xref: /freebsd/contrib/llvm-project/lldb/source/Core/Disassembler.cpp (revision 0fca6ea1d4eea4c934cfff25ac9ee8ad6fe95583)
1 //===-- Disassembler.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/Core/Disassembler.h"
10 
11 #include "lldb/Core/AddressRange.h"
12 #include "lldb/Core/Debugger.h"
13 #include "lldb/Core/EmulateInstruction.h"
14 #include "lldb/Core/Mangled.h"
15 #include "lldb/Core/Module.h"
16 #include "lldb/Core/ModuleList.h"
17 #include "lldb/Core/PluginManager.h"
18 #include "lldb/Core/SourceManager.h"
19 #include "lldb/Host/FileSystem.h"
20 #include "lldb/Interpreter/OptionValue.h"
21 #include "lldb/Interpreter/OptionValueArray.h"
22 #include "lldb/Interpreter/OptionValueDictionary.h"
23 #include "lldb/Interpreter/OptionValueRegex.h"
24 #include "lldb/Interpreter/OptionValueString.h"
25 #include "lldb/Interpreter/OptionValueUInt64.h"
26 #include "lldb/Symbol/Function.h"
27 #include "lldb/Symbol/Symbol.h"
28 #include "lldb/Symbol/SymbolContext.h"
29 #include "lldb/Target/ExecutionContext.h"
30 #include "lldb/Target/SectionLoadList.h"
31 #include "lldb/Target/StackFrame.h"
32 #include "lldb/Target/Target.h"
33 #include "lldb/Target/Thread.h"
34 #include "lldb/Utility/DataBufferHeap.h"
35 #include "lldb/Utility/DataExtractor.h"
36 #include "lldb/Utility/RegularExpression.h"
37 #include "lldb/Utility/Status.h"
38 #include "lldb/Utility/Stream.h"
39 #include "lldb/Utility/StreamString.h"
40 #include "lldb/Utility/Timer.h"
41 #include "lldb/lldb-private-enumerations.h"
42 #include "lldb/lldb-private-interfaces.h"
43 #include "lldb/lldb-private-types.h"
44 #include "llvm/Support/Compiler.h"
45 #include "llvm/TargetParser/Triple.h"
46 
47 #include <cstdint>
48 #include <cstring>
49 #include <utility>
50 
51 #include <cassert>
52 
53 #define DEFAULT_DISASM_BYTE_SIZE 32
54 
55 using namespace lldb;
56 using namespace lldb_private;
57 
FindPlugin(const ArchSpec & arch,const char * flavor,const char * plugin_name)58 DisassemblerSP Disassembler::FindPlugin(const ArchSpec &arch,
59                                         const char *flavor,
60                                         const char *plugin_name) {
61   LLDB_SCOPED_TIMERF("Disassembler::FindPlugin (arch = %s, plugin_name = %s)",
62                      arch.GetArchitectureName(), plugin_name);
63 
64   DisassemblerCreateInstance create_callback = nullptr;
65 
66   if (plugin_name) {
67     create_callback =
68         PluginManager::GetDisassemblerCreateCallbackForPluginName(plugin_name);
69     if (create_callback) {
70       if (auto disasm_sp = create_callback(arch, flavor))
71         return disasm_sp;
72     }
73   } else {
74     for (uint32_t idx = 0;
75          (create_callback = PluginManager::GetDisassemblerCreateCallbackAtIndex(
76               idx)) != nullptr;
77          ++idx) {
78       if (auto disasm_sp = create_callback(arch, flavor))
79         return disasm_sp;
80     }
81   }
82   return DisassemblerSP();
83 }
84 
FindPluginForTarget(const Target & target,const ArchSpec & arch,const char * flavor,const char * plugin_name)85 DisassemblerSP Disassembler::FindPluginForTarget(const Target &target,
86                                                  const ArchSpec &arch,
87                                                  const char *flavor,
88                                                  const char *plugin_name) {
89   if (flavor == nullptr) {
90     // FIXME - we don't have the mechanism in place to do per-architecture
91     // settings.  But since we know that for now we only support flavors on x86
92     // & x86_64,
93     if (arch.GetTriple().getArch() == llvm::Triple::x86 ||
94         arch.GetTriple().getArch() == llvm::Triple::x86_64)
