1 //===-- StackFrame.cpp ----------------------------------------------------===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 9 #include "lldb/Target/StackFrame.h" 10 #include "lldb/Core/Debugger.h" 11 #include "lldb/Core/Disassembler.h" 12 #include "lldb/Core/FormatEntity.h" 13 #include "lldb/Core/Mangled.h" 14 #include "lldb/Core/Module.h" 15 #include "lldb/Core/Value.h" 16 #include "lldb/Core/ValueObjectConstResult.h" 17 #include "lldb/Core/ValueObjectMemory.h" 18 #include "lldb/Core/ValueObjectVariable.h" 19 #include "lldb/Symbol/CompileUnit.h" 20 #include "lldb/Symbol/Function.h" 21 #include "lldb/Symbol/Symbol.h" 22 #include "lldb/Symbol/SymbolContextScope.h" 23 #include "lldb/Symbol/SymbolFile.h" 24 #include "lldb/Symbol/Type.h" 25 #include "lldb/Symbol/VariableList.h" 26 #include "lldb/Target/ABI.h" 27 #include "lldb/Target/ExecutionContext.h" 28 #include "lldb/Target/Process.h" 29 #include "lldb/Target/RegisterContext.h" 30 #include "lldb/Target/StackFrameRecognizer.h" 31 #include "lldb/Target/Target.h" 32 #include "lldb/Target/Thread.h" 33 #include "lldb/Utility/LLDBLog.h" 34 #include "lldb/Utility/Log.h" 35 #include "lldb/Utility/RegisterValue.h" 36 37 #include "lldb/lldb-enumerations.h" 38 39 #include <memory> 40 41 using namespace lldb; 42 using namespace lldb_private; 43 44 // The first bits in the flags are reserved for the SymbolContext::Scope bits 45 // so we know if we have tried to look up information in our internal symbol 46 // context (m_sc) already. 47 #define RESOLVED_FRAME_CODE_ADDR (uint32_t(eSymbolContextLastItem) << 1) 48 #define RESOLVED_FRAME_ID_SYMBOL_SCOPE (RESOLVED_FRAME_CODE_ADDR << 1) 49 #define GOT_FRAME_BASE (RESOLVED_FRAME_ID_SYMBOL_SCOPE << 1) 50 #define RESOLVED_VARIABLES (GOT_FRAME_BASE << 1) 51 #define RESOLVED_GLOBAL_VARIABLES (RESOLVED_VARIABLES << 1) 52 53 StackFrame::StackFrame(const ThreadSP &thread_sp, user_id_t frame_idx, 54 user_id_t unwind_frame_index, addr_t cfa, 55 bool cfa_is_valid, addr_t pc, StackFrame::Kind kind, 56 bool behaves_like_zeroth_frame, 57 const SymbolContext *sc_ptr) 58 : m_thread_wp(thread_sp), m_frame_index(frame_idx), 59 m_concrete_frame_index(unwind_frame_index), m_reg_context_sp(), 60 m_id(pc, cfa, nullptr), m_frame_code_addr(pc), m_sc(), m_flags(), 61 m_frame_base(), m_frame_base_error(), m_cfa_is_valid(cfa_is_valid), 62 m_stack_frame_kind(kind), 63 m_behaves_like_zeroth_frame(behaves_like_zeroth_frame), 64 m_variable_list_sp(), m_variable_list_value_objects(), 65 m_recognized_frame_sp(), m_disassembly(), m_mutex() { 66 // If we don't have a CFA value, use the frame index for our StackID so that 67 // recursive functions properly aren't confused with one another on a history 68 // stack. 69 if (IsHistorical() && !m_cfa_is_valid) { 70 m_id.SetCFA(m_frame_index); 71 } 72 73 if (sc_ptr != nullptr) { 74 m_sc = *sc_ptr; 75 m_flags.Set(m_sc.GetResolvedMask()); 76 } 77 } 78 79 StackFrame::StackFrame(const ThreadSP &thread_sp, user_id_t frame_idx, 80 user_id_t unwind_frame_index, 81 const RegisterContextSP ®_context_sp, addr_t cfa, 82 addr_t pc, bool behaves_like_zeroth_frame, 83 const SymbolContext *sc_ptr) 84 : m_thread_wp(thread_sp), m_frame_index(frame_idx), 85 m_concrete_frame_index(unwind_frame_index), 86 m_reg_context_sp(reg_context_sp), m_id(pc, cfa, nullptr), 87 m_frame_code_addr(pc), m_sc(), m_flags(), m_frame_base(), 88 m_frame_base_error(), m_cfa_is_valid(true), 89 m_stack_frame_kind(StackFrame::Kind::Regular), 90 m_behaves_like_zeroth_frame(behaves_like_zeroth_frame), 91 m_variable_list_sp(), m_variable_list_value_objects(), 92 m_recognized_frame_sp(), m_disassembly(), m_mutex() { 93 if (sc_ptr != nullptr) { 94 m_sc = *sc_ptr; 95 m_flags.Set(m_sc.GetResolvedMask()); 96 } 97 98 if (reg_context_sp && !m_sc.target_sp) { 99 m_sc.target_sp = reg_context_sp->CalculateTarget(); 100 if (m_sc.target_sp) 101 m_flags.Set(eSymbolContextTarget); 102 } 103 } 104 105 StackFrame::StackFrame(const ThreadSP &thread_sp, user_id_t frame_idx, 106 user_id_t unwind_frame_index, 107 const RegisterContextSP ®_context_sp, addr_t cfa, 108 const Address &pc_addr, bool behaves_like_zeroth_frame, 109 const SymbolContext *sc_ptr) 110 : m_thread_wp(thread_sp), m_frame_index(frame_idx), 111 m_concrete_frame_index(unwind_frame_index), 112 m_reg_context_sp(reg_context_sp), 113 m_id(pc_addr.GetLoadAddress(thread_sp->CalculateTarget().get()), cfa, 114 nullptr), 115 m_frame_code_addr(pc_addr), m_sc(), m_flags(), m_frame_base(), 116 m_frame_base_error(), m_cfa_is_valid(true), 117 m_stack_frame_kind(StackFrame::Kind::Regular), 118 m_behaves_like_zeroth_frame(behaves_like_zeroth_frame), 119 m_variable_list_sp(), m_variable_list_value_objects(), 120 m_recognized_frame_sp(), m_disassembly(), m_mutex() { 121 if (sc_ptr != nullptr) { 122 m_sc = *sc_ptr; 123 m_flags.Set(m_sc.GetResolvedMask()); 124 } 125 126 if (!m_sc.target_sp && reg_context_sp) { 127 m_sc.target_sp = reg_context_sp->CalculateTarget(); 128 if (m_sc.target_sp) 129 m_flags.Set(eSymbolContextTarget); 130 } 131 132 ModuleSP pc_module_sp(pc_addr.GetModule()); 133 if (!m_sc.module_sp || m_sc.module_sp != pc_module_sp) { 134 if (pc_module_sp) { 135 m_sc.module_sp = pc_module_sp; 136 m_flags.Set(eSymbolContextModule); 137 } else { 138 m_sc.module_sp.reset(); 139 } 140 } 141 } 142 143 StackFrame::~StackFrame() = default; 144 145 StackID &StackFrame::GetStackID() { 146 std::lock_guard<std::recursive_mutex> guard(m_mutex); 147 // Make sure we have resolved the StackID object's symbol context scope if we 148 // already haven't looked it up. 149 150 if (m_flags.IsClear(RESOLVED_FRAME_ID_SYMBOL_SCOPE)) { 151 if (m_id.GetSymbolContextScope()) { 152 // We already have a symbol context scope, we just don't have our flag 153 // bit set. 154 m_flags.Set(RESOLVED_FRAME_ID_SYMBOL_SCOPE); 155 } else { 156 // Calculate the frame block and use this for the stack ID symbol context 157 // scope if we have one. 158 SymbolContextScope *scope = GetFrameBlock(); 159 if (scope == nullptr) { 160 // We don't have a block, so use the symbol 161 if (m_flags.IsClear(eSymbolContextSymbol)) 162 GetSymbolContext(eSymbolContextSymbol); 163 164 // It is ok if m_sc.symbol is nullptr here 165 scope = m_sc.symbol; 166 } 167 // Set the symbol context scope (the accessor will set the 168 // RESOLVED_FRAME_ID_SYMBOL_SCOPE bit in m_flags). 169 SetSymbolContextScope(scope); 170 } 171 } 172 return m_id; 173 } 174 175 uint32_t StackFrame::GetFrameIndex() const { 176 ThreadSP thread_sp = GetThread(); 177 if (thread_sp) 178 return thread_sp->GetStackFrameList()->GetVisibleStackFrameIndex( 179 m_frame_index); 180 else 181 return m_frame_index; 182 } 183 184 void StackFrame::SetSymbolContextScope(SymbolContextScope *symbol_scope) { 185 std::lock_guard<std::recursive_mutex> guard(m_mutex); 186 m_flags.Set(RESOLVED_FRAME_ID_SYMBOL_SCOPE); 187 m_id.SetSymbolContextScope(symbol_scope); 188 } 189 190 const Address &StackFrame::GetFrameCodeAddress() { 191 std::lock_guard<std::recursive_mutex> guard(m_mutex); 192 if (m_flags.IsClear(RESOLVED_FRAME_CODE_ADDR) && 193 !m_frame_code_addr.IsSectionOffset()) { 194 m_flags.Set(RESOLVED_FRAME_CODE_ADDR); 195 196 // Resolve the PC into a temporary address because if ResolveLoadAddress 197 // fails to resolve the address, it will clear the address object... 198 ThreadSP thread_sp(GetThread()); 199 if (thread_sp) { 200 TargetSP target_sp(thread_sp->CalculateTarget()); 201 if (target_sp) { 202 const bool allow_section_end = true; 203 if (m_frame_code_addr.SetOpcodeLoadAddress( 204 m_frame_code_addr.GetOffset(), target_sp.get(), 205 AddressClass::eCode, allow_section_end)) { 206 ModuleSP module_sp(m_frame_code_addr.GetModule()); 207 if (module_sp) { 208 m_sc.module_sp = module_sp; 209 m_flags.Set(eSymbolContextModule); 210 } 211 } 212 } 213 } 214 } 215 return m_frame_code_addr; 216 } 217 218 // This can't be rewritten into a call to 219 // RegisterContext::GetPCForSymbolication because this 220 // StackFrame may have been constructed with a special pc, 221 // e.g. tail-call artificial frames. 222 Address StackFrame::GetFrameCodeAddressForSymbolication() { 223 Address lookup_addr(GetFrameCodeAddress()); 224 if (!lookup_addr.IsValid()) 225 return lookup_addr; 226 if (m_behaves_like_zeroth_frame) 227 return lookup_addr; 228 229 addr_t offset = lookup_addr.GetOffset(); 230 if (offset > 0) { 231 lookup_addr.SetOffset(offset - 1); 232 } else { 233 // lookup_addr is the start of a section. We need do the math on the 234 // actual load address and re-compute the section. We're working with 235 // a 'noreturn' function at the end of a section. 236 TargetSP target_sp = CalculateTarget(); 237 if (target_sp) { 238 addr_t addr_minus_one = lookup_addr.GetOpcodeLoadAddress( 239 target_sp.get(), AddressClass::eCode) - 240 1; 241 lookup_addr.SetOpcodeLoadAddress(addr_minus_one, target_sp.get()); 242 } 243 } 244 return lookup_addr; 245 } 246 247 bool StackFrame::ChangePC(addr_t pc) { 248 std::lock_guard<std::recursive_mutex> guard(m_mutex); 249 // We can't change the pc value of a history stack frame - it is immutable. 250 if (IsHistorical()) 251 return false; 252 m_frame_code_addr.SetRawAddress(pc); 253 m_sc.Clear(false); 254 m_flags.Reset(0); 255 ThreadSP thread_sp(GetThread()); 256 if (thread_sp) 257 thread_sp->ClearStackFrames(); 258 return true; 259 } 260 261 const char *StackFrame::Disassemble() { 262 std::lock_guard<std::recursive_mutex> guard(m_mutex); 263 if (!m_disassembly.Empty()) 264 return m_disassembly.GetData(); 265 266 ExecutionContext exe_ctx(shared_from_this()); 267 if (Target *target = exe_ctx.GetTargetPtr()) { 268 Disassembler::Disassemble(target->GetDebugger(), target->GetArchitecture(), 269 *this, m_disassembly); 270 } 271 272 return m_disassembly.Empty() ? nullptr : m_disassembly.GetData(); 273 } 274 275 Block *StackFrame::GetFrameBlock() { 276 if (m_sc.block == nullptr && m_flags.IsClear(eSymbolContextBlock)) 277 GetSymbolContext(eSymbolContextBlock); 278 279 if (m_sc.block) { 280 Block *inline_block = m_sc.block->GetContainingInlinedBlock(); 281 if (inline_block) { 282 // Use the block with the inlined function info as the frame block we 283 // want this frame to have only the variables for the inlined function 284 // and its non-inlined block child blocks. 285 return inline_block; 286 } else { 287 // This block is not contained within any inlined function blocks with so 288 // we want to use the top most function block. 289 return &m_sc.function->GetBlock(false); 290 } 291 } 292 return nullptr; 293 } 294 295 // Get the symbol context if we already haven't done so by resolving the 296 // PC address as much as possible. This way when we pass around a 297 // StackFrame object, everyone will have as much information as possible and no 298 // one will ever have to look things up manually. 299 const SymbolContext & 300 StackFrame::GetSymbolContext(SymbolContextItem resolve_scope) { 301 std::lock_guard<std::recursive_mutex> guard(m_mutex); 302 // Copy our internal symbol context into "sc". 303 if ((m_flags.Get() & resolve_scope) != resolve_scope) { 304 uint32_t resolved = 0; 305 306 // If the target was requested add that: 307 if (!m_sc.target_sp) { 308 m_sc.target_sp = CalculateTarget(); 309 if (m_sc.target_sp) 310 resolved |= eSymbolContextTarget; 311 } 312 313 // Resolve our PC to section offset if we haven't already done so and if we 314 // don't have a module. The resolved address section will contain the 315 // module to which it belongs 316 if (!m_sc.module_sp && m_flags.IsClear(RESOLVED_FRAME_CODE_ADDR)) 317 GetFrameCodeAddress(); 318 319 // If this is not frame zero, then we need to subtract 1 from the PC value 320 // when doing address lookups since the PC will be on the instruction 321 // following the function call instruction... 322 Address lookup_addr(GetFrameCodeAddressForSymbolication()); 323 324 if (m_sc.module_sp) { 325 // We have something in our stack frame symbol context, lets check if we 326 // haven't already tried to lookup one of those things. If we haven't 327 // then we will do the query. 328 329 SymbolContextItem actual_resolve_scope = SymbolContextItem(0); 330 331 if (resolve_scope & eSymbolContextCompUnit) { 332 if (m_flags.IsClear(eSymbolContextCompUnit)) { 333 if (m_sc.comp_unit) 334 resolved |= eSymbolContextCompUnit; 335 else 336 actual_resolve_scope |= eSymbolContextCompUnit; 337 } 338 } 339 340 if (resolve_scope & eSymbolContextFunction) { 341 if (m_flags.IsClear(eSymbolContextFunction)) { 342 if (m_sc.function) 343 resolved |= eSymbolContextFunction; 344 else 345 actual_resolve_scope |= eSymbolContextFunction; 346 } 347 } 348 349 if (resolve_scope & eSymbolContextBlock) { 350 if (m_flags.IsClear(eSymbolContextBlock)) { 351 if (m_sc.block) 352 resolved |= eSymbolContextBlock; 353 else 354 actual_resolve_scope |= eSymbolContextBlock; 355 } 356 } 357 358 if (resolve_scope & eSymbolContextSymbol) { 359 if (m_flags.IsClear(eSymbolContextSymbol)) { 360 if (m_sc.symbol) 361 resolved |= eSymbolContextSymbol; 362 else 363 actual_resolve_scope |= eSymbolContextSymbol; 364 } 365 } 366 367 if (resolve_scope & eSymbolContextLineEntry) { 368 if (m_flags.IsClear(eSymbolContextLineEntry)) { 369 if (m_sc.line_entry.IsValid()) 370 resolved |= eSymbolContextLineEntry; 371 else 372 actual_resolve_scope |= eSymbolContextLineEntry; 373 } 374 } 375 376 if (actual_resolve_scope) { 377 // We might be resolving less information than what is already in our 378 // current symbol context so resolve into a temporary symbol context 379 // "sc" so we don't clear out data we have already found in "m_sc" 380 SymbolContext sc; 381 // Set flags that indicate what we have tried to resolve 382 resolved |= m_sc.module_sp->ResolveSymbolContextForAddress( 383 lookup_addr, actual_resolve_scope, sc); 384 // Only replace what we didn't already have as we may have information 385 // for an inlined function scope that won't match what a standard 386 // lookup by address would match 387 if ((resolved & eSymbolContextCompUnit) && m_sc.comp_unit == nullptr) 388 m_sc.comp_unit = sc.comp_unit; 389 if ((resolved & eSymbolContextFunction) && m_sc.function == nullptr) 390 m_sc.function = sc.function; 391 if ((resolved & eSymbolContextBlock) && m_sc.block == nullptr) 392 m_sc.block = sc.block; 393 if ((resolved & eSymbolContextSymbol) && m_sc.symbol == nullptr) 394 m_sc.symbol = sc.symbol; 395 if ((resolved & eSymbolContextLineEntry) && 396 !m_sc.line_entry.IsValid()) { 397 m_sc.line_entry = sc.line_entry; 398 m_sc.line_entry.ApplyFileMappings(m_sc.target_sp); 399 } 400 } 401 } else { 402 // If we don't have a module, then we can't have the compile unit, 403 // function, block, line entry or symbol, so we can safely call 404 // ResolveSymbolContextForAddress with our symbol context member m_sc. 405 if (m_sc.target_sp) { 406 resolved |= m_sc.target_sp->GetImages().ResolveSymbolContextForAddress( 407 lookup_addr, resolve_scope, m_sc); 408 } 409 } 410 411 // Update our internal flags so we remember what we have tried to locate so 412 // we don't have to keep trying when more calls to this function are made. 413 // We might have dug up more information that was requested (for example if 414 // we were asked to only get the block, we will have gotten the compile 415 // unit, and function) so set any additional bits that we resolved 416 m_flags.Set(resolve_scope | resolved); 417 } 418 419 // Return the symbol context with everything that was possible to resolve 420 // resolved. 421 return m_sc; 422 } 423 424 VariableList *StackFrame::GetVariableList(bool get_file_globals, 425 Status *error_ptr) { 426 std::lock_guard<std::recursive_mutex> guard(m_mutex); 427 if (m_flags.IsClear(RESOLVED_VARIABLES)) { 428 m_flags.Set(RESOLVED_VARIABLES); 429 m_variable_list_sp = std::make_shared<VariableList>(); 430 431 Block *frame_block = GetFrameBlock(); 432 433 if (frame_block) { 434 const bool get_child_variables = true; 435 const bool can_create = true; 436 const bool stop_if_child_block_is_inlined_function = true; 437 frame_block->AppendBlockVariables(can_create, get_child_variables, 438 stop_if_child_block_is_inlined_function, 439 [](Variable *v) { return true; }, 440 m_variable_list_sp.get()); 441 } 442 } 443 444 if (m_flags.IsClear(RESOLVED_GLOBAL_VARIABLES) && get_file_globals) { 445 m_flags.Set(RESOLVED_GLOBAL_VARIABLES); 446 447 if (m_flags.IsClear(eSymbolContextCompUnit)) 448 GetSymbolContext(eSymbolContextCompUnit); 449 450 if (m_sc.comp_unit) { 451 VariableListSP global_variable_list_sp( 452 m_sc.comp_unit->GetVariableList(true)); 453 if (m_variable_list_sp) 454 m_variable_list_sp->AddVariables(global_variable_list_sp.get()); 455 else 456 m_variable_list_sp = global_variable_list_sp; 457 } 458 } 459 460 if (error_ptr && m_variable_list_sp->GetSize() == 0) { 461 // Check with the symbol file to check if there is an error for why we 462 // don't have variables that the user might need to know about. 463 GetSymbolContext(eSymbolContextEverything); 464 if (m_sc.module_sp) { 465 SymbolFile *sym_file = m_sc.module_sp->GetSymbolFile(); 466 if (sym_file) 467 *error_ptr = sym_file->GetFrameVariableError(*this); 468 } 469 } 470 471 return m_variable_list_sp.get(); 472 } 473 474 VariableListSP 475 StackFrame::GetInScopeVariableList(bool get_file_globals, 476 bool must_have_valid_location) { 477 std::lock_guard<std::recursive_mutex> guard(m_mutex); 478 // We can't fetch variable information for a history stack frame. 479 if (IsHistorical()) 480 return VariableListSP(); 481 482 VariableListSP var_list_sp(new VariableList); 483 GetSymbolContext(eSymbolContextCompUnit | eSymbolContextBlock); 484 485 if (m_sc.block) { 486 const bool can_create = true; 487 const bool get_parent_variables = true; 488 const bool stop_if_block_is_inlined_function = true; 489 m_sc.block->AppendVariables( 490 can_create, get_parent_variables, stop_if_block_is_inlined_function, 491 [this, must_have_valid_location](Variable *v) { 492 return v->IsInScope(this) && (!must_have_valid_location || 493 v->LocationIsValidForFrame(this)); 494 }, 495 var_list_sp.get()); 496 } 497 498 if (m_sc.comp_unit && get_file_globals) { 499 VariableListSP global_variable_list_sp( 500 m_sc.comp_unit->GetVariableList(true)); 501 if (global_variable_list_sp) 502 var_list_sp->AddVariables(global_variable_list_sp.get()); 503 } 504 505 return var_list_sp; 506 } 507 508 ValueObjectSP StackFrame::GetValueForVariableExpressionPath( 509 llvm::StringRef var_expr, DynamicValueType use_dynamic, uint32_t options, 510 VariableSP &var_sp, Status &error) { 511 llvm::StringRef original_var_expr = var_expr; 512 // We can't fetch variable information for a history stack frame. 513 if (IsHistorical()) 514 return ValueObjectSP(); 515 516 if (var_expr.empty()) { 517 error.SetErrorStringWithFormat("invalid variable path '%s'", 518 var_expr.str().c_str()); 519 return ValueObjectSP(); 520 } 521 522 const bool check_ptr_vs_member = 523 (options & eExpressionPathOptionCheckPtrVsMember) != 0; 524 const bool no_fragile_ivar = 525 (options & eExpressionPathOptionsNoFragileObjcIvar) != 0; 526 const bool no_synth_child = 527 (options & eExpressionPathOptionsNoSyntheticChildren) != 0; 528 // const bool no_synth_array = (options & 529 // eExpressionPathOptionsNoSyntheticArrayRange) != 0; 530 error.Clear(); 531 bool deref = false; 532 bool address_of = false; 533 ValueObjectSP valobj_sp; 534 const bool get_file_globals = true; 535 // When looking up a variable for an expression, we need only consider the 536 // variables that are in scope. 537 VariableListSP var_list_sp(GetInScopeVariableList(get_file_globals)); 538 VariableList *variable_list = var_list_sp.get(); 539 540 if (!variable_list) 541 return ValueObjectSP(); 542 543 // If first character is a '*', then show pointer contents 544 std::string var_expr_storage; 545 if (var_expr[0] == '*') { 546 deref = true; 547 var_expr = var_expr.drop_front(); // Skip the '*' 548 } else if (var_expr[0] == '&') { 549 address_of = true; 550 var_expr = var_expr.drop_front(); // Skip the '&' 551 } 552 553 size_t separator_idx = var_expr.find_first_of(".-[=+~|&^%#@!/?,<>{}"); 554 StreamString var_expr_path_strm; 555 556 ConstString name_const_string(var_expr.substr(0, separator_idx)); 557 558 var_sp = variable_list->FindVariable(name_const_string, false); 559 560 bool synthetically_added_instance_object = false; 561 562 if (var_sp) { 563 var_expr = var_expr.drop_front(name_const_string.GetLength()); 564 } 565 566 if (!var_sp && (options & eExpressionPathOptionsAllowDirectIVarAccess)) { 567 // Check for direct ivars access which helps us with implicit access to 568 // ivars using "this" or "self". 569 GetSymbolContext(eSymbolContextFunction | eSymbolContextBlock); 570 llvm::StringRef instance_var_name = m_sc.GetInstanceVariableName(); 571 if (!instance_var_name.empty()) { 572 var_sp = variable_list->FindVariable(ConstString(instance_var_name)); 573 if (var_sp) { 574 separator_idx = 0; 575 if (Type *var_type = var_sp->GetType()) 576 if (auto compiler_type = var_type->GetForwardCompilerType()) 577 if (!compiler_type.IsPointerType()) 578 var_expr_storage = "."; 579 580 if (var_expr_storage.empty()) 581 var_expr_storage = "->"; 582 var_expr_storage += var_expr; 583 var_expr = var_expr_storage; 584 synthetically_added_instance_object = true; 585 } 586 } 587 } 588 589 if (!var_sp && (options & eExpressionPathOptionsInspectAnonymousUnions)) { 590 // Check if any anonymous unions are there which contain a variable with 591 // the name we need 592 for (const VariableSP &variable_sp : *variable_list) { 593 if (!variable_sp) 594 continue; 595 if (!variable_sp->GetName().IsEmpty()) 596 continue; 597 598 Type *var_type = variable_sp->GetType(); 599 if (!var_type) 600 continue; 601 602 if (!var_type->GetForwardCompilerType().IsAnonymousType()) 603 continue; 604 valobj_sp = GetValueObjectForFrameVariable(variable_sp, use_dynamic); 605 if (!valobj_sp) 606 return valobj_sp; 607 valobj_sp = valobj_sp->GetChildMemberWithName(name_const_string); 608 if (valobj_sp) 609 break; 610 } 611 } 612 613 if (var_sp && !valobj_sp) { 614 valobj_sp = GetValueObjectForFrameVariable(var_sp, use_dynamic); 615 if (!valobj_sp) 616 return valobj_sp; 617 } 618 if (!valobj_sp) { 619 error.SetErrorStringWithFormat("no variable named '%s' found in this frame", 620 name_const_string.GetCString()); 621 return ValueObjectSP(); 622 } 623 624 // We are dumping at least one child 625 while (!var_expr.empty()) { 626 // Calculate the next separator index ahead of time 627 ValueObjectSP child_valobj_sp; 628 const char separator_type = var_expr[0]; 629 bool expr_is_ptr = false; 630 switch (separator_type) { 631 case '-': 632 expr_is_ptr = true; 633 if (var_expr.size() >= 2 && var_expr[1] != '>') 634 return ValueObjectSP(); 635 636 if (no_fragile_ivar) { 637 // Make sure we aren't trying to deref an objective 638 // C ivar if this is not allowed 639 const uint32_t pointer_type_flags = 640 valobj_sp->GetCompilerType().GetTypeInfo(nullptr); 641 if ((pointer_type_flags & eTypeIsObjC) && 642 (pointer_type_flags & eTypeIsPointer)) { 643 // This was an objective C object pointer and it was requested we 644 // skip any fragile ivars so return nothing here 645 return ValueObjectSP(); 646 } 647 } 648 649 // If we have a non pointer type with a sythetic value then lets check if 650 // we have an sythetic dereference specified. 651 if (!valobj_sp->IsPointerType() && valobj_sp->HasSyntheticValue()) { 652 Status deref_error; 653 if (valobj_sp->GetCompilerType().IsReferenceType()) { 654 valobj_sp = valobj_sp->GetSyntheticValue()->Dereference(deref_error); 655 if (!valobj_sp || deref_error.Fail()) { 656 error.SetErrorStringWithFormatv( 657 "Failed to dereference reference type: %s", deref_error); 658 return ValueObjectSP(); 659 } 660 } 661 662 valobj_sp = valobj_sp->Dereference(deref_error); 663 if (!valobj_sp || deref_error.Fail()) { 664 error.SetErrorStringWithFormatv( 665 "Failed to dereference sythetic value: {0}", deref_error); 666 return ValueObjectSP(); 667 } 668 // Some synthetic plug-ins fail to set the error in Dereference 669 if (!valobj_sp) { 670 error.SetErrorString("Failed to dereference sythetic value"); 671 return ValueObjectSP(); 672 } 673 expr_is_ptr = false; 674 } 675 676 var_expr = var_expr.drop_front(); // Remove the '-' 677 [[fallthrough]]; 678 case '.': { 679 var_expr = var_expr.drop_front(); // Remove the '.' or '>' 680 separator_idx = var_expr.find_first_of(".-["); 681 ConstString child_name(var_expr.substr(0, var_expr.find_first_of(".-["))); 682 683 if (check_ptr_vs_member) { 684 // We either have a pointer type and need to verify valobj_sp is a 685 // pointer, or we have a member of a class/union/struct being accessed 686 // with the . syntax and need to verify we don't have a pointer. 687 const bool actual_is_ptr = valobj_sp->IsPointerType(); 688 689 if (actual_is_ptr != expr_is_ptr) { 690 // Incorrect use of "." with a pointer, or "->" with a 691 // class/union/struct instance or reference. 692 valobj_sp->GetExpressionPath(var_expr_path_strm); 693 if (actual_is_ptr) 694 error.SetErrorStringWithFormat( 695 "\"%s\" is a pointer and . was used to attempt to access " 696 "\"%s\". Did you mean \"%s->%s\"?", 697 var_expr_path_strm.GetData(), child_name.GetCString(), 698 var_expr_path_strm.GetData(), var_expr.str().c_str()); 699 else 700 error.SetErrorStringWithFormat( 701 "\"%s\" is not a pointer and -> was used to attempt to " 702 "access \"%s\". Did you mean \"%s.%s\"?", 703 var_expr_path_strm.GetData(), child_name.GetCString(), 704 var_expr_path_strm.GetData(), var_expr.str().c_str()); 705 return ValueObjectSP(); 706 } 707 } 708 child_valobj_sp = valobj_sp->GetChildMemberWithName(child_name); 709 if (!child_valobj_sp) { 710 if (!no_synth_child) { 711 child_valobj_sp = valobj_sp->GetSyntheticValue(); 712 if (child_valobj_sp) 713 child_valobj_sp = 714 child_valobj_sp->GetChildMemberWithName(child_name); 715 } 716 717 if (no_synth_child || !child_valobj_sp) { 718 // No child member with name "child_name" 719 if (synthetically_added_instance_object) { 720 // We added a "this->" or "self->" to the beginning of the 721 // expression and this is the first pointer ivar access, so just 722 // return the normal error 723 error.SetErrorStringWithFormat( 724 "no variable or instance variable named '%s' found in " 725 "this frame", 726 name_const_string.GetCString()); 727 } else { 728 valobj_sp->GetExpressionPath(var_expr_path_strm); 729 if (child_name) { 730 error.SetErrorStringWithFormat( 731 "\"%s\" is not a member of \"(%s) %s\"", 732 child_name.GetCString(), 733 valobj_sp->GetTypeName().AsCString("<invalid type>"), 734 var_expr_path_strm.GetData()); 735 } else { 736 error.SetErrorStringWithFormat( 737 "incomplete expression path after \"%s\" in \"%s\"", 738 var_expr_path_strm.GetData(), 739 original_var_expr.str().c_str()); 740 } 741 } 742 return ValueObjectSP(); 743 } 744 } 745 synthetically_added_instance_object = false; 746 // Remove the child name from the path 747 var_expr = var_expr.drop_front(child_name.GetLength()); 748 if (use_dynamic != eNoDynamicValues) { 749 ValueObjectSP dynamic_value_sp( 750 child_valobj_sp->GetDynamicValue(use_dynamic)); 751 if (dynamic_value_sp) 752 child_valobj_sp = dynamic_value_sp; 753 } 754 } break; 755 756 case '[': { 757 // Array member access, or treating pointer as an array Need at least two 758 // brackets and a number 759 if (var_expr.size() <= 2) { 760 error.SetErrorStringWithFormat( 761 "invalid square bracket encountered after \"%s\" in \"%s\"", 762 var_expr_path_strm.GetData(), var_expr.str().c_str()); 763 return ValueObjectSP(); 764 } 765 766 // Drop the open brace. 767 var_expr = var_expr.drop_front(); 768 long child_index = 0; 769 770 // If there's no closing brace, this is an invalid expression. 771 size_t end_pos = var_expr.find_first_of(']'); 772 if (end_pos == llvm::StringRef::npos) { 773 error.SetErrorStringWithFormat( 774 "missing closing square bracket in expression \"%s\"", 775 var_expr_path_strm.GetData()); 776 return ValueObjectSP(); 777 } 778 llvm::StringRef index_expr = var_expr.take_front(end_pos); 779 llvm::StringRef original_index_expr = index_expr; 780 // Drop all of "[index_expr]" 781 var_expr = var_expr.drop_front(end_pos + 1); 782 783 if (index_expr.consumeInteger(0, child_index)) { 784 // If there was no integer anywhere in the index expression, this is 785 // erroneous expression. 786 error.SetErrorStringWithFormat("invalid index expression \"%s\"", 787 index_expr.str().c_str()); 788 return ValueObjectSP(); 789 } 790 791 if (index_expr.empty()) { 792 // The entire index expression was a single integer. 793 794 if (valobj_sp->GetCompilerType().IsPointerToScalarType() && deref) { 795 // what we have is *ptr[low]. the most similar C++ syntax is to deref 796 // ptr and extract bit low out of it. reading array item low would be 797 // done by saying ptr[low], without a deref * sign 798 Status deref_error; 799 ValueObjectSP temp(valobj_sp->Dereference(deref_error)); 800 if (!temp || deref_error.Fail()) { 801 valobj_sp->GetExpressionPath(var_expr_path_strm); 802 error.SetErrorStringWithFormat( 803 "could not dereference \"(%s) %s\"", 804 valobj_sp->GetTypeName().AsCString("<invalid type>"), 805 var_expr_path_strm.GetData()); 806 return ValueObjectSP(); 807 } 808 valobj_sp = temp; 809 deref = false; 810 } else if (valobj_sp->GetCompilerType().IsArrayOfScalarType() && 811 deref) { 812 // what we have is *arr[low]. the most similar C++ syntax is to get 813 // arr[0] (an operation that is equivalent to deref-ing arr) and 814 // extract bit low out of it. reading array item low would be done by 815 // saying arr[low], without a deref * sign 816 ValueObjectSP temp(valobj_sp->GetChildAtIndex(0)); 817 if (!temp) { 818 valobj_sp->GetExpressionPath(var_expr_path_strm); 819 error.SetErrorStringWithFormat( 820 "could not get item 0 for \"(%s) %s\"", 821 valobj_sp->GetTypeName().AsCString("<invalid type>"), 822 var_expr_path_strm.GetData()); 823 return ValueObjectSP(); 824 } 825 valobj_sp = temp; 826 deref = false; 827 } 828 829 bool is_incomplete_array = false; 830 if (valobj_sp->IsPointerType()) { 831 bool is_objc_pointer = true; 832 833 if (valobj_sp->GetCompilerType().GetMinimumLanguage() != 834 eLanguageTypeObjC) 835 is_objc_pointer = false; 836 else if (!valobj_sp->GetCompilerType().IsPointerType()) 837 is_objc_pointer = false; 838 839 if (no_synth_child && is_objc_pointer) { 840 error.SetErrorStringWithFormat( 841 "\"(%s) %s\" is an Objective-C pointer, and cannot be " 842 "subscripted", 843 valobj_sp->GetTypeName().AsCString("<invalid type>"), 844 var_expr_path_strm.GetData()); 845 846 return ValueObjectSP(); 847 } else if (is_objc_pointer) { 848 // dereferencing ObjC variables is not valid.. so let's try and 849 // recur to synthetic children 850 ValueObjectSP synthetic = valobj_sp->GetSyntheticValue(); 851 if (!synthetic /* no synthetic */ 852 || synthetic == valobj_sp) /* synthetic is the same as 853 the original object */ 854 { 855 valobj_sp->GetExpressionPath(var_expr_path_strm); 856 error.SetErrorStringWithFormat( 857 "\"(%s) %s\" is not an array type", 858 valobj_sp->GetTypeName().AsCString("<invalid type>"), 859 var_expr_path_strm.GetData()); 860 } else if ( 861 static_cast<uint32_t>(child_index) >= 862 synthetic 863 ->GetNumChildren() /* synthetic does not have that many values */) { 864 valobj_sp->GetExpressionPath(var_expr_path_strm); 865 error.SetErrorStringWithFormat( 866 "array index %ld is not valid for \"(%s) %s\"", child_index, 867 valobj_sp->GetTypeName().AsCString("<invalid type>"), 868 var_expr_path_strm.GetData()); 869 } else { 870 child_valobj_sp = synthetic->GetChildAtIndex(child_index); 871 if (!child_valobj_sp) { 872 valobj_sp->GetExpressionPath(var_expr_path_strm); 873 error.SetErrorStringWithFormat( 874 "array index %ld is not valid for \"(%s) %s\"", child_index, 875 valobj_sp->GetTypeName().AsCString("<invalid type>"), 876 var_expr_path_strm.GetData()); 877 } 878 } 879 } else { 880 child_valobj_sp = 881 valobj_sp->GetSyntheticArrayMember(child_index, true); 882 if (!child_valobj_sp) { 883 valobj_sp->GetExpressionPath(var_expr_path_strm); 884 error.SetErrorStringWithFormat( 885 "failed to use pointer as array for index %ld for " 886 "\"(%s) %s\"", 887 child_index, 888 valobj_sp->GetTypeName().AsCString("<invalid type>"), 889 var_expr_path_strm.GetData()); 890 } 891 } 892 } else if (valobj_sp->GetCompilerType().IsArrayType( 893 nullptr, nullptr, &is_incomplete_array)) { 894 // Pass false to dynamic_value here so we can tell the difference 895 // between no dynamic value and no member of this type... 896 child_valobj_sp = valobj_sp->GetChildAtIndex(child_index); 897 if (!child_valobj_sp && (is_incomplete_array || !no_synth_child)) 898 child_valobj_sp = 899 valobj_sp->GetSyntheticArrayMember(child_index, true); 900 901 if (!child_valobj_sp) { 902 valobj_sp->GetExpressionPath(var_expr_path_strm); 903 error.SetErrorStringWithFormat( 904 "array index %ld is not valid for \"(%s) %s\"", child_index, 905 valobj_sp->GetTypeName().AsCString("<invalid type>"), 906 var_expr_path_strm.GetData()); 907 } 908 } else if (valobj_sp->GetCompilerType().IsScalarType()) { 909 // this is a bitfield asking to display just one bit 910 child_valobj_sp = valobj_sp->GetSyntheticBitFieldChild( 911 child_index, child_index, true); 912 if (!child_valobj_sp) { 913 valobj_sp->GetExpressionPath(var_expr_path_strm); 914 error.SetErrorStringWithFormat( 915 "bitfield range %ld-%ld is not valid for \"(%s) %s\"", 916 child_index, child_index, 917 valobj_sp->GetTypeName().AsCString("<invalid type>"), 918 var_expr_path_strm.GetData()); 919 } 920 } else { 921 ValueObjectSP synthetic = valobj_sp->GetSyntheticValue(); 922 if (no_synth_child /* synthetic is forbidden */ || 923 !synthetic /* no synthetic */ 924 || synthetic == valobj_sp) /* synthetic is the same as the 925 original object */ 926 { 927 valobj_sp->GetExpressionPath(var_expr_path_strm); 928 error.SetErrorStringWithFormat( 929 "\"(%s) %s\" is not an array type", 930 valobj_sp->GetTypeName().AsCString("<invalid type>"), 931 var_expr_path_strm.GetData()); 932 } else if ( 933 static_cast<uint32_t>(child_index) >= 934 synthetic 935 ->GetNumChildren() /* synthetic does not have that many values */) { 936 valobj_sp->GetExpressionPath(var_expr_path_strm); 937 error.SetErrorStringWithFormat( 938 "array index %ld is not valid for \"(%s) %s\"", child_index, 939 valobj_sp->GetTypeName().AsCString("<invalid type>"), 940 var_expr_path_strm.GetData()); 941 } else { 942 child_valobj_sp = synthetic->GetChildAtIndex(child_index); 943 if (!child_valobj_sp) { 944 valobj_sp->GetExpressionPath(var_expr_path_strm); 945 error.SetErrorStringWithFormat( 946 "array index %ld is not valid for \"(%s) %s\"", child_index, 947 valobj_sp->GetTypeName().AsCString("<invalid type>"), 948 var_expr_path_strm.GetData()); 949 } 950 } 951 } 952 953 if (!child_valobj_sp) { 954 // Invalid array index... 955 return ValueObjectSP(); 956 } 957 958 if (use_dynamic != eNoDynamicValues) { 959 ValueObjectSP dynamic_value_sp( 960 child_valobj_sp->GetDynamicValue(use_dynamic)); 961 if (dynamic_value_sp) 962 child_valobj_sp = dynamic_value_sp; 963 } 964 // Break out early from the switch since we were able to find the child 965 // member 966 break; 967 } 968 969 // this is most probably a BitField, let's take a look 970 if (index_expr.front() != '-') { 971 error.SetErrorStringWithFormat("invalid range expression \"'%s'\"", 972 original_index_expr.str().c_str()); 973 return ValueObjectSP(); 974 } 975 976 index_expr = index_expr.drop_front(); 977 long final_index = 0; 978 if (index_expr.getAsInteger(0, final_index)) { 979 error.SetErrorStringWithFormat("invalid range expression \"'%s'\"", 980 original_index_expr.str().c_str()); 981 return ValueObjectSP(); 982 } 983 984 // if the format given is [high-low], swap range 985 if (child_index > final_index) { 986 long temp = child_index; 987 child_index = final_index; 988 final_index = temp; 989 } 990 991 if (valobj_sp->GetCompilerType().IsPointerToScalarType() && deref) { 992 // what we have is *ptr[low-high]. the most similar C++ syntax is to 993 // deref ptr and extract bits low thru high out of it. reading array 994 // items low thru high would be done by saying ptr[low-high], without a 995 // deref * sign 996 Status deref_error; 997 ValueObjectSP temp(valobj_sp->Dereference(deref_error)); 998 if (!temp || deref_error.Fail()) { 999 valobj_sp->GetExpressionPath(var_expr_path_strm); 1000 error.SetErrorStringWithFormat( 1001 "could not dereference \"(%s) %s\"", 1002 valobj_sp->GetTypeName().AsCString("<invalid type>"), 1003 var_expr_path_strm.GetData()); 1004 return ValueObjectSP(); 1005 } 1006 valobj_sp = temp; 1007 deref = false; 1008 } else if (valobj_sp->GetCompilerType().IsArrayOfScalarType() && deref) { 1009 // what we have is *arr[low-high]. the most similar C++ syntax is to 1010 // get arr[0] (an operation that is equivalent to deref-ing arr) and 1011 // extract bits low thru high out of it. reading array items low thru 1012 // high would be done by saying arr[low-high], without a deref * sign 1013 ValueObjectSP temp(valobj_sp->GetChildAtIndex(0)); 1014 if (!temp) { 1015 valobj_sp->GetExpressionPath(var_expr_path_strm); 1016 error.SetErrorStringWithFormat( 1017 "could not get item 0 for \"(%s) %s\"", 1018 valobj_sp->GetTypeName().AsCString("<invalid type>"), 1019 var_expr_path_strm.GetData()); 1020 return ValueObjectSP(); 1021 } 1022 valobj_sp = temp; 1023 deref = false; 1024 } 1025 1026 child_valobj_sp = 1027 valobj_sp->GetSyntheticBitFieldChild(child_index, final_index, true); 1028 if (!child_valobj_sp) { 1029 valobj_sp->GetExpressionPath(var_expr_path_strm); 1030 error.SetErrorStringWithFormat( 1031 "bitfield range %ld-%ld is not valid for \"(%s) %s\"", child_index, 1032 final_index, valobj_sp->GetTypeName().AsCString("<invalid type>"), 1033 var_expr_path_strm.GetData()); 1034 } 1035 1036 if (!child_valobj_sp) { 1037 // Invalid bitfield range... 1038 return ValueObjectSP(); 1039 } 1040 1041 if (use_dynamic != eNoDynamicValues) { 1042 ValueObjectSP dynamic_value_sp( 1043 child_valobj_sp->GetDynamicValue(use_dynamic)); 1044 if (dynamic_value_sp) 1045 child_valobj_sp = dynamic_value_sp; 1046 } 1047 // Break out early from the switch since we were able to find the child 1048 // member 1049 break; 1050 } 1051 default: 1052 // Failure... 1053 { 1054 valobj_sp->GetExpressionPath(var_expr_path_strm); 1055 error.SetErrorStringWithFormat( 1056 "unexpected char '%c' encountered after \"%s\" in \"%s\"", 1057 separator_type, var_expr_path_strm.GetData(), 1058 var_expr.str().c_str()); 1059 1060 return ValueObjectSP(); 1061 } 1062 } 1063 1064 if (child_valobj_sp) 1065 valobj_sp = child_valobj_sp; 1066 } 1067 if (valobj_sp) { 1068 if (deref) { 1069 ValueObjectSP deref_valobj_sp(valobj_sp->Dereference(error)); 1070 valobj_sp = deref_valobj_sp; 1071 } else if (address_of) { 1072 ValueObjectSP address_of_valobj_sp(valobj_sp->AddressOf(error)); 1073 valobj_sp = address_of_valobj_sp; 1074 } 1075 } 1076 return valobj_sp; 1077 } 1078 1079 bool StackFrame::GetFrameBaseValue(Scalar &frame_base, Status *error_ptr) { 1080 std::lock_guard<std::recursive_mutex> guard(m_mutex); 1081 if (!m_cfa_is_valid) { 1082 m_frame_base_error.SetErrorString( 1083 "No frame base available for this historical stack frame."); 1084 return false; 1085 } 1086 1087 if (m_flags.IsClear(GOT_FRAME_BASE)) { 1088 if (m_sc.function) { 1089 m_frame_base.Clear(); 1090 m_frame_base_error.Clear(); 1091 1092 m_flags.Set(GOT_FRAME_BASE); 1093 ExecutionContext exe_ctx(shared_from_this()); 1094 Value expr_value; 1095 addr_t loclist_base_addr = LLDB_INVALID_ADDRESS; 1096 if (!m_sc.function->GetFrameBaseExpression().IsAlwaysValidSingleExpr()) 1097 loclist_base_addr = 1098 m_sc.function->GetAddressRange().GetBaseAddress().GetLoadAddress( 1099 exe_ctx.GetTargetPtr()); 1100 1101 if (!m_sc.function->GetFrameBaseExpression().Evaluate( 1102 &exe_ctx, nullptr, loclist_base_addr, nullptr, nullptr, 1103 expr_value, &m_frame_base_error)) { 1104 // We should really have an error if evaluate returns, but in case we 1105 // don't, lets set the error to something at least. 1106 if (m_frame_base_error.Success()) 1107 m_frame_base_error.SetErrorString( 1108 "Evaluation of the frame base expression failed."); 1109 } else { 1110 m_frame_base = expr_value.ResolveValue(&exe_ctx); 1111 } 1112 } else { 1113 m_frame_base_error.SetErrorString("No function in symbol context."); 1114 } 1115 } 1116 1117 if (m_frame_base_error.Success()) 1118 frame_base = m_frame_base; 1119 1120 if (error_ptr) 1121 *error_ptr = m_frame_base_error; 1122 return m_frame_base_error.Success(); 1123 } 1124 1125 DWARFExpressionList *StackFrame::GetFrameBaseExpression(Status *error_ptr) { 1126 if (!m_sc.function) { 1127 if (error_ptr) { 1128 error_ptr->SetErrorString("No function in symbol context."); 1129 } 1130 return nullptr; 1131 } 1132 1133 return &m_sc.function->GetFrameBaseExpression(); 1134 } 1135 1136 RegisterContextSP StackFrame::GetRegisterContext() { 1137 std::lock_guard<std::recursive_mutex> guard(m_mutex); 1138 if (!m_reg_context_sp) { 1139 ThreadSP thread_sp(GetThread()); 1140 if (thread_sp) 1141 m_reg_context_sp = thread_sp->CreateRegisterContextForFrame(this); 1142 } 1143 return m_reg_context_sp; 1144 } 1145 1146 bool StackFrame::HasDebugInformation() { 1147 GetSymbolContext(eSymbolContextLineEntry); 1148 return m_sc.line_entry.IsValid(); 1149 } 1150 1151 ValueObjectSP 1152 StackFrame::GetValueObjectForFrameVariable(const VariableSP &variable_sp, 1153 DynamicValueType use_dynamic) { 1154 ValueObjectSP valobj_sp; 1155 { // Scope for stack frame mutex. We need to drop this mutex before we figure 1156 // out the dynamic value. That will require converting the StackID in the 1157 // VO back to a StackFrame, which will in turn require locking the 1158 // StackFrameList. If we still hold the StackFrame mutex, we could suffer 1159 // lock inversion against the pattern of getting the StackFrameList and 1160 // then the stack frame, which is fairly common. 1161 std::lock_guard<std::recursive_mutex> guard(m_mutex); 1162 if (IsHistorical()) { 1163 return valobj_sp; 1164 } 1165 VariableList *var_list = GetVariableList(true, nullptr); 1166 if (var_list) { 1167 // Make sure the variable is a frame variable 1168 const uint32_t var_idx = var_list->FindIndexForVariable(variable_sp.get()); 1169 const uint32_t num_variables = var_list->GetSize(); 1170 if (var_idx < num_variables) { 1171 valobj_sp = m_variable_list_value_objects.GetValueObjectAtIndex(var_idx); 1172 if (!valobj_sp) { 1173 if (m_variable_list_value_objects.GetSize() < num_variables) 1174 m_variable_list_value_objects.Resize(num_variables); 1175 valobj_sp = ValueObjectVariable::Create(this, variable_sp); 1176 m_variable_list_value_objects.SetValueObjectAtIndex(var_idx, 1177 valobj_sp); 1178 } 1179 } 1180 } 1181 } // End of StackFrame mutex scope. 1182 if (use_dynamic != eNoDynamicValues && valobj_sp) { 1183 ValueObjectSP dynamic_sp = valobj_sp->GetDynamicValue(use_dynamic); 1184 if (dynamic_sp) 1185 return dynamic_sp; 1186 } 1187 return valobj_sp; 1188 } 1189 1190 bool StackFrame::IsInlined() { 1191 if (m_sc.block == nullptr) 1192 GetSymbolContext(eSymbolContextBlock); 1193 if (m_sc.block) 1194 return m_sc.block->GetContainingInlinedBlock() != nullptr; 1195 return false; 1196 } 1197 1198 bool StackFrame::IsHistorical() const { 1199 return m_stack_frame_kind == StackFrame::Kind::History; 1200 } 1201 1202 bool StackFrame::IsArtificial() const { 1203 return m_stack_frame_kind == StackFrame::Kind::Artificial; 1204 } 1205 1206 lldb::LanguageType StackFrame::GetLanguage() { 1207 CompileUnit *cu = GetSymbolContext(eSymbolContextCompUnit).comp_unit; 1208 if (cu) 1209 return cu->GetLanguage(); 1210 return lldb::eLanguageTypeUnknown; 1211 } 1212 1213 lldb::LanguageType StackFrame::GuessLanguage() { 1214 LanguageType lang_type = GetLanguage(); 1215 1216 if (lang_type == eLanguageTypeUnknown) { 1217 SymbolContext sc = GetSymbolContext(eSymbolContextFunction 1218 | eSymbolContextSymbol); 1219 if (sc.function) { 1220 lang_type = sc.function->GetMangled().GuessLanguage(); 1221 } 1222 else if (sc.symbol) 1223 { 1224 lang_type = sc.symbol->GetMangled().GuessLanguage(); 1225 } 1226 } 1227 1228 return lang_type; 1229 } 1230 1231 namespace { 1232 std::pair<const Instruction::Operand *, int64_t> 1233 GetBaseExplainingValue(const Instruction::Operand &operand, 1234 RegisterContext ®ister_context, lldb::addr_t value) { 1235 switch (operand.m_type) { 1236 case Instruction::Operand::Type::Dereference: 1237 case Instruction::Operand::Type::Immediate: 1238 case Instruction::Operand::Type::Invalid: 1239 case Instruction::Operand::Type::Product: 1240 // These are not currently interesting 1241 return std::make_pair(nullptr, 0); 1242 case Instruction::Operand::Type::Sum: { 1243 const Instruction::Operand *immediate_child = nullptr; 1244 const Instruction::Operand *variable_child = nullptr; 1245 if (operand.m_children[0].m_type == Instruction::Operand::Type::Immediate) { 1246 immediate_child = &operand.m_children[0]; 1247 variable_child = &operand.m_children[1]; 1248 } else if (operand.m_children[1].m_type == 1249 Instruction::Operand::Type::Immediate) { 1250 immediate_child = &operand.m_children[1]; 1251 variable_child = &operand.m_children[0]; 1252 } 1253 if (!immediate_child) { 1254 return std::make_pair(nullptr, 0); 1255 } 1256 lldb::addr_t adjusted_value = value; 1257 if (immediate_child->m_negative) { 1258 adjusted_value += immediate_child->m_immediate; 1259 } else { 1260 adjusted_value -= immediate_child->m_immediate; 1261 } 1262 std::pair<const Instruction::Operand *, int64_t> base_and_offset = 1263 GetBaseExplainingValue(*variable_child, register_context, 1264 adjusted_value); 1265 if (!base_and_offset.first) { 1266 return std::make_pair(nullptr, 0); 1267 } 1268 if (immediate_child->m_negative) { 1269 base_and_offset.second -= immediate_child->m_immediate; 1270 } else { 1271 base_and_offset.second += immediate_child->m_immediate; 1272 } 1273 return base_and_offset; 1274 } 1275 case Instruction::Operand::Type::Register: { 1276 const RegisterInfo *info = 1277 register_context.GetRegisterInfoByName(operand.m_register.AsCString()); 1278 if (!info) { 1279 return std::make_pair(nullptr, 0); 1280 } 1281 RegisterValue reg_value; 1282 if (!register_context.ReadRegister(info, reg_value)) { 1283 return std::make_pair(nullptr, 0); 1284 } 1285 if (reg_value.GetAsUInt64() == value) { 1286 return std::make_pair(&operand, 0); 1287 } else { 1288 return std::make_pair(nullptr, 0); 1289 } 1290 } 1291 } 1292 return std::make_pair(nullptr, 0); 1293 } 1294 1295 std::pair<const Instruction::Operand *, int64_t> 1296 GetBaseExplainingDereference(const Instruction::Operand &operand, 1297 RegisterContext ®ister_context, 1298 lldb::addr_t addr) { 1299 if (operand.m_type == Instruction::Operand::Type::Dereference) { 1300 return GetBaseExplainingValue(operand.m_children[0], register_context, 1301 addr); 1302 } 1303 return std::make_pair(nullptr, 0); 1304 } 1305 } 1306 1307 lldb::ValueObjectSP StackFrame::GuessValueForAddress(lldb::addr_t addr) { 1308 TargetSP target_sp = CalculateTarget(); 1309 1310 const ArchSpec &target_arch = target_sp->GetArchitecture(); 1311 1312 AddressRange pc_range; 1313 pc_range.GetBaseAddress() = GetFrameCodeAddress(); 1314 pc_range.SetByteSize(target_arch.GetMaximumOpcodeByteSize()); 1315 1316 const char *plugin_name = nullptr; 1317 const char *flavor = nullptr; 1318 const bool force_live_memory = true; 1319 1320 DisassemblerSP disassembler_sp = 1321 Disassembler::DisassembleRange(target_arch, plugin_name, flavor, 1322 *target_sp, pc_range, force_live_memory); 1323 1324 if (!disassembler_sp || !disassembler_sp->GetInstructionList().GetSize()) { 1325 return ValueObjectSP(); 1326 } 1327 1328 InstructionSP instruction_sp = 1329 disassembler_sp->GetInstructionList().GetInstructionAtIndex(0); 1330 1331 llvm::SmallVector<Instruction::Operand, 3> operands; 1332 1333 if (!instruction_sp->ParseOperands(operands)) { 1334 return ValueObjectSP(); 1335 } 1336 1337 RegisterContextSP register_context_sp = GetRegisterContext(); 1338 1339 if (!register_context_sp) { 1340 return ValueObjectSP(); 1341 } 1342 1343 for (const Instruction::Operand &operand : operands) { 1344 std::pair<const Instruction::Operand *, int64_t> base_and_offset = 1345 GetBaseExplainingDereference(operand, *register_context_sp, addr); 1346 1347 if (!base_and_offset.first) { 1348 continue; 1349 } 1350 1351 switch (base_and_offset.first->m_type) { 1352 case Instruction::Operand::Type::Immediate: { 1353 lldb_private::Address addr; 1354 if (target_sp->ResolveLoadAddress(base_and_offset.first->m_immediate + 1355 base_and_offset.second, 1356 addr)) { 1357 auto c_type_system_or_err = 1358 target_sp->GetScratchTypeSystemForLanguage(eLanguageTypeC); 1359 if (auto err = c_type_system_or_err.takeError()) { 1360 LLDB_LOG_ERROR(GetLog(LLDBLog::Thread), std::move(err), 1361 "Unable to guess value for given address: {0}"); 1362 return ValueObjectSP(); 1363 } else { 1364 auto ts = *c_type_system_or_err; 1365 if (!ts) 1366 return {}; 1367 CompilerType void_ptr_type = 1368 ts->GetBasicTypeFromAST(lldb::BasicType::eBasicTypeChar) 1369 .GetPointerType(); 1370 return ValueObjectMemory::Create(this, "", addr, void_ptr_type); 1371 } 1372 } else { 1373 return ValueObjectSP(); 1374 } 1375 break; 1376 } 1377 case Instruction::Operand::Type::Register: { 1378 return GuessValueForRegisterAndOffset(base_and_offset.first->m_register, 1379 base_and_offset.second); 1380 } 1381 default: 1382 return ValueObjectSP(); 1383 } 1384 } 1385 1386 return ValueObjectSP(); 1387 } 1388 1389 namespace { 1390 ValueObjectSP GetValueForOffset(StackFrame &frame, ValueObjectSP &parent, 1391 int64_t offset) { 1392 if (offset < 0 || uint64_t(offset) >= parent->GetByteSize()) { 1393 return ValueObjectSP(); 1394 } 1395 1396 if (parent->IsPointerOrReferenceType()) { 1397 return parent; 1398 } 1399 1400 for (int ci = 0, ce = parent->GetNumChildren(); ci != ce; ++ci) { 1401 ValueObjectSP child_sp = parent->GetChildAtIndex(ci); 1402 1403 if (!child_sp) { 1404 return ValueObjectSP(); 1405 } 1406 1407 int64_t child_offset = child_sp->GetByteOffset(); 1408 int64_t child_size = child_sp->GetByteSize().value_or(0); 1409 1410 if (offset >= child_offset && offset < (child_offset + child_size)) { 1411 return GetValueForOffset(frame, child_sp, offset - child_offset); 1412 } 1413 } 1414 1415 if (offset == 0) { 1416 return parent; 1417 } else { 1418 return ValueObjectSP(); 1419 } 1420 } 1421 1422 ValueObjectSP GetValueForDereferincingOffset(StackFrame &frame, 1423 ValueObjectSP &base, 1424 int64_t offset) { 1425 // base is a pointer to something 1426 // offset is the thing to add to the pointer We return the most sensible 1427 // ValueObject for the result of *(base+offset) 1428 1429 if (!base->IsPointerOrReferenceType()) { 1430 return ValueObjectSP(); 1431 } 1432 1433 Status error; 1434 ValueObjectSP pointee = base->Dereference(error); 1435 1436 if (!pointee) { 1437 return ValueObjectSP(); 1438 } 1439 1440 if (offset >= 0 && uint64_t(offset) >= pointee->GetByteSize()) { 1441 int64_t index = offset / pointee->GetByteSize().value_or(1); 1442 offset = offset % pointee->GetByteSize().value_or(1); 1443 const bool can_create = true; 1444 pointee = base->GetSyntheticArrayMember(index, can_create); 1445 } 1446 1447 if (!pointee || error.Fail()) { 1448 return ValueObjectSP(); 1449 } 1450 1451 return GetValueForOffset(frame, pointee, offset); 1452 } 1453 1454 /// Attempt to reconstruct the ValueObject for the address contained in a 1455 /// given register plus an offset. 1456 /// 1457 /// \param [in] frame 1458 /// The current stack frame. 1459 /// 1460 /// \param [in] reg 1461 /// The register. 1462 /// 1463 /// \param [in] offset 1464 /// The offset from the register. 1465 /// 1466 /// \param [in] disassembler 1467 /// A disassembler containing instructions valid up to the current PC. 1468 /// 1469 /// \param [in] variables 1470 /// The variable list from the current frame, 1471 /// 1472 /// \param [in] pc 1473 /// The program counter for the instruction considered the 'user'. 1474 /// 1475 /// \return 1476 /// A string describing the base for the ExpressionPath. This could be a 1477 /// variable, a register value, an argument, or a function return value. 1478 /// The ValueObject if found. If valid, it has a valid ExpressionPath. 1479 lldb::ValueObjectSP DoGuessValueAt(StackFrame &frame, ConstString reg, 1480 int64_t offset, Disassembler &disassembler, 1481 VariableList &variables, const Address &pc) { 1482 // Example of operation for Intel: 1483 // 1484 // +14: movq -0x8(%rbp), %rdi 1485 // +18: movq 0x8(%rdi), %rdi 1486 // +22: addl 0x4(%rdi), %eax 1487 // 1488 // f, a pointer to a struct, is known to be at -0x8(%rbp). 1489 // 1490 // DoGuessValueAt(frame, rdi, 4, dis, vars, 0x22) finds the instruction at 1491 // +18 that assigns to rdi, and calls itself recursively for that dereference 1492 // DoGuessValueAt(frame, rdi, 8, dis, vars, 0x18) finds the instruction at 1493 // +14 that assigns to rdi, and calls itself recursively for that 1494 // dereference 1495 // DoGuessValueAt(frame, rbp, -8, dis, vars, 0x14) finds "f" in the 1496 // variable list. 1497 // Returns a ValueObject for f. (That's what was stored at rbp-8 at +14) 1498 // Returns a ValueObject for *(f+8) or f->b (That's what was stored at rdi+8 1499 // at +18) 1500 // Returns a ValueObject for *(f->b+4) or f->b->a (That's what was stored at 1501 // rdi+4 at +22) 1502 1503 // First, check the variable list to see if anything is at the specified 1504 // location. 1505 1506 using namespace OperandMatchers; 1507 1508 const RegisterInfo *reg_info = 1509 frame.GetRegisterContext()->GetRegisterInfoByName(reg.AsCString()); 1510 if (!reg_info) { 1511 return ValueObjectSP(); 1512 } 1513 1514 Instruction::Operand op = 1515 offset ? Instruction::Operand::BuildDereference( 1516 Instruction::Operand::BuildSum( 1517 Instruction::Operand::BuildRegister(reg), 1518 Instruction::Operand::BuildImmediate(offset))) 1519 : Instruction::Operand::BuildDereference( 1520 Instruction::Operand::BuildRegister(reg)); 1521 1522 for (VariableSP var_sp : variables) { 1523 if (var_sp->LocationExpressionList().MatchesOperand(frame, op)) 1524 return frame.GetValueObjectForFrameVariable(var_sp, eNoDynamicValues); 1525 } 1526 1527 const uint32_t current_inst = 1528 disassembler.GetInstructionList().GetIndexOfInstructionAtAddress(pc); 1529 if (current_inst == UINT32_MAX) { 1530 return ValueObjectSP(); 1531 } 1532 1533 for (uint32_t ii = current_inst - 1; ii != (uint32_t)-1; --ii) { 1534 // This is not an exact algorithm, and it sacrifices accuracy for 1535 // generality. Recognizing "mov" and "ld" instructions –– and which 1536 // are their source and destination operands -- is something the 1537 // disassembler should do for us. 1538 InstructionSP instruction_sp = 1539 disassembler.GetInstructionList().GetInstructionAtIndex(ii); 1540 1541 if (instruction_sp->IsCall()) { 1542 ABISP abi_sp = frame.CalculateProcess()->GetABI(); 1543 if (!abi_sp) { 1544 continue; 1545 } 1546 1547 const char *return_register_name; 1548 if (!abi_sp->GetPointerReturnRegister(return_register_name)) { 1549 continue; 1550 } 1551 1552 const RegisterInfo *return_register_info = 1553 frame.GetRegisterContext()->GetRegisterInfoByName( 1554 return_register_name); 1555 if (!return_register_info) { 1556 continue; 1557 } 1558 1559 int64_t offset = 0; 1560 1561 if (!MatchUnaryOp(MatchOpType(Instruction::Operand::Type::Dereference), 1562 MatchRegOp(*return_register_info))(op) && 1563 !MatchUnaryOp( 1564 MatchOpType(Instruction::Operand::Type::Dereference), 1565 MatchBinaryOp(MatchOpType(Instruction::Operand::Type::Sum), 1566 MatchRegOp(*return_register_info), 1567 FetchImmOp(offset)))(op)) { 1568 continue; 1569 } 1570 1571 llvm::SmallVector<Instruction::Operand, 1> operands; 1572 if (!instruction_sp->ParseOperands(operands) || operands.size() != 1) { 1573 continue; 1574 } 1575 1576 switch (operands[0].m_type) { 1577 default: 1578 break; 1579 case Instruction::Operand::Type::Immediate: { 1580 SymbolContext sc; 1581 Address load_address; 1582 if (!frame.CalculateTarget()->ResolveLoadAddress( 1583 operands[0].m_immediate, load_address)) { 1584 break; 1585 } 1586 frame.CalculateTarget()->GetImages().ResolveSymbolContextForAddress( 1587 load_address, eSymbolContextFunction, sc); 1588 if (!sc.function) { 1589 break; 1590 } 1591 CompilerType function_type = sc.function->GetCompilerType(); 1592 if (!function_type.IsFunctionType()) { 1593 break; 1594 } 1595 CompilerType return_type = function_type.GetFunctionReturnType(); 1596 RegisterValue return_value; 1597 if (!frame.GetRegisterContext()->ReadRegister(return_register_info, 1598 return_value)) { 1599 break; 1600 } 1601 std::string name_str( 1602 sc.function->GetName().AsCString("<unknown function>")); 1603 name_str.append("()"); 1604 Address return_value_address(return_value.GetAsUInt64()); 1605 ValueObjectSP return_value_sp = ValueObjectMemory::Create( 1606 &frame, name_str, return_value_address, return_type); 1607 return GetValueForDereferincingOffset(frame, return_value_sp, offset); 1608 } 1609 } 1610 1611 continue; 1612 } 1613 1614 llvm::SmallVector<Instruction::Operand, 2> operands; 1615 if (!instruction_sp->ParseOperands(operands) || operands.size() != 2) { 1616 continue; 1617 } 1618 1619 Instruction::Operand *origin_operand = nullptr; 1620 auto clobbered_reg_matcher = [reg_info](const Instruction::Operand &op) { 1621 return MatchRegOp(*reg_info)(op) && op.m_clobbered; 1622 }; 1623 1624 if (clobbered_reg_matcher(operands[0])) { 1625 origin_operand = &operands[1]; 1626 } 1627 else if (clobbered_reg_matcher(operands[1])) { 1628 origin_operand = &operands[0]; 1629 } 1630 else { 1631 continue; 1632 } 1633 1634 // We have an origin operand. Can we track its value down? 1635 ValueObjectSP source_path; 1636 ConstString origin_register; 1637 int64_t origin_offset = 0; 1638 1639 if (FetchRegOp(origin_register)(*origin_operand)) { 1640 source_path = DoGuessValueAt(frame, origin_register, 0, disassembler, 1641 variables, instruction_sp->GetAddress()); 1642 } else if (MatchUnaryOp( 1643 MatchOpType(Instruction::Operand::Type::Dereference), 1644 FetchRegOp(origin_register))(*origin_operand) || 1645 MatchUnaryOp( 1646 MatchOpType(Instruction::Operand::Type::Dereference), 1647 MatchBinaryOp(MatchOpType(Instruction::Operand::Type::Sum), 1648 FetchRegOp(origin_register), 1649 FetchImmOp(origin_offset)))(*origin_operand)) { 1650 source_path = 1651 DoGuessValueAt(frame, origin_register, origin_offset, disassembler, 1652 variables, instruction_sp->GetAddress()); 1653 if (!source_path) { 1654 continue; 1655 } 1656 source_path = 1657 GetValueForDereferincingOffset(frame, source_path, offset); 1658 } 1659 1660 if (source_path) { 1661 return source_path; 1662 } 1663 } 1664 1665 return ValueObjectSP(); 1666 } 1667 } 1668 1669 lldb::ValueObjectSP StackFrame::GuessValueForRegisterAndOffset(ConstString reg, 1670 int64_t offset) { 1671 TargetSP target_sp = CalculateTarget(); 1672 1673 const ArchSpec &target_arch = target_sp->GetArchitecture(); 1674 1675 Block *frame_block = GetFrameBlock(); 1676 1677 if (!frame_block) { 1678 return ValueObjectSP(); 1679 } 1680 1681 Function *function = frame_block->CalculateSymbolContextFunction(); 1682 if (!function) { 1683 return ValueObjectSP(); 1684 } 1685 1686 AddressRange pc_range = function->GetAddressRange(); 1687 1688 if (GetFrameCodeAddress().GetFileAddress() < 1689 pc_range.GetBaseAddress().GetFileAddress() || 1690 GetFrameCodeAddress().GetFileAddress() - 1691 pc_range.GetBaseAddress().GetFileAddress() >= 1692 pc_range.GetByteSize()) { 1693 return ValueObjectSP(); 1694 } 1695 1696 const char *plugin_name = nullptr; 1697 const char *flavor = nullptr; 1698 const bool force_live_memory = true; 1699 DisassemblerSP disassembler_sp = 1700 Disassembler::DisassembleRange(target_arch, plugin_name, flavor, 1701 *target_sp, pc_range, force_live_memory); 1702 1703 if (!disassembler_sp || !disassembler_sp->GetInstructionList().GetSize()) { 1704 return ValueObjectSP(); 1705 } 1706 1707 const bool get_file_globals = false; 1708 VariableList *variables = GetVariableList(get_file_globals, nullptr); 1709 1710 if (!variables) { 1711 return ValueObjectSP(); 1712 } 1713 1714 return DoGuessValueAt(*this, reg, offset, *disassembler_sp, *variables, 1715 GetFrameCodeAddress()); 1716 } 1717 1718 lldb::ValueObjectSP StackFrame::FindVariable(ConstString name) { 1719 ValueObjectSP value_sp; 1720 1721 if (!name) 1722 return value_sp; 1723 1724 TargetSP target_sp = CalculateTarget(); 1725 ProcessSP process_sp = CalculateProcess(); 1726 1727 if (!target_sp && !process_sp) 1728 return value_sp; 1729 1730 VariableList variable_list; 1731 VariableSP var_sp; 1732 SymbolContext sc(GetSymbolContext(eSymbolContextBlock)); 1733 1734 if (sc.block) { 1735 const bool can_create = true; 1736 const bool get_parent_variables = true; 1737 const bool stop_if_block_is_inlined_function = true; 1738 1739 if (sc.block->AppendVariables( 1740 can_create, get_parent_variables, stop_if_block_is_inlined_function, 1741 [this](Variable *v) { return v->IsInScope(this); }, 1742 &variable_list)) { 1743 var_sp = variable_list.FindVariable(name); 1744 } 1745 1746 if (var_sp) 1747 value_sp = GetValueObjectForFrameVariable(var_sp, eNoDynamicValues); 1748 } 1749 1750 return value_sp; 1751 } 1752 1753 TargetSP StackFrame::CalculateTarget() { 1754 TargetSP target_sp; 1755 ThreadSP thread_sp(GetThread()); 1756 if (thread_sp) { 1757 ProcessSP process_sp(thread_sp->CalculateProcess()); 1758 if (process_sp) 1759 target_sp = process_sp->CalculateTarget(); 1760 } 1761 return target_sp; 1762 } 1763 1764 ProcessSP StackFrame::CalculateProcess() { 1765 ProcessSP process_sp; 1766 ThreadSP thread_sp(GetThread()); 1767 if (thread_sp) 1768 process_sp = thread_sp->CalculateProcess(); 1769 return process_sp; 1770 } 1771 1772 ThreadSP StackFrame::CalculateThread() { return GetThread(); } 1773 1774 StackFrameSP StackFrame::CalculateStackFrame() { return shared_from_this(); } 1775 1776 void StackFrame::CalculateExecutionContext(ExecutionContext &exe_ctx) { 1777 exe_ctx.SetContext(shared_from_this()); 1778 } 1779 1780 bool StackFrame::DumpUsingFormat(Stream &strm, 1781 const FormatEntity::Entry *format, 1782 llvm::StringRef frame_marker) { 1783 GetSymbolContext(eSymbolContextEverything); 1784 ExecutionContext exe_ctx(shared_from_this()); 1785 StreamString s; 1786 s.PutCString(frame_marker); 1787 1788 if (format && FormatEntity::Format(*format, s, &m_sc, &exe_ctx, nullptr, 1789 nullptr, false, false)) { 1790 strm.PutCString(s.GetString()); 1791 return true; 1792 } 1793 return false; 1794 } 1795 1796 void StackFrame::DumpUsingSettingsFormat(Stream *strm, bool show_unique, 1797 const char *frame_marker) { 1798 if (strm == nullptr) 1799 return; 1800 1801 ExecutionContext exe_ctx(shared_from_this()); 1802 StreamString s; 1803 1804 const FormatEntity::Entry *frame_format = nullptr; 1805 Target *target = exe_ctx.GetTargetPtr(); 1806 if (target) { 1807 if (show_unique) { 1808 frame_format = target->GetDebugger().GetFrameFormatUnique(); 1809 } else { 1810 frame_format = target->GetDebugger().GetFrameFormat(); 1811 } 1812 } 1813 if (!DumpUsingFormat(*strm, frame_format, frame_marker)) { 1814 Dump(strm, true, false); 1815 strm->EOL(); 1816 } 1817 } 1818 1819 void StackFrame::Dump(Stream *strm, bool show_frame_index, 1820 bool show_fullpaths) { 1821 if (strm == nullptr) 1822 return; 1823 1824 if (show_frame_index) 1825 strm->Printf("frame #%u: ", m_frame_index); 1826 ExecutionContext exe_ctx(shared_from_this()); 1827 Target *target = exe_ctx.GetTargetPtr(); 1828 strm->Printf("0x%0*" PRIx64 " ", 1829 target ? (target->GetArchitecture().GetAddressByteSize() * 2) 1830 : 16, 1831 GetFrameCodeAddress().GetLoadAddress(target)); 1832 GetSymbolContext(eSymbolContextEverything); 1833 const bool show_module = true; 1834 const bool show_inline = true; 1835 const bool show_function_arguments = true; 1836 const bool show_function_name = true; 1837 m_sc.DumpStopContext(strm, exe_ctx.GetBestExecutionContextScope(), 1838 GetFrameCodeAddress(), show_fullpaths, show_module, 1839 show_inline, show_function_arguments, 1840 show_function_name); 1841 } 1842 1843 void StackFrame::UpdateCurrentFrameFromPreviousFrame(StackFrame &prev_frame) { 1844 std::lock_guard<std::recursive_mutex> guard(m_mutex); 1845 assert(GetStackID() == 1846 prev_frame.GetStackID()); // TODO: remove this after some testing 1847 m_variable_list_sp = prev_frame.m_variable_list_sp; 1848 m_variable_list_value_objects.Swap(prev_frame.m_variable_list_value_objects); 1849 if (!m_disassembly.GetString().empty()) { 1850 m_disassembly.Clear(); 1851 m_disassembly.PutCString(prev_frame.m_disassembly.GetString()); 1852 } 1853 } 1854 1855 void StackFrame::UpdatePreviousFrameFromCurrentFrame(StackFrame &curr_frame) { 1856 std::lock_guard<std::recursive_mutex> guard(m_mutex); 1857 assert(GetStackID() == 1858 curr_frame.GetStackID()); // TODO: remove this after some testing 1859 m_id.SetPC(curr_frame.m_id.GetPC()); // Update the Stack ID PC value 1860 assert(GetThread() == curr_frame.GetThread()); 1861 m_frame_index = curr_frame.m_frame_index; 1862 m_concrete_frame_index = curr_frame.m_concrete_frame_index; 1863 m_reg_context_sp = curr_frame.m_reg_context_sp; 1864 m_frame_code_addr = curr_frame.m_frame_code_addr; 1865 m_behaves_like_zeroth_frame = curr_frame.m_behaves_like_zeroth_frame; 1866 assert(!m_sc.target_sp || !curr_frame.m_sc.target_sp || 1867 m_sc.target_sp.get() == curr_frame.m_sc.target_sp.get()); 1868 assert(!m_sc.module_sp || !curr_frame.m_sc.module_sp || 1869 m_sc.module_sp.get() == curr_frame.m_sc.module_sp.get()); 1870 assert(m_sc.comp_unit == nullptr || curr_frame.m_sc.comp_unit == nullptr || 1871 m_sc.comp_unit == curr_frame.m_sc.comp_unit); 1872 assert(m_sc.function == nullptr || curr_frame.m_sc.function == nullptr || 1873 m_sc.function == curr_frame.m_sc.function); 1874 m_sc = curr_frame.m_sc; 1875 m_flags.Clear(GOT_FRAME_BASE | eSymbolContextEverything); 1876 m_flags.Set(m_sc.GetResolvedMask()); 1877 m_frame_base.Clear(); 1878 m_frame_base_error.Clear(); 1879 } 1880 1881 bool StackFrame::HasCachedData() const { 1882 if (m_variable_list_sp) 1883 return true; 1884 if (m_variable_list_value_objects.GetSize() > 0) 1885 return true; 1886 if (!m_disassembly.GetString().empty()) 1887 return true; 1888 return false; 1889 } 1890 1891 bool StackFrame::GetStatus(Stream &strm, bool show_frame_info, bool show_source, 1892 bool show_unique, const char *frame_marker) { 1893 if (show_frame_info) { 1894 strm.Indent(); 1895 DumpUsingSettingsFormat(&strm, show_unique, frame_marker); 1896 } 1897 1898 if (show_source) { 1899 ExecutionContext exe_ctx(shared_from_this()); 1900 bool have_source = false, have_debuginfo = false; 1901 Debugger::StopDisassemblyType disasm_display = 1902 Debugger::eStopDisassemblyTypeNever; 1903 Target *target = exe_ctx.GetTargetPtr(); 1904 if (target) { 1905 Debugger &debugger = target->GetDebugger(); 1906 const uint32_t source_lines_before = 1907 debugger.GetStopSourceLineCount(true); 1908 const uint32_t source_lines_after = 1909 debugger.GetStopSourceLineCount(false); 1910 disasm_display = debugger.GetStopDisassemblyDisplay(); 1911 1912 GetSymbolContext(eSymbolContextCompUnit | eSymbolContextLineEntry); 1913 if (m_sc.comp_unit && m_sc.line_entry.IsValid()) { 1914 have_debuginfo = true; 1915 if (source_lines_before > 0 || source_lines_after > 0) { 1916 uint32_t start_line = m_sc.line_entry.line; 1917 if (!start_line && m_sc.function) { 1918 FileSpec source_file; 1919 m_sc.function->GetStartLineSourceInfo(source_file, start_line); 1920 } 1921 1922 size_t num_lines = 1923 target->GetSourceManager().DisplaySourceLinesWithLineNumbers( 1924 m_sc.line_entry.file, start_line, m_sc.line_entry.column, 1925 source_lines_before, source_lines_after, "->", &strm); 1926 if (num_lines != 0) 1927 have_source = true; 1928 // TODO: Give here a one time warning if source file is missing. 1929 if (!m_sc.line_entry.line) { 1930 ConstString fn_name = m_sc.GetFunctionName(); 1931 1932 if (!fn_name.IsEmpty()) 1933 strm.Printf( 1934 "Note: this address is compiler-generated code in function " 1935 "%s that has no source code associated with it.", 1936 fn_name.AsCString()); 1937 else 1938 strm.Printf("Note: this address is compiler-generated code that " 1939 "has no source code associated with it."); 1940 strm.EOL(); 1941 } 1942 } 1943 } 1944 switch (disasm_display) { 1945 case Debugger::eStopDisassemblyTypeNever: 1946 break; 1947 1948 case Debugger::eStopDisassemblyTypeNoDebugInfo: 1949 if (have_debuginfo) 1950 break; 1951 [[fallthrough]]; 1952 1953 case Debugger::eStopDisassemblyTypeNoSource: 1954 if (have_source) 1955 break; 1956 [[fallthrough]]; 1957 1958 case Debugger::eStopDisassemblyTypeAlways: 1959 if (target) { 1960 const uint32_t disasm_lines = debugger.GetDisassemblyLineCount(); 1961 if (disasm_lines > 0) { 1962 const ArchSpec &target_arch = target->GetArchitecture(); 1963 const char *plugin_name = nullptr; 1964 const char *flavor = nullptr; 1965 const bool mixed_source_and_assembly = false; 1966 Disassembler::Disassemble( 1967 target->GetDebugger(), target_arch, plugin_name, flavor, 1968 exe_ctx, GetFrameCodeAddress(), 1969 {Disassembler::Limit::Instructions, disasm_lines}, 1970 mixed_source_and_assembly, 0, 1971 Disassembler::eOptionMarkPCAddress, strm); 1972 } 1973 } 1974 break; 1975 } 1976 } 1977 } 1978 return true; 1979 } 1980 1981 RecognizedStackFrameSP StackFrame::GetRecognizedFrame() { 1982 if (!m_recognized_frame_sp) { 1983 m_recognized_frame_sp = GetThread() 1984 ->GetProcess() 1985 ->GetTarget() 1986 .GetFrameRecognizerManager() 1987 .RecognizeFrame(CalculateStackFrame()); 1988 } 1989 return m_recognized_frame_sp; 1990 } 1991