return 2; 500 } 501 if (format[1] == 'e') { // 'memop: load/store instructions. 502 ASSERT(STRING_STARTS_WITH(format, "memop")); 503 if (instr->HasL()) { 504 Print("ldr"); 505 } else { 506 if ((instr->Bits(27, 25) == 0) && (instr->Bit(20) == 0) && 507 (instr->Bits(7, 6) == 3) && (instr->Bit(4) == 1)) { 508 if (instr->Bit(5) == 1) { 509 Print("strd"); 510 } else { 511 Print("ldrd"); 512 } 513 return 5; 514 } 515 Print("str"); 516 } 517 return 5; 518 } 519 // 'msg: for simulator break instructions 520 ASSERT(STRING_STARTS_WITH(format, "msg")); 521 byte* str = 522 reinterpret_cast<byte*>(instr->InstructionBits() & 0x0fffffff); 523 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 524 "%s", converter_.NameInCode(str)); 525 return 3; 526 } 527 case 'o': { 528 if ((format[3] == '1') && (format[4] == '2')) { 529 // 'off12: 12-bit offset for load and store instructions 530 ASSERT(STRING_STARTS_WITH(format, "off12")); 531 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 532 "%d", instr->Offset12Value()); 533 return 5; 534 } else if (format[3] == '0') { 535 // 'off0to3and8to19 16-bit immediate encoded in bits 19-8 and 3-0. 536 ASSERT(STRING_STARTS_WITH(format, "off0to3and8to19")); 537 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 538 "%d", 539 (instr->Bits(19, 8) << 4) + 540 instr->Bits(3, 0)); 541 return 15; 542 } 543 // 'off8: 8-bit offset for extra load and store instructions 544 ASSERT(STRING_STARTS_WITH(format, "off8")); 545 int offs8 = (instr->ImmedHValue() << 4) | instr->ImmedLValue(); 546 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 547 "%d", offs8); 548 return 4; 549 } 550 case 'p': { // 'pu: P and U bits for load and store instructions 551 ASSERT(STRING_STARTS_WITH(format, "pu")); 552 PrintPU(instr); 553 return 2; 554 } 555 case 'r': { 556 return FormatRegister(instr, format); 557 } 558 case 's': { 559 if (format[1] == 'h') { // 'shift_op or 'shift_rm or 'shift_sat. 560 if (format[6] == 'o') { // 'shift_op 561 ASSERT(STRING_STARTS_WITH(format, "shift_op")); 562 if (instr->TypeValue() == 0) { 563 PrintShiftRm(instr); 564 } else { 565 ASSERT(instr->TypeValue() == 1); 566 PrintShiftImm(instr); 567 } 568 return 8; 569 } else if (format[6] == 's') { // 'shift_sat. 570 ASSERT(STRING_STARTS_WITH(format, "shift_sat")); 571 PrintShiftSat(instr); 572 return 9; 573 } else { // 'shift_rm 574 ASSERT(STRING_STARTS_WITH(format, "shift_rm")); 575 PrintShiftRm(instr); 576 return 8; 577 } 578 } else if (format[1] == 'v') { // 'svc 579 ASSERT(STRING_STARTS_WITH(format, "svc")); 580 PrintSoftwareInterrupt(instr->SvcValue()); 581 return 3; 582 } else if (format[1] == 'i') { // 'sign: signed extra loads and stores 583 ASSERT(STRING_STARTS_WITH(format, "sign")); 584 if (instr->HasSign()) { 585 Print("s"); 586 } 587 return 4; 588 } 589 // 's: S field of data processing instructions 590 if (instr->HasS()) { 591 Print("s"); 592 } 593 return 1; 594 } 595 case 't': { // 'target: target of branch instructions 596 ASSERT(STRING_STARTS_WITH(format, "target")); 597 int off = (instr->SImmed24Value() << 2) + 8; 598 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 599 "%+d -> %s", 600 off, 601 converter_.NameOfAddress( 602 reinterpret_cast<byte*>(instr) + off)); 603 return 6; 604 } 605 case 'u': { // 'u: signed or unsigned multiplies 606 // The manual gets the meaning of bit 22 backwards in the multiply 607 // instruction overview on page A3.16.2. The instructions that 608 // exist in u and s variants are the following: 609 // smull A4.1.87 610 // umull A4.1.129 611 // umlal A4.1.128 612 // smlal A4.1.76 613 // For these 0 means u and 1 means s. As can be seen on their individual 614 // pages. The other 18 mul instructions have the bit set or unset in 615 // arbitrary ways that are unrelated to the signedness of the instruction. 616 // None of these 18 instructions exist in both a 'u' and an 's' variant. 617 618 if (instr->Bit(22) == 0) { 619 Print("u"); 620 } else { 621 Print("s"); 622 } 623 return 1; 624 } 625 case 'v': { 626 return FormatVFPinstruction(instr, format); 627 } 628 case 'S': 629 case 'D': { 630 return FormatVFPRegister(instr, format); 631 } 632 case 'w': { // 'w: W field of load and store instructions 633 if (instr->HasW()) { 634 Print("!"); 635 } 636 return 1; 637 } 638 default: { 639 UNREACHABLE(); 640 break; 641 } 642 } 643 UNREACHABLE(); 644 return -1; 645 } 646 647 648 // Format takes a formatting string for a whole instruction and prints it into 649 // the output buffer. All escaped options are handed to FormatOption to be 650 // parsed further. 651 void Decoder::Format(Instruction* instr, const char* format) { 652 char cur = *format++; 653 while ((cur != 0) && (out_buffer_pos_ < (out_buffer_.length() - 1))) { 654 if (cur == '\'') { // Single quote is used as the formatting escape. 655 format += FormatOption(instr, format); 656 } else { 657 out_buffer_[out_buffer_pos_++] = cur; 658 } 659 cur = *format++; 660 } 661 out_buffer_[out_buffer_pos_] = '\0'; 662 } 663 664 665 // The disassembler may end up decoding data inlined in the code. We do not want 666 // it to crash if the data does not ressemble any known instruction. 667 #define VERIFY(condition) \ 668 if(!(condition)) { \ 669 Unknown(instr); \ 670 return; \ 671 } 672 673 674 // For currently unimplemented decodings the disassembler calls Unknown(instr) 675 // which will just print "unknown" of the instruction bits. 676 void Decoder::Unknown(Instruction* instr) { 677 Format(instr, "unknown"); 678 } 679 680 681 void Decoder::DecodeType01(Instruction* instr) { 682 int type = instr->TypeValue(); 683 if ((type == 0) && instr->IsSpecialType0()) { 684 // multiply instruction or extra loads and stores 685 if (instr->Bits(7, 4) == 9) { 686 if (instr->Bit(24) == 0) { 687 // multiply instructions 688 if (instr->Bit(23) == 0) { 689 if (instr->Bit(21) == 0) { 690 // The MUL instruction description (A 4.1.33) refers to Rd as being 691 // the destination for the operation, but it confusingly uses the 692 // Rn field to encode it. 693 Format(instr, "mul'cond's 'rn, 'rm, 'rs"); 694 } else { 695 // The MLA instruction description (A 4.1.28) refers to the order 696 // of registers as "Rd, Rm, Rs, Rn". But confusingly it uses the 697 // Rn field to encode the Rd register and the Rd field to encode 698 // the Rn register. 699 Format(instr, "mla'cond's 'rn, 'rm, 'rs, 'rd"); 700 } 701 } else { 702 // The signed/long multiply instructions use the terms RdHi and RdLo 703 // when referring to the target registers. They are mapped to the Rn 704 // and Rd fields as follows: 705 // RdLo == Rd field 706 // RdHi == Rn field 707 // The order of registers is: <RdLo>, <RdHi>, <Rm>, <Rs> 708 Format(instr, "'um'al'cond's 'rd, 'rn, 'rm, 'rs"); 709 } 710 } else { 711 Unknown(instr); // not used by V8 712 } 713 } else if ((instr->Bit(20) == 0) && ((instr->Bits(7, 4) & 0xd) == 0xd)) { 714 // ldrd, strd 715 switch (instr->PUField()) { 716 case da_x: { 717 if (instr->Bit(22) == 0) { 718 Format(instr, "'memop'cond's 'rd, ['rn], -'rm"); 719 } else { 720 Format(instr, "'memop'cond's 'rd, ['rn], #-'off8"); 721 } 722 break; 723 } 724 case ia_x: { 725 if (instr->Bit(22) == 0) { 726 Format(instr, "'memop'cond's 'rd, ['rn], +'rm"); 727 } else { 728 Format(instr, "'memop'cond's 'rd, ['rn], #+'off8"); 729 } 730 break; 731 } 732 case db_x: { 733 if (instr->Bit(22) == 0) { 734 Format(instr, "'memop'cond's 'rd, ['rn, -'rm]'w"); 735 } else { 736 Format(instr, "'memop'cond's 'rd, ['rn, #-'off8]'w"); 737 } 738 break; 739 } 740 case ib_x: { 741 if (instr->Bit(22) == 0) { 742 Format(instr, "'memop'cond's 'rd, ['rn, +'rm]'w"); 743 } else { 744 Format(instr, "'memop'cond's 'rd, ['rn, #+'off8]'w"); 745 } 746 break; 747 } 748 default: { 749 // The PU field is a 2-bit field. 750 UNREACHABLE(); 751 break; 752 } 753 } 754 } else { 755 // extra load/store instructions 756 switch (instr->PUField()) { 757 case da_x: { 758 if (instr->Bit(22) == 0) { 759 Format(instr, "'memop'cond'sign'h 'rd, ['rn], -'rm"); 760 } else { 761 Format(instr, "'memop'cond'sign'h 'rd, ['rn], #-'off8"); 762 } 763 break; 764 } 765 case ia_x: { 766 if (instr->Bit(22) == 0) { 767 Format(instr, "'memop'cond'sign'h 'rd, ['rn], +'rm"); 768 } else { 769 Format(instr, "'memop'cond'sign'h 'rd, ['rn], #+'off8"); 770 } 771 break; 772 } 773 case db_x: { 774 if (instr->Bit(22) == 0) { 775 Format(instr, "'memop'cond'sign'h 'rd, ['rn, -'rm]'w"); 776 } else { 777 Format(instr, "'memop'cond'sign'h 'rd, ['rn, #-'off8]'w"); 778 } 779 break; 780 } 781 case ib_x: { 782 if (instr->Bit(22) == 0) { 783 Format(instr, "'memop'cond'sign'h 'rd, ['rn, +'rm]'w"); 784 } else { 785 Format(instr, "'memop'cond'sign'h 'rd, ['rn, #+'off8]'w"); 786 } 787 break; 788 } 789 default: { 790 // The PU field is a 2-bit field. 791 UNREACHABLE(); 792 break; 793 } 794 } 795 return; 796 } 797 } else if ((type == 0) && instr->IsMiscType0()) { 798 if (instr->Bits(22, 21) == 1) { 799 switch (instr->BitField(7, 4)) { 800 case BX: 801 Format(instr, "bx'cond 'rm"); 802 break; 803 case BLX: 804 Format(instr, "blx'cond 'rm"); 805 break; 806 case BKPT: 807 Format(instr, "bkpt 'off0to3and8to19"); 808 break; 809 default: 810 Unknown(instr); // not used by V8 811 break; 812 } 813 } else if (instr->Bits(22, 21) == 3) { 814 switch (instr->BitField(7, 4)) { 815 case CLZ: 816 Format(instr, "clz'cond 'rd, 'rm"); 817 break; 818 default: 819 Unknown(instr); // not used by V8 820 break; 821 } 822 } else { 823 Unknown(instr); // not used by V8 824 } 825 } else { 826 switch (instr->OpcodeField()) { 827 case AND: { 828 Format(instr, "and'cond's 'rd, 'rn, 'shift_op"); 829 break; 830 } 831 case EOR: { 832 Format(instr, "eor'cond's 'rd, 'rn, 'shift_op"); 833 break; 834 } 835 case SUB: { 836 Format(instr, "sub'cond's 'rd, 'rn, 'shift_op"); 837 break; 838 } 839 case RSB: { 840 Format(instr, "rsb'cond's 'rd, 'rn, 'shift_op"); 841 break; 842 } 843 case ADD: { 844 Format(instr, "add'cond's 'rd, 'rn, 'shift_op"); 845 break; 846 } 847 case ADC: { 848 Format(instr, "adc'cond's 'rd, 'rn, 'shift_op"); 849 break; 850 } 851 case SBC: { 852 Format(instr, "sbc'cond's 'rd, 'rn, 'shift_op"); 853 break; 854 } 855 case RSC: { 856 Format(instr, "rsc'cond's 'rd, 'rn, 'shift_op"); 857 break; 858 } 859 case TST: { 860 if (instr->HasS()) { 861 Format(instr, "tst'cond 'rn, 'shift_op"); 862 } else { 863 Format(instr, "movw'cond 'mw"); 864 } 865 break; 866 } 867 case TEQ: { 868 if (instr->HasS()) { 869 Format(instr, "teq'cond 'rn, 'shift_op"); 870 } else { 871 // Other instructions matching this pattern are handled in the 872 // miscellaneous instructions part above. 873 UNREACHABLE(); 874 } 875 break; 876 } 877 case CMP: { 878 if (instr->HasS()) { 879 Format(instr, "cmp'cond 'rn, 'shift_op"); 880 } else { 881 Format(instr, "movt'cond 'mw"); 882 } 883 break; 884 } 885 case CMN: { 886 if (instr->HasS()) { 887 Format(instr, "cmn'cond 'rn, 'shift_op"); 888 } else { 889 // Other instructions matching this pattern are handled in the 890 // miscellaneous instructions part above. 891 UNREACHABLE(); 892 } 893 break; 894 } 895 case ORR: { 896 Format(instr, "orr'cond's 'rd, 'rn, 'shift_op"); 897 break; 898 } 899 case MOV: { 900 Format(instr, "mov'cond's 'rd, 'shift_op"); 901 break; 902 } 903 case BIC: { 904 Format(instr, "bic'cond's 'rd, 'rn, 'shift_op"); 905 break; 906 } 907 case MVN: { 908 Format(instr, "mvn'cond's 'rd, 'shift_op"); 909 break; 910 } 911 default: { 912 // The Opcode field is a 4-bit field. 913 UNREACHABLE(); 914 break; 915 } 916 } 917 } 918 } 919 920 921 void Decoder::DecodeType2(Instruction* instr) { 922 switch (instr->PUField()) { 923 case da_x: { 924 if (instr->HasW()) { 925 Unknown(instr); // not used in V8 926 return; 927 } 928 Format(instr, "'memop'cond'b 'rd, ['rn], #-'off12"); 929 break; 930 } 931 case ia_x: { 932 if (instr->HasW()) { 933 Unknown(instr); // not used in V8 934 return; 935 } 936 Format(instr, "'memop'cond'b 'rd, ['rn], #+'off12"); 937 break; 938 } 939 case db_x: { 940 Format(instr, "'memop'cond'b 'rd, ['rn, #-'off12]'w"); 941 break; 942 } 943 case ib_x: { 944 Format(instr, "'memop'cond'b 'rd, ['rn, #+'off12]'w"); 945 break; 946 } 947 default: { 948 // The PU field is a 2-bit field. 949 UNREACHABLE(); 950 break; 951 } 952 } 953 } 954 955 956 void Decoder::DecodeType3(Instruction* instr) { 957 switch (instr->PUField()) { 958 case da_x: { 959 VERIFY(!instr->HasW()); 960 Format(instr, "'memop'cond'b 'rd, ['rn], -'shift_rm"); 961 break; 962 } 963 case ia_x: { 964 if (instr->HasW()) { 965 VERIFY(instr->Bits(5, 4) == 0x1); 966 if (instr->Bit(22) == 0x1) { 967 Format(instr, "usat 'rd, #'imm05@16, 'rm'shift_sat"); 968 } else { 969 UNREACHABLE(); // SSAT. 970 } 971 } else { 972 Format(instr, "'memop'cond'b 'rd, ['rn], +'shift_rm"); 973 } 974 break; 975 } 976 case db_x: { 977 Format(instr, "'memop'cond'b 'rd, ['rn, -'shift_rm]'w"); 978 break; 979 } 980 case ib_x: { 981 if (instr->HasW() && (instr->Bits(6, 4) == 0x5)) { 982 uint32_t widthminus1 = static_cast<uint32_t>(instr->Bits(20, 16)); 983 uint32_t lsbit = static_cast<uint32_t>(instr->Bits(11, 7)); 984 uint32_t msbit = widthminus1 + lsbit; 985 if (msbit <= 31) { 986 if (instr->Bit(22)) { 987 Format(instr, "ubfx'cond 'rd, 'rm, 'f"); 988 } else { 989 Format(instr, "sbfx'cond 'rd, 'rm, 'f"); 990 } 991 } else { 992 UNREACHABLE(); 993 } 994 } else if (!instr->HasW() && (instr->Bits(6, 4) == 0x1)) { 995 uint32_t lsbit = static_cast<uint32_t>(instr->Bits(11, 7)); 996 uint32_t msbit = static_cast<uint32_t>(instr->Bits(20, 16)); 997 if (msbit >= lsbit) { 998 if (instr->RmValue() == 15) { 999 Format(instr, "bfc'cond 'rd, 'f"); 1000 } else { 1001 Format(instr, "bfi'cond 'rd, 'rm, 'f"); 1002 } 1003 } else { 1004 UNREACHABLE(); 1005 } 1006 } else { 1007 Format(instr, "'memop'cond'b 'rd, ['rn, +'shift_rm]'w"); 1008 } 1009 break; 1010 } 1011 default: { 1012 // The PU field is a 2-bit field. 1013 UNREACHABLE(); 1014 break; 1015 } 1016 } 1017 } 1018 1019 1020 void Decoder::DecodeType4(Instruction* instr) { 1021 if (instr->Bit(22) != 0) { 1022 // Privileged mode currently not supported. 1023 Unknown(instr); 1024 } else { 1025 if (instr->HasL()) { 1026 Format(instr, "ldm'cond'pu 'rn'w, 'rlist"); 1027 } else { 1028 Format(instr, "stm'cond'pu 'rn'w, 'rlist"); 1029 } 1030 } 1031 } 1032 1033 1034 void Decoder::DecodeType5(Instruction* instr) { 1035 Format(instr, "b'l'cond 'target"); 1036 } 1037 1038 1039 void Decoder::DecodeType6(Instruction* instr) { 1040 DecodeType6CoprocessorIns(instr); 1041 } 1042 1043 1044 int Decoder::DecodeType7(Instruction* instr) { 1045 if (instr->Bit(24) == 1) { 1046 if (instr->SvcValue() >= kStopCode) { 1047 Format(instr, "stop'cond 'svc"); 1048 // Also print the stop message. Its address is encoded 1049 // in the following 4 bytes. 1050 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 1051 "\n %p %08x stop message: %s", 1052 reinterpret_cast<int32_t*>(instr 1053 + Instruction::kInstrSize), 1054 *reinterpret_cast<char**>(instr 1055 + Instruction::kInstrSize), 1056 *reinterpret_cast<char**>(instr 1057 + Instruction::kInstrSize)); 1058 // We have decoded 2 * Instruction::kInstrSize bytes. 1059 return 2 * Instruction::kInstrSize; 1060 } else { 1061 Format(instr, "svc'cond 'svc"); 1062 } 1063 } else { 1064 DecodeTypeVFP(instr); 1065 } 1066 return Instruction::kInstrSize; 1067 } 1068 1069 1070 // void Decoder::DecodeTypeVFP(Instruction* instr) 1071 // vmov: Sn = Rt 1072 // vmov: Rt = Sn 1073 // vcvt: Dd = Sm 1074 // vcvt: Sd = Dm 1075 // Dd = vabs(Dm) 1076 // Dd = vneg(Dm) 1077 // Dd = vadd(Dn, Dm) 1078 // Dd = vsub(Dn, Dm) 1079 // Dd = vmul(Dn, Dm) 1080 // Dd = vdiv(Dn, Dm) 1081 // vcmp(Dd, Dm) 1082 // vmrs 1083 // vmsr 1084 // Dd = vsqrt(Dm) 1085 void Decoder::DecodeTypeVFP(Instruction* instr) { 1086 VERIFY((instr->TypeValue() == 7) && (instr->Bit(24) == 0x0) ); 1087 VERIFY(instr->Bits(11, 9) == 0x5); 1088 1089 if (instr->Bit(4) == 0) { 1090 if (instr->Opc1Value() == 0x7) { 1091 // Other data processing instructions 1092 if ((instr->Opc2Value() == 0x0) && (instr->Opc3Value() == 0x1)) { 1093 // vmov register to register. 1094 if (instr->SzValue() == 0x1) { 1095 Format(instr, "vmov.f64'cond 'Dd, 'Dm"); 1096 } else { 1097 Format(instr, "vmov.f32'cond 'Sd, 'Sm"); 1098 } 1099 } else if ((instr->Opc2Value() == 0x0) && (instr->Opc3Value() == 0x3)) { 1100 // vabs 1101 Format(instr, "vabs.f64'cond 'Dd, 'Dm"); 1102 } else if ((instr->Opc2Value() == 0x1) && (instr->Opc3Value() == 0x1)) { 1103 // vneg 1104 Format(instr, "vneg.f64'cond 'Dd, 'Dm"); 1105 } else if ((instr->Opc2Value() == 0x7) && (instr->Opc3Value() == 0x3)) { 1106 DecodeVCVTBetweenDoubleAndSingle(instr); 1107 } else if ((instr->Opc2Value() == 0x8) && (instr->Opc3Value() & 0x1)) { 1108 DecodeVCVTBetweenFloatingPointAndInteger(instr); 1109 } else if (((instr->Opc2Value() >> 1) == 0x6) && 1110 (instr->Opc3Value() & 0x1)) { 1111 DecodeVCVTBetweenFloatingPointAndInteger(instr); 1112 } else if (((instr->Opc2Value() == 0x4) || (instr->Opc2Value() == 0x5)) && 1113 (instr->Opc3Value() & 0x1)) { 1114 DecodeVCMP(instr); 1115 } else if (((instr->Opc2Value() == 0x1)) && (instr->Opc3Value() == 0x3)) { 1116 Format(instr, "vsqrt.f64'cond 'Dd, 'Dm"); 1117 } else if (instr->Opc3Value() == 0x0) { 1118 if (instr->SzValue() == 0x1) { 1119 Format(instr, "vmov.f64'cond 'Dd, 'd"); 1120 } else { 1121 Unknown(instr); // Not used by V8. 1122 } 1123 } else { 1124 Unknown(instr); // Not used by V8. 1125 } 1126 } else if (instr->Opc1Value() == 0x3) { 1127 if (instr->SzValue() == 0x1) { 1128 if (instr->Opc3Value() & 0x1) { 1129 Format(instr, "vsub.f64'cond 'Dd, 'Dn, 'Dm"); 1130 } else { 1131 Format(instr, "vadd.f64'cond 'Dd, 'Dn, 'Dm"); 1132 } 1133 } else { 1134 Unknown(instr); // Not used by V8. 1135 } 1136 } else if ((instr->Opc1Value() == 0x2) && !(instr->Opc3Value() & 0x1)) { 1137 if (instr->SzValue() == 0x1) { 1138 Format(instr, "vmul.f64'cond 'Dd, 'Dn, 'Dm"); 1139 } else { 1140 Unknown(instr); // Not used by V8. 1141 } 1142 } else if ((instr->Opc1Value() == 0x4) && !(instr->Opc3Value() & 0x1)) { 1143 if (instr->SzValue() == 0x1) { 1144 Format(instr, "vdiv.f64'cond 'Dd, 'Dn, 'Dm"); 1145 } else { 1146 Unknown(instr); // Not used by V8. 1147 } 1148 } else { 1149 Unknown(instr); // Not used by V8. 1150 } 1151 } else { 1152 if ((instr->VCValue() == 0x0) && 1153 (instr->VAValue() == 0x0)) { 1154 DecodeVMOVBetweenCoreAndSinglePrecisionRegisters(instr); 1155 } else if ((instr->VCValue() == 0x0) && 1156 (instr->VAValue() == 0x7) && 1157 (instr->Bits(19, 16) == 0x1)) { 1158 if (instr->VLValue() == 0) { 1159 if (instr->Bits(15, 12) == 0xF) { 1160 Format(instr, "vmsr'cond FPSCR, APSR"); 1161 } else { 1162 Format(instr, "vmsr'cond FPSCR, 'rt"); 1163 } 1164 } else { 1165 if (instr->Bits(15, 12) == 0xF) { 1166 Format(instr, "vmrs'cond APSR, FPSCR"); 1167 } else { 1168 Format(instr, "vmrs'cond 'rt, FPSCR"); 1169 } 1170 } 1171 } 1172 } 1173 } 1174 1175 1176 void Decoder::DecodeVMOVBetweenCoreAndSinglePrecisionRegisters( 1177 Instruction* instr) { 1178 VERIFY((instr->Bit(4) == 1) && (instr->VCValue() == 0x0) && 1179 (instr->VAValue() == 0x0)); 1180 1181 bool to_arm_register = (instr->VLValue() == 0x1); 1182 1183 if (to_arm_register) { 1184 Format(instr, "vmov'cond 'rt, 'Sn"); 1185 } else { 1186 Format(instr, "vmov'cond 'Sn, 'rt"); 1187 } 1188 } 1189 1190 1191 void Decoder::DecodeVCMP(Instruction* instr) { 1192 VERIFY((instr->Bit(4) == 0) && (instr->Opc1Value() == 0x7)); 1193 VERIFY(((instr->Opc2Value() == 0x4) || (instr->Opc2Value() == 0x5)) && 1194 (instr->Opc3Value() & 0x1)); 1195 1196 // Comparison. 1197 bool dp_operation = (instr->SzValue() == 1); 1198 bool raise_exception_for_qnan = (instr->Bit(7) == 0x1); 1199 1200 if (dp_operation && !raise_exception_for_qnan) { 1201 if (instr->Opc2Value() == 0x4) { 1202 Format(instr, "vcmp.f64'cond 'Dd, 'Dm"); 1203 } else if (instr->Opc2Value() == 0x5) { 1204 Format(instr, "vcmp.f64'cond 'Dd, #0.0"); 1205 } else { 1206 Unknown(instr); // invalid 1207 } 1208 } else { 1209 Unknown(instr); // Not used by V8. 1210 } 1211 } 1212 1213 1214 void Decoder::DecodeVCVTBetweenDoubleAndSingle(Instruction* instr) { 1215 VERIFY((instr->Bit(4) == 0) && (instr->Opc1Value() == 0x7)); 1216 VERIFY((instr->Opc2Value() == 0x7) && (instr->Opc3Value() == 0x3)); 1217 1218 bool double_to_single = (instr->SzValue() == 1); 1219 1220 if (double_to_single) { 1221 Format(instr, "vcvt.f32.f64'cond 'Sd, 'Dm"); 1222 } else { 1223 Format(instr, "vcvt.f64.f32'cond 'Dd, 'Sm"); 1224 } 1225 } 1226 1227 1228 void Decoder::DecodeVCVTBetweenFloatingPointAndInteger(Instruction* instr) { 1229 VERIFY((instr->Bit(4) == 0) && (instr->Opc1Value() == 0x7)); 1230 VERIFY(((instr->Opc2Value() == 0x8) && (instr->Opc3Value() & 0x1)) || 1231 (((instr->Opc2Value() >> 1) == 0x6) && (instr->Opc3Value() & 0x1))); 1232 1233 bool to_integer = (instr->Bit(18) == 1); 1234 bool dp_operation = (instr->SzValue() == 1); 1235 if (to_integer) { 1236 bool unsigned_integer = (instr->Bit(16) == 0); 1237 1238 if (dp_operation) { 1239 if (unsigned_integer) { 1240 Format(instr, "vcvt.u32.f64'cond 'Sd, 'Dm"); 1241 } else { 1242 Format(instr, "vcvt.s32.f64'cond 'Sd, 'Dm"); 1243 } 1244 } else { 1245 if (unsigned_integer) { 1246 Format(instr, "vcvt.u32.f32'cond 'Sd, 'Sm"); 1247 } else { 1248 Format(instr, "vcvt.s32.f32'cond 'Sd, 'Sm"); 1249 } 1250 } 1251 } else { 1252 bool unsigned_integer = (instr->Bit(7) == 0); 1253 1254 if (dp_operation) { 1255 if (unsigned_integer) { 1256 Format(instr, "vcvt.f64.u32'cond 'Dd, 'Sm"); 1257 } else { 1258 Format(instr, "vcvt.f64.s32'cond 'Dd, 'Sm"); 1259 } 1260 } else { 1261 if (unsigned_integer) { 1262 Format(instr, "vcvt.f32.u32'cond 'Sd, 'Sm"); 1263 } else { 1264 Format(instr, "vcvt.f32.s32'cond 'Sd, 'Sm"); 1265 } 1266 } 1267 } 1268 } 1269 1270 1271 // Decode Type 6 coprocessor instructions. 