95       flavor = target.GetDisassemblyFlavor();
96   }
97   return FindPlugin(arch, flavor, plugin_name);
98 }
99 
ResolveAddress(Target & target,const Address & addr)100 static Address ResolveAddress(Target &target, const Address &addr) {
101   if (!addr.IsSectionOffset()) {
102     Address resolved_addr;
103     // If we weren't passed in a section offset address range, try and resolve
104     // it to something
105     bool is_resolved = target.GetSectionLoadList().IsEmpty()
106                            ? target.GetImages().ResolveFileAddress(
107                                  addr.GetOffset(), resolved_addr)
108                            : target.GetSectionLoadList().ResolveLoadAddress(
109                                  addr.GetOffset(), resolved_addr);
110 
111     // We weren't able to resolve the address, just treat it as a raw address
112     if (is_resolved && resolved_addr.IsValid())
113       return resolved_addr;
114   }
115   return addr;
116 }
117 
DisassembleRange(const ArchSpec & arch,const char * plugin_name,const char * flavor,Target & target,const AddressRange & range,bool force_live_memory)118 lldb::DisassemblerSP Disassembler::DisassembleRange(
119     const ArchSpec &arch, const char *plugin_name, const char *flavor,
120     Target &target, const AddressRange &range, bool force_live_memory) {
121   if (range.GetByteSize() <= 0)
122     return {};
123 
124   if (!range.GetBaseAddress().IsValid())
125     return {};
126 
127   lldb::DisassemblerSP disasm_sp =
128       Disassembler::FindPluginForTarget(target, arch, flavor, plugin_name);
129 
130   if (!disasm_sp)
131     return {};
132 
133   const size_t bytes_disassembled = disasm_sp->ParseInstructions(
134       target, range.GetBaseAddress(), {Limit::Bytes, range.GetByteSize()},
135       nullptr, force_live_memory);
136   if (bytes_disassembled == 0)
137     return {};
138 
139   return disasm_sp;
140 }
141 
142 lldb::DisassemblerSP
DisassembleBytes(const ArchSpec & arch,const char * plugin_name,const char * flavor,const Address & start,const void * src,size_t src_len,uint32_t num_instructions,bool data_from_file)143 Disassembler::DisassembleBytes(const ArchSpec &arch, const char *plugin_name,
144                                const char *flavor, const Address &start,
145                                const void *src, size_t src_len,
146                                uint32_t num_instructions, bool data_from_file) {
147   if (!src)
148     return {};
149 
150   lldb::DisassemblerSP disasm_sp =
151       Disassembler::FindPlugin(arch, flavor, plugin_name);
152 
153   if (!disasm_sp)
154     return {};
155 
156   DataExtractor data(src, src_len, arch.GetByteOrder(),
157                      arch.GetAddressByteSize());
158 
159   (void)disasm_sp->DecodeInstructions(start, data, 0, num_instructions, false,
160                                       data_from_file);
161   return disasm_sp;
162 }
163 
Disassemble(Debugger & debugger,const ArchSpec & arch,const char * plugin_name,const char * flavor,const ExecutionContext & exe_ctx,const Address & address,Limit limit,bool mixed_source_and_assembly,uint32_t num_mixed_context_lines,uint32_t options,Stream & strm)164 bool Disassembler::Disassemble(Debugger &debugger, const ArchSpec &arch,
165                                const char *plugin_name, const char *flavor,
166                                const ExecutionContext &exe_ctx,
167                                const Address &address, Limit limit,
168                                bool mixed_source_and_assembly,
169                                uint32_t num_mixed_context_lines,
170                                uint32_t options, Stream &strm) {
171   if (!exe_ctx.GetTargetPtