1 //===-- DWARFCallFrameInfo.cpp ----------------------------------*- C++ -*-===// 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 11 // C Includes 12 // C++ Includes 13 #include <list> 14 15 #include "lldb/Core/Log.h" 16 #include "lldb/Core/Section.h" 17 #include "lldb/Core/ArchSpec.h" 18 #include "lldb/Core/Module.h" 19 #include "lldb/Core/Section.h" 20 #include "lldb/Host/Host.h" 21 #include "lldb/Symbol/DWARFCallFrameInfo.h" 22 #include "lldb/Symbol/ObjectFile.h" 23 #include "lldb/Symbol/UnwindPlan.h" 24 #include "lldb/Target/RegisterContext.h" 25 #include "lldb/Target/Thread.h" 26 27 using namespace lldb; 28 using namespace lldb_private; 29 30 DWARFCallFrameInfo::DWARFCallFrameInfo(ObjectFile& objfile, SectionSP& section_sp, lldb::RegisterKind reg_kind, bool is_eh_frame) : 31 m_objfile (objfile), 32 m_section_sp (section_sp), 33 m_reg_kind (reg_kind), // The flavor of registers that the CFI data uses (enum RegisterKind) 34 m_flags (), 35 m_cie_map (), 36 m_cfi_data (), 37 m_cfi_data_initialized (false), 38 m_fde_index (), 39 m_fde_index_initialized (false), 40 m_is_eh_frame (is_eh_frame) 41 { 42 } 43 44 DWARFCallFrameInfo::~DWARFCallFrameInfo() 45 { 46 } 47 48 49 bool 50 DWARFCallFrameInfo::GetAddressRange (Address addr, AddressRange &range) 51 { 52 FDEEntry fde_entry; 53 if (GetFDEEntryByAddress (addr, fde_entry) == false) 54 return false; 55 range = fde_entry.bounds; 56 return true; 57 } 58 59 bool 60 DWARFCallFrameInfo::GetUnwindPlan (Address addr, UnwindPlan& unwind_plan) 61 { 62 FDEEntry fde_entry; 63 if (GetFDEEntryByAddress (addr, fde_entry) == false) 64 return false; 65 return FDEToUnwindPlan (fde_entry.offset, addr, unwind_plan); 66 } 67 68 bool 69 DWARFCallFrameInfo::GetFDEEntryByAddress (Address addr, FDEEntry& fde_entry) 70 { 71 if (m_section_sp.get() == NULL || m_section_sp->IsEncrypted()) 72 return false; 73 GetFDEIndex(); 74 75 struct FDEEntry searchfde; 76 searchfde.bounds = AddressRange (addr, 1); 77 78 std::vector<FDEEntry>::const_iterator idx; 79 if (m_fde_index.size() == 0) 80 return false; 81 82 idx = std::lower_bound (m_fde_index.begin(), m_fde_index.end(), searchfde); 83 if (idx == m_fde_index.end()) 84 { 85 --idx; 86 } 87 if (idx != m_fde_index.begin() && idx->bounds.GetBaseAddress().GetOffset() != addr.GetOffset()) 88 { 89 --idx; 90 } 91 if (idx->bounds.ContainsFileAddress (addr)) 92 { 93 fde_entry = *idx; 94 return true; 95 } 96 97 return false; 98 } 99 100 const DWARFCallFrameInfo::CIE* 101 DWARFCallFrameInfo::GetCIE(dw_offset_t cie_offset) 102 { 103 cie_map_t::iterator pos = m_cie_map.find(cie_offset); 104 105 if (pos != m_cie_map.end()) 106 { 107 // Parse and cache the CIE 108 if (pos->second.get() == NULL) 109 pos->second = ParseCIE (cie_offset); 110 111 return pos->second.get(); 112 } 113 return NULL; 114 } 115 116 DWARFCallFrameInfo::CIESP 117 DWARFCallFrameInfo::ParseCIE (const dw_offset_t cie_offset) 118 { 119 CIESP cie_sp(new CIE(cie_offset)); 120 dw_offset_t offset = cie_offset; 121 if (m_cfi_data_initialized == false) 122 GetCFIData(); 123 const uint32_t length = m_cfi_data.GetU32(&offset); 124 const dw_offset_t cie_id = m_cfi_data.GetU32(&offset); 125 const dw_offset_t end_offset = cie_offset + length + 4; 126 if (length > 0 && ((!m_is_eh_frame && cie_id == 0xfffffffful) || (m_is_eh_frame && cie_id == 0ul))) 127 { 128 size_t i; 129 // cie.offset = cie_offset; 130 // cie.length = length; 131 // cie.cieID = cieID; 132 cie_sp->ptr_encoding = DW_EH_PE_absptr; 133 cie_sp->version = m_cfi_data.GetU8(&offset); 134 135 