1272 // Dm = vmov(Rt, Rt2) 1273 // <Rt, Rt2> = vmov(Dm) 1274 // Ddst = MEM(Rbase + 4*offset). 1275 // MEM(Rbase + 4*offset) = Dsrc. 1276 void Decoder::DecodeType6CoprocessorIns(Instruction* instr) { 1277 VERIFY(instr->TypeValue() == 6); 1278 1279 if (instr->CoprocessorValue() == 0xA) { 1280 switch (instr->OpcodeValue()) { 1281 case 0x8: 1282 case 0xA: 1283 if (instr->HasL()) { 1284 Format(instr, "vldr'cond 'Sd, ['rn - 4*'imm08@00]"); 1285 } else { 1286 Format(instr, "vstr'cond 'Sd, ['rn - 4*'imm08@00]"); 1287 } 1288 break; 1289 case 0xC: 1290 case 0xE: 1291 if (instr->HasL()) { 1292 Format(instr, "vldr'cond 'Sd, ['rn + 4*'imm08@00]"); 1293 } else { 1294 Format(instr, "vstr'cond 'Sd, ['rn + 4*'imm08@00]"); 1295 } 1296 break; 1297 case 0x4: 1298 case 0x5: 1299 case 0x6: 1300 case 0x7: 1301 case 0x9: 1302 case 0xB: { 1303 bool to_vfp_register = (instr->VLValue() == 0x1); 1304 if (to_vfp_register) { 1305 Format(instr, "vldm'cond'pu 'rn'w, {'Sd-'Sd+}"); 1306 } else { 1307 Format(instr, "vstm'cond'pu 'rn'w, {'Sd-'Sd+}"); 1308 } 1309 break; 1310 } 1311 default: 1312 Unknown(instr); // Not used by V8. 1313 } 1314 } else if (instr->CoprocessorValue() == 0xB) { 1315 switch (instr->OpcodeValue()) { 1316 case 0x2: 1317 // Load and store double to two GP registers 1318 if (instr->Bits(7, 4) != 0x1) { 1319 Unknown(instr); // Not used by V8. 1320 } else if (instr->HasL()) { 1321 Format(instr, "vmov'cond 'rt, 'rn, 'Dm"); 1322 } else { 1323 Format(instr, "vmov'cond 'Dm, 'rt, 'rn"); 1324 } 1325 break; 1326 case 0x8: 1327 if (instr->HasL()) { 1328 Format(instr, "vldr'cond 'Dd, ['rn - 4*'imm08@00]"); 1329 } else { 1330 Format(instr, "vstr'cond 'Dd, ['rn - 4*'imm08@00]"); 1331 } 1332 break; 1333 case 0xC: 1334 if (instr->HasL()) { 1335 Format(instr, "vldr'cond 'Dd, ['rn + 4*'imm08@00]"); 1336 } else { 1337 Format(instr, "vstr'cond 'Dd, ['rn + 4*'imm08@00]"); 1338 } 1339 break; 1340 case 0x4: 1341 case 0x5: 1342 case 0x9: { 1343 bool to_vfp_register = (instr->VLValue() == 0x1); 1344 if (to_vfp_register) { 1345 Format(instr, "vldm'cond'pu 'rn'w, {'Dd-'Dd+}"); 1346 } else { 1347 Format(instr, "vstm'cond'pu 'rn'w, {'Dd-'Dd+}"); 1348 } 1349 break; 1350 } 1351 default: 1352 Unknown(instr); // Not used by V8. 1353 } 1354 } else { 1355 Unknown(instr); // Not used by V8. 1356 } 1357 } 1358 1359 #undef VERIFIY 1360 1361 bool Decoder::IsConstantPoolAt(byte* instr_ptr) { 1362 int instruction_bits = *(reinterpret_cast<int*>(instr_ptr)); 1363 return (instruction_bits & kConstantPoolMarkerMask) == kConstantPoolMarker; 1364 } 1365 1366 1367 int Decoder::ConstantPoolSizeAt(byte* instr_ptr) { 1368 if (IsConstantPoolAt(instr_ptr)) { 1369 int instruction_bits = *(reinterpret_cast<int*>(instr_ptr)); 1370 return instruction_bits & kConstantPoolLengthMask; 1371 } else { 1372 return -1; 1373 } 1374 } 1375 1376 1377 // Disassemble the instruction at *instr_ptr into the output buffer. 1378 int Decoder::InstructionDecode(byte* instr_ptr) { 1379 Instruction* instr = Instruction::At(instr_ptr); 1380 // Print raw instruction bytes. 1381 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 1382 "%08x ", 1383 instr->InstructionBits()); 1384 if (instr->ConditionField() == kSpecialCondition) { 1385 Unknown(instr); 1386 return Instruction::kInstrSize; 1387 } 1388 int instruction_bits = *(reinterpret_cast<int*>(instr_ptr)); 1389 if ((instruction_bits & kConstantPoolMarkerMask) == kConstantPoolMarker) { 1390 out_buffer_pos_ += OS::SNPrintF(out_buffer_ + out_buffer_pos_, 1391 "constant pool begin (length %d)", 1392 instruction_bits & 1393 kConstantPoolLengthMask); 1394 return Instruction::kInstrSize; 1395 } 1396 switch (instr->TypeValue()) { 1397 case 0: 1398 case 1: { 1399 DecodeType01(instr); 1400 break; 1401 } 1402 case 2: { 1403 DecodeType2(instr); 1404 break; 1405 } 1406 case 3: { 1407 DecodeType3(instr); 1408 break; 1409 } 1410 case 4: { 1411 DecodeType4(instr); 1412 break; 1413 } 1414 case 5: { 1415 DecodeType5(instr); 1416 break; 1417 } 1418 case 6: { 1419 DecodeType6(instr); 1420 break; 1421 } 1422 case 7: { 1423 return DecodeType7(instr); 1424 } 1425 default: { 1426 // The type field is 3-bits in the ARM encoding. 1427 UNREACHABLE(); 1428 break; 1429 } 1430 } 1431 return Instruction::kInstrSize; 1432 } 1433 1434 1435 } } // namespace v8::internal 1436 1437 1438 1439 //------------------------------------------------------------------------------ 1440 1441 namespace disasm { 1442 1443 1444 const char* NameConverter::NameOfAddress(byte* addr) const { 1445 v8::internal::OS::SNPrintF(tmp_buffer_, "%p", addr); 1446 return tmp_buffer_.start(); 1447 } 1448 1449 1450 const char* NameConverter::NameOfConstant(byte* addr) const { 1451 return NameOfAddress(addr); 1452 } 1453 1454 1455 const char* NameConverter::NameOfCPURegister(int reg) const { 1456 return v8::internal::Registers::Name(reg); 1457 } 1458 1459 1460 const char* NameConverter::NameOfByteCPURegister(int reg) const { 1461 UNREACHABLE(); // ARM does not have the concept of a byte register 1462 return "nobytereg"; 1463 } 1464 1465 1466 const char* NameConverter::NameOfXMMRegister(int reg) const { 1467 UNREACHABLE(); // ARM does not have any XMM registers 1468 return "noxmmreg"; 1469 } 1470 1471 1472 const char* NameConverter::NameInCode(byte* addr) const { 1473 // The default name converter is called for unknown code. So we will not try 1474 // to access any memory. 1475 return ""; 1476 } 1477 1478 1479 //------------------------------------------------------------------------------ 1480 1481 Disassembler::Disassembler(const NameConverter& converter) 1482 : converter_(converter) {} 1483 1484 1485 Disassembler::~Disassembler() {} 1486 1487 1488 int Disassembler::InstructionDecode(v8::internal::Vector<char> buffer, 1489 byte* instruction) { 1490 v8::internal::Decoder d(converter_, buffer); 1491 return d.InstructionDecode(instruction); 1492 } 1493 1494 1495 int Disassembler::ConstantPoolSizeAt(byte* instruction) { 1496 return v8::internal::Decoder::ConstantPoolSizeAt(instruction); 1497 } 1498 1499 1500 void Disassembler::Disassemble(FILE* f, byte* begin, byte* end) { 1501 NameConverter converter; 1502 Disassembler d(converter); 1503 for (byte* pc = begin; pc < end;) { 1504 v8::internal::EmbeddedVector<char, 128> buffer; 1505 buffer[0] = '\0'; 1506 byte* prev_pc = pc; 1507 pc += d.InstructionDecode(buffer, pc); 1508 fprintf(f, "%p %08x %s\n", 1509 prev_pc, *reinterpret_cast<int32_t*>(prev_pc), buffer.start()); 1510 } 1511 } 1512 1513 1514 } // namespace disasm 1515 1516 #endif // V8_TARGET_ARCH_ARM 1517