for (i=0; i<CFI_AUG_MAX_SIZE; ++i) 136 { 137 cie_sp->augmentation[i] = m_cfi_data.GetU8(&offset); 138 if (cie_sp->augmentation[i] == '\0') 139 { 140 // Zero out remaining bytes in augmentation string 141 for (size_t j = i+1; j<CFI_AUG_MAX_SIZE; ++j) 142 cie_sp->augmentation[j] = '\0'; 143 144 break; 145 } 146 } 147 148 if (i == CFI_AUG_MAX_SIZE && cie_sp->augmentation[CFI_AUG_MAX_SIZE-1] != '\0') 149 { 150 Host::SystemLog (Host::eSystemLogError, "CIE parse error: CIE augmentation string was too large for the fixed sized buffer of %d bytes.\n", CFI_AUG_MAX_SIZE); 151 return cie_sp; 152 } 153 cie_sp->code_align = (uint32_t)m_cfi_data.GetULEB128(&offset); 154 cie_sp->data_align = (int32_t)m_cfi_data.GetSLEB128(&offset); 155 cie_sp->return_addr_reg_num = m_cfi_data.GetU8(&offset); 156 157 if (cie_sp->augmentation[0]) 158 { 159 // Get the length of the eh_frame augmentation data 160 // which starts with a ULEB128 length in bytes 161 const size_t aug_data_len = (size_t)m_cfi_data.GetULEB128(&offset); 162 const size_t aug_data_end = offset + aug_data_len; 163 const size_t aug_str_len = strlen(cie_sp->augmentation); 164 // A 'z' may be present as the first character of the string. 165 // If present, the Augmentation Data field shall be present. 166 // The contents of the Augmentation Data shall be intepreted 167 // according to other characters in the Augmentation String. 168 if (cie_sp->augmentation[0] == 'z') 169 { 170 // Extract the Augmentation Data 171 size_t aug_str_idx = 0; 172 for (aug_str_idx = 1; aug_str_idx < aug_str_len; aug_str_idx++) 173 { 174 char aug = cie_sp->augmentation[aug_str_idx]; 175 switch (aug) 176 { 177 case 'L': 178 // Indicates the presence of one argument in the 179 // Augmentation Data of the CIE, and a corresponding 180 // argument in the Augmentation Data of the FDE. The 181 // argument in the Augmentation Data of the CIE is 182 // 1-byte and represents the pointer encoding used 183 // for the argument in the Augmentation Data of the 184 // FDE, which is the address of a language-specific 185 // data area (LSDA). The size of the LSDA pointer is 186 // specified by the pointer encoding used. 187 m_cfi_data.GetU8(&offset); 188 break; 189 190 case 'P': 191 // Indicates the presence of two arguments in the 192 // Augmentation Data of the cie_sp-> The first argument 193 // is 1-byte and represents the pointer encoding 194 // used for the second argument, which is the 195 // address of a personality routine handler. The 196 // size of the personality routine pointer is 197 // specified by the pointer encoding used. 198 { 199 uint8_t arg_ptr_encoding = m_cfi_data.GetU8(&offset); 200 m_cfi_data.GetGNUEHPointer(&offset, arg_ptr_encoding, LLDB_INVALID_ADDRESS, LLDB_INVALID_ADDRESS, LLDB_INVALID_ADDRESS); 201 } 202 break; 203 204 case 'R': 205 // A 'R' may be present at any position after the 206 // first character of the string. The Augmentation 207 // Data shall include a 1 byte argument that 208 // represents the pointer encoding for the address 209 // pointers used in the FDE. 210 cie_sp->ptr_encoding = m_cfi_data.GetU8(&offset); 211 break; 212 } 213 } 214 } 215 else if (strcmp(cie_sp->augmentation, "eh") == 0) 216 { 217 // If the Augmentation string has the value "eh", then 218 // the EH Data field shall be present 219 } 220 221 // Set the offset to be the end of the augmentation data just in case 222 // we didn't understand any of the data. 223 offset = (uint32_t)aug_data_end; 224 } 225 226 if (end_offset > offset) 227 { 228 cie_sp->inst_offset = offset; 229 cie_sp->inst_length = end_offset - offset; 230 } 231 while (offset < end_offset) 232 { 233 uint8_t inst = m_cfi_data.GetU8(&offset); 234 uint8_t primary_opcode = inst & 0xC0; 235 uint8_t extended_opcode = inst & 0x3F; 236 237 if (extended_opcode == DW_CFA_def_cfa) 238 { 239 // Takes two unsigned LEB128 operands representing a register 240 // number and a (non-factored) offset. The required action 241 // is to define the current CFA rule to use the provided 242 // register and offset. 243 uint32_t reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 244 int op_offset = (int32_t)m_cfi_data.GetULEB128(&offset); 245 cie_sp->initial_row.SetCFARegister (reg_num); 246 cie_sp->initial_row.SetCFAOffset (op_offset); 247 continue; 248 } 249 if (primary_opcode == DW_CFA_offset) 250 { 251 // 0x80 - high 2 bits are 0x2, lower 6 bits are register. 252 // Takes two arguments: an unsigned LEB128 constant representing a 253 // factored offset and a register number. The required action is to 254 // change the rule for the register indicated by the register number 255 // to be an offset(N) rule with a value of 256 // (N = factored offset * data_align). 257 uint32_t reg_num = extended_opcode; 258 int op_offset = (int32_t)m_cfi_data.GetULEB128(&offset) * cie_sp->data_align; 259 UnwindPlan::Row::RegisterLocation reg_location; 260 reg_location.SetAtCFAPlusOffset(op_offset); 261 cie_sp->initial_row.SetRegisterInfo (reg_num, reg_location); 262 continue; 263 } 264 if (extended_opcode == DW_CFA_nop) 265 { 266 continue; 267 } 268 break; // Stop if we hit an unrecognized opcode 269 } 270 } 271 272 return cie_sp; 273 } 274 275 void 276 DWARFCallFrameInfo::GetCFIData() 277 { 278 if (m_cfi_data_initialized == false) 279 { 280 LogSP log(GetLogIfAllCategoriesSet (LIBLLDB_LOG_UNWIND)); 281 if (log) 282 m_objfile.GetModule()->LogMessage(log.get(), "Reading EH frame info"); 283 m_objfile.ReadSectionData (m_section_sp.get(), m_cfi_data); 284 m_cfi_data_initialized = true; 285 } 286 } 287 // Scan through the eh_frame or debug_frame section looking for FDEs and noting the start/end addresses 288 // of the functions and a pointer back to the function's FDE for later expansion. 289 // Internalize CIEs as we come across them. 290 291 void 292 DWARFCallFrameInfo::GetFDEIndex () 293 { 294 if (m_section_sp.get() == NULL || m_section_sp->IsEncrypted()) 295 return; 296 297 if (m_fde_index_initialized) 298 return; 299 300 Mutex::Locker locker(m_fde_index_mutex); 301 302 if (m_fde_index_initialized) // if two threads hit the locker 303 return; 304 305 dw_offset_t offset = 0; 306 if (m_cfi_data_initialized == false) 307 GetCFIData(); 308 while (m_cfi_data.ValidOffsetForDataOfSize (offset, 8)) 309 { 310 const dw_offset_t current_entry = offset; 311 uint32_t len = m_cfi_data.GetU32 (&offset); 312 dw_offset_t next_entry = current_entry + len + 4; 313 dw_offset_t cie_id = m_cfi_data.GetU32 (&offset); 314 315 if (cie_id == 0 || cie_id == UINT32_MAX) 316 { 317 m_cie_map[current_entry] = ParseCIE (current_entry); 318 offset = next_entry; 319 continue; 320 } 321 322 const dw_offset_t cie_offset = current_entry + 4 - cie_id; 323 const CIE *cie = GetCIE (cie_offset); 324 if (cie) 325 { 326 const lldb::addr_t pc_rel_addr = m_section_sp->GetFileAddress(); 327 const lldb::addr_t text_addr = LLDB_INVALID_ADDRESS; 328 const lldb::addr_t data_addr = LLDB_INVALID_ADDRESS; 329 330 lldb::addr_t addr = m_cfi_data.GetGNUEHPointer(&offset, cie->ptr_encoding, pc_rel_addr, text_addr, data_addr); 331 lldb::addr_t length = m_cfi_data.GetGNUEHPointer(&offset, cie->ptr_encoding & DW_EH_PE_MASK_ENCODING, pc_rel_addr, text_addr, data_addr); 332 FDEEntry fde; 333 fde.bounds = AddressRange (addr, length, m_objfile.GetSectionList()); 334 fde.offset = current_entry; 335 m_fde_index.push_back(fde); 336 } 337 else 338 { 339 Host::SystemLog (Host::eSystemLogError, 340 "error: unable to find CIE at 0x%8.8x for cie_id = 0x%8.8x for entry at 0x%8.8x.\n", 341 cie_offset, 342 cie_id, 343 current_entry); 344 } 345 offset = next_entry; 346 } 347 std::sort (m_fde_index.begin(), m_fde_index.end()); 348 m_fde_index_initialized = true; 349 } 350 351 bool 352 DWARFCallFrameInfo::FDEToUnwindPlan (dw_offset_t offset, Address startaddr, UnwindPlan& unwind_plan) 353 { 354 dw_offset_t current_entry = offset; 355 356 if (m_section_sp.get() == NULL || m_section_sp->IsEncrypted()) 357 return false; 358 359 if (m_cfi_data_initialized == false) 360 GetCFIData(); 361 362 uint32_t length = m_cfi_data.GetU32 (&offset); 363 dw_offset_t cie_offset = m_cfi_data.GetU32 (&offset); 364 365 assert (cie_offset != 0 && cie_offset != UINT32_MAX); 366 367 // Translate the CIE_id from the eh_frame format, which 368 // is relative to the FDE offset, into a __eh_frame section 369 // offset 370 if (m_is_eh_frame) 371 { 372 unwind_plan.SetSourceName ("eh_frame CFI"); 373 cie_offset = current_entry + 4 - cie_offset; 374 } 375 else 376 { 377 unwind_plan.SetSourceName ("DWARF CFI"); 378 } 379 380 const CIE *cie = GetCIE (cie_offset); 381 assert (cie != NULL); 382 383 const dw_offset_t end_offset = current_entry + length + 4; 384 385 const lldb::addr_t pc_rel_addr = m_section_sp->GetFileAddress(); 386 const lldb::addr_t text_addr = LLDB_INVALID_ADDRESS; 387 const lldb::addr_t data_addr = LLDB_INVALID_ADDRESS; 388 lldb::addr_t range_base = m_cfi_data.GetGNUEHPointer(&offset, cie->ptr_encoding, pc_rel_addr, text_addr, data_addr); 389 lldb::addr_t range_len = m_cfi_data.GetGNUEHPointer(&offset, cie->ptr_encoding & DW_EH_PE_MASK_ENCODING, pc_rel_addr, text_addr, data_addr); 390 AddressRange range (range_base, m_objfile.GetAddressByteSize(), m_objfile.GetSectionList()); 391 range.SetByteSize (range_len); 392 393 if (cie->augmentation[0] == 'z') 394 { 395 uint32_t aug_data_len = (uint32_t)m_cfi_data.GetULEB128(&offset); 396 offset += aug_data_len; 397 } 398 399 uint32_t reg_num = 0; 400 int32_t op_offset = 0; 401 uint32_t code_align = cie->code_align; 402 int32_t data_align = cie->data_align; 403 404 unwind_plan.SetPlanValidAddressRange (range); 405 UnwindPlan::Row *cie_initial_row = new UnwindPlan::Row; 406 *cie_initial_row = cie->initial_row; 407 UnwindPlan::RowSP row(cie_initial_row); 408 409 unwind_plan.SetRegisterKind (m_reg_kind); 410 411 UnwindPlan::Row::RegisterLocation reg_location; 412 while (m_cfi_data.ValidOffset(offset) && offset < end_offset) 413 { 414 uint8_t inst = m_cfi_data.GetU8(&offset); 415 uint8_t primary_opcode = inst & 0xC0; 416 uint8_t extended_opcode = inst & 0x3F; 417 418 if (primary_opcode) 419 { 420 switch (primary_opcode) 421 { 422 case DW_CFA_advance_loc : // (Row Creation Instruction) 423 { // 0x40 - high 2 bits are 0x1, lower 6 bits are delta 424 // takes a single argument that represents a constant delta. The 425 // required action is to create a new table row with a location 426 // value that is computed by taking the current entry's location 427 // value and adding (delta * code_align). All other 428 // values in the new row are initially identical to the current row. 429 unwind_plan.AppendRow(row); 430 UnwindPlan::Row *newrow = new UnwindPlan::Row; 431 *newrow = *row.get(); 432 row.reset (newrow); 433 row->SlideOffset(extended_opcode * code_align); 434 } 435 break; 436 437 case DW_CFA_offset : 438 { // 0x80 - high 2 bits are 0x2, lower 6 bits are register 439 // takes two arguments: an unsigned LEB128 constant representing a 440 // factored offset and a register number. The required action is to 441 // change the rule for the register indicated by the register number 442 // to be an offset(N) rule with a value of 443 // (N = factored offset * data_align). 444 reg_num = extended_opcode; 445 op_offset = (int32_t)m_cfi_data.GetULEB128(&offset) * data_align; 446 reg_location.SetAtCFAPlusOffset(op_offset); 447 row->SetRegisterInfo (reg_num, reg_location); 448 } 449 break; 450 451 case DW_CFA_restore : 452 { // 0xC0 - high 2 bits are 0x3, lower 6 bits are register 453 // takes a single argument that represents a register number. The 454 // required action is to change the rule for the indicated register 455 // to the rule assigned it by the initial_instructions in the CIE. 456 reg_num = extended_opcode; 457 // We only keep enough register locations around to 458 // unwind what is in our thread, and these are organized 459 // by the register index in that state, so we need to convert our 460 // GCC register number from the EH frame info, to a register index 461 462 if (unwind_plan.IsValidRowIndex(0) && unwind_plan.GetRowAtIndex(0)->GetRegisterInfo(reg_num, reg_location)) 463 row->SetRegisterInfo (reg_num, reg_location); 464 } 465 break; 466 } 467 } 468 else 469 { 470 switch (extended_opcode) 471 { 472 case DW_CFA_nop : // 0x0 473 break; 474 475 case DW_CFA_set_loc : // 0x1 (Row Creation Instruction) 476 { 477 // DW_CFA_set_loc takes a single argument that represents an address. 478 // The required action is to create a new table row using the 479 // specified address as the location. All other values in the new row 480 // are initially identical to the current row. The new location value 481 // should always be greater than the current one. 482 unwind_plan.AppendRow(row); 483 UnwindPlan::Row *newrow = new UnwindPlan::Row; 484 *newrow = *row.get(); 485 row.reset (newrow); 486 row->SetOffset(m_cfi_data.GetPointer(&offset) - startaddr.GetFileAddress()); 487 } 488 break; 489 490 case DW_CFA_advance_loc1 : // 0x2 (Row Creation Instruction) 491 { 492 // takes a single uword argument that represents a constant delta. 493 // This instruction is identical to DW_CFA_advance_loc except for the 494 // encoding and size of the delta argument. 495 unwind_plan.AppendRow(row); 496 UnwindPlan::Row *newrow = new UnwindPlan::Row; 497 *newrow = *row.get(); 498 row.reset (newrow); 499 row->SlideOffset (m_cfi_data.GetU8(&offset) * code_align); 500 } 501 break; 502 503 case DW_CFA_advance_loc2 : // 0x3 (Row Creation Instruction) 504 { 505 // takes a single uword argument that represents a constant delta. 506 // This instruction is identical to DW_CFA_advance_loc except for the 507 // encoding and size of the delta argument. 508 unwind_plan.AppendRow(row); 509 UnwindPlan::Row *newrow = new UnwindPlan::Row; 510 *newrow = *row.get(); 511 row.reset (newrow); 512 row->SlideOffset (m_cfi_data.GetU16(&offset) * code_align); 513 } 514 break; 515 516 case DW_CFA_advance_loc4 : // 0x4 (Row Creation Instruction) 517 { 518 // takes a single uword argument that represents a constant delta. 519 // This instruction is identical to DW_CFA_advance_loc except for the 520 // encoding and size of the delta argument. 521 unwind_plan.AppendRow(row); 522 UnwindPlan::Row *newrow = new UnwindPlan::Row; 523 *newrow = *row.get(); 524 row.reset (newrow); 525 row->SlideOffset (m_cfi_data.GetU32(&offset) * code_align); 526 } 527 break; 528 529 case DW_CFA_offset_extended : // 0x5 530 { 531 // takes two unsigned LEB128 arguments representing a register number 532 // and a factored offset. This instruction is identical to DW_CFA_offset 533 // except for the encoding and size of the register argument. 534 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 535 op_offset = (int32_t)m_cfi_data.GetULEB128(&offset) * data_align; 536 reg_location.SetAtCFAPlusOffset(op_offset); 537 row->SetRegisterInfo (reg_num, reg_location); 538 } 539 break; 540 541 case DW_CFA_restore_extended : // 0x6 542 { 543 // takes a single unsigned LEB128 argument that represents a register 544 // number. This instruction is identical to DW_CFA_restore except for 545 // the encoding and size of the register argument. 546 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 547 if (unwind_plan.IsValidRowIndex(0) && unwind_plan.GetRowAtIndex(0)->GetRegisterInfo(reg_num, reg_location)) 548 row->SetRegisterInfo (reg_num, reg_location); 549 } 550 break; 551 552 case DW_CFA_undefined : // 0x7 553 { 554 // takes a single unsigned LEB128 argument that represents a register 555 // number. The required action is to set the rule for the specified 556 // register to undefined. 557 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 558 reg_location.SetUndefined(); 559 row->SetRegisterInfo (reg_num, reg_location); 560 } 561 break; 562 563 case DW_CFA_same_value : // 0x8 564 { 565 // takes a single unsigned LEB128 argument that represents a register 566 // number. The required action is to set the rule for the specified 567 // register to same value. 568 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 569 reg_location.SetSame(); 570 row->SetRegisterInfo (reg_num, reg_location); 571 } 572 break; 573 574 case DW_CFA_register : // 0x9 575 { 576 // takes two unsigned LEB128 arguments representing register numbers. 577 // The required action is to set the rule for the first register to be 578 // the second register. 579 580 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 581 uint32_t other_reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 582 reg_location.SetInRegister(other_reg_num); 583 row->SetRegisterInfo (reg_num, reg_location); 584 } 585 break; 586 587 case DW_CFA_remember_state : // 0xA 588 { 589 // These instructions define a stack of information. Encountering the 590 // DW_CFA_remember_state instruction means to save the rules for every 591 // register on the current row on the stack. Encountering the 592 // DW_CFA_restore_state instruction means to pop the set of rules off 593 // the stack and place them in the current row. (This operation is 594 // useful for compilers that move epilogue code into the body of a 595 // function.) 596 unwind_plan.AppendRow (row); 597 UnwindPlan::Row *newrow = new UnwindPlan::Row; 598 *newrow = *row.get(); 599 row.reset (newrow); 600 } 601 break; 602 603 case DW_CFA_restore_state : // 0xB 604 // These instructions define a stack of information. Encountering the 605 // DW_CFA_remember_state instruction means to save the rules for every 606 // register on the current row on the stack. Encountering the 607 // DW_CFA_restore_state instruction means to pop the set of rules off 608 // the stack and place them in the current row. (This operation is 609 // useful for compilers that move epilogue code into the body of a 610 // function.) 611 { 612 row = unwind_plan.GetRowAtIndex(unwind_plan.GetRowCount() - 1); 613 } 614 break; 615 616 case DW_CFA_def_cfa : // 0xC (CFA Definition Instruction) 617 { 618 // Takes two unsigned LEB128 operands representing a register 619 // number and a (non-factored) offset. The required action 620 // is to define the current CFA rule to use the provided 621 // register and offset. 622 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 623 op_offset = (int32_t)m_cfi_data.GetULEB128(&offset); 624 row->SetCFARegister (reg_num); 625 row->SetCFAOffset (op_offset); 626 } 627 break; 628 629 case DW_CFA_def_cfa_register : // 0xD (CFA Definition Instruction) 630 { 631 // takes a single unsigned LEB128 argument representing a register 632 // number. The required action is to define the current CFA rule to 633 // use the provided register (but to keep the old offset). 634 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 635 row->SetCFARegister (reg_num); 636 } 637 break; 638 639 case DW_CFA_def_cfa_offset : // 0xE (CFA Definition Instruction) 640 { 641 // Takes a single unsigned LEB128 operand representing a 642 // (non-factored) offset. The required action is to define 643 // the current CFA rule to use the provided offset (but 644 // to keep the old register). 645 op_offset = (int32_t)m_cfi_data.GetULEB128(&offset); 646 row->SetCFAOffset (op_offset); 647 } 648 break; 649 650 case DW_CFA_def_cfa_expression : // 0xF (CFA Definition Instruction) 651 { 652 size_t block_len = (size_t)m_cfi_data.GetULEB128(&offset); 653 offset += (uint32_t)block_len; 654 } 655 break; 656 657 case DW_CFA_expression : // 0x10 658 { 659 // Takes two operands: an unsigned LEB128 value representing 660 // a register number, and a DW_FORM_block value representing a DWARF 661 // expression. The required action is to change the rule for the 662 // register indicated by the register number to be an expression(E) 663 // rule where E is the DWARF expression. That is, the DWARF 664 // expression computes the address. The value of the CFA is 665 // pushed on the DWARF evaluation stack prior to execution of 666 // the DWARF expression. 667 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 668 uint32_t block_len = (uint32_t)m_cfi_data.GetULEB128(&offset); 669 const uint8_t *block_data = (uint8_t *)m_cfi_data.GetData(&offset, block_len); 670 671 reg_location.SetAtDWARFExpression(block_data, block_len); 672 row->SetRegisterInfo (reg_num, reg_location); 673 } 674 break; 675 676 case DW_CFA_offset_extended_sf : // 0x11 677 { 678 // takes two operands: an unsigned LEB128 value representing a 679 // register number and a signed LEB128 factored offset. This 680 // instruction is identical to DW_CFA_offset_extended except 681 //that the second operand is signed and factored. 682 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 683 op_offset = (int32_t)m_cfi_data.GetSLEB128(&offset) * data_align; 684 reg_location.SetAtCFAPlusOffset(op_offset); 685 row->SetRegisterInfo (reg_num, reg_location); 686 } 687 break; 688 689 case DW_CFA_def_cfa_sf : // 0x12 (CFA Definition Instruction) 690 { 691 // Takes two operands: an unsigned LEB128 value representing 692 // a register number and a signed LEB128 factored offset. 693 // This instruction is identical to DW_CFA_def_cfa except 694 // that the second operand is signed and factored. 695 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 696 op_offset = (int32_t)m_cfi_data.GetSLEB128(&offset) * data_align; 697 row->SetCFARegister (reg_num); 698 row->SetCFAOffset (op_offset); 699 } 700 break; 701 702 case DW_CFA_def_cfa_offset_sf : // 0x13 (CFA Definition Instruction) 703 { 704 // takes a signed LEB128 operand representing a factored 705 // offset. This instruction is identical to DW_CFA_def_cfa_offset 706 // except that the operand is signed and factored. 707 op_offset = (int32_t)m_cfi_data.GetSLEB128(&offset) * data_align; 708 row->SetCFAOffset (op_offset); 709 } 710 break; 711 712 case DW_CFA_val_expression : // 0x16 713 { 714 // takes two operands: an unsigned LEB128 value representing a register 715 // number, and a DW_FORM_block value representing a DWARF expression. 716 // The required action is to change the rule for the register indicated 717 // by the register number to be a val_expression(E) rule where E is the 718 // DWARF expression. That is, the DWARF expression computes the value of 719 // the given register. The value of the CFA is pushed on the DWARF 720 // evaluation stack prior to execution of the DWARF expression. 721 reg_num = (uint32_t)m_cfi_data.GetULEB128(&offset); 722 uint32_t block_len = (uint32_t)m_cfi_data.GetULEB128(&offset); 723 const uint8_t* block_data = (uint8_t*)m_cfi_data.GetData(&offset, block_len); 724 //#if defined(__i386__) || defined(__x86_64__) 725 // // The EH frame info for EIP and RIP contains code that looks for traps to 726 // // be a specific type and increments the PC. 727 // // For i386: 728 // // DW_CFA_val_expression where: 729 // // eip = DW_OP_breg6(+28), DW_OP_deref, DW_OP_dup, DW_OP_plus_uconst(0x34), 730 // // DW_OP_deref, DW_OP_swap, DW_OP_plus_uconst(0), DW_OP_deref, 731 // // DW_OP_dup, DW_OP_lit3, DW_OP_ne, DW_OP_swap, DW_OP_lit4, DW_OP_ne, 732 // // DW_OP_and, DW_OP_plus 733 // // This basically does a: 734 // // eip = ucontenxt.mcontext32->gpr.eip; 735 // // if (ucontenxt.mcontext32->exc.trapno != 3 && ucontenxt.mcontext32->exc.trapno != 4) 736 // // eip++; 737 // // 738 // // For x86_64: 739 // // DW_CFA_val_expression where: 740 // // rip = DW_OP_breg3(+48), DW_OP_deref, DW_OP_dup, DW_OP_plus_uconst(0x90), DW_OP_deref, 741 // // DW_OP_swap, DW_OP_plus_uconst(0), DW_OP_deref_size(4), DW_OP_dup, DW_OP_lit3, 742 // // DW_OP_ne, DW_OP_swap, DW_OP_lit4, DW_OP_ne, DW_OP_and, DW_OP_plus 743 // // This basically does a: 744 // // rip = ucontenxt.mcontext64->gpr.rip; 745 // // if (ucontenxt.mcontext64->exc.trapno != 3 && ucontenxt.mcontext64->exc.trapno != 4) 746 // // rip++; 747 // // The trap comparisons and increments are not needed as it hoses up the unwound PC which 748 // // is expected to point at least past the instruction that causes the fault/trap. So we 749 // // take it out by trimming the expression right at the first "DW_OP_swap" opcodes 750 // if (block_data != NULL && thread->GetPCRegNum(Thread::GCC) == reg_num) 751 // { 752 // if (thread->Is64Bit()) 753 // { 754 // if (block_len > 9 && block_data[8] == DW_OP_swap && block_data[9] == DW_OP_plus_uconst) 755 // block_len = 8; 756 // } 757 // else 758 // { 759 // if (block_len > 8 && block_data[7] == DW_OP_swap && block_data[8] == DW_OP_plus_uconst) 760 // block_len = 7; 761 // } 762 // } 763 //#endif 764 reg_location.SetIsDWARFExpression(block_data, block_len); 765 row->SetRegisterInfo (reg_num, reg_location); 766 } 767 break; 768 769 case DW_CFA_val_offset : // 0x14 770 case DW_CFA_val_offset_sf : // 0x15 771 default: 772 break; 773 } 774 } 775 } 776 unwind_plan.AppendRow(row); 777 778 return true; 779 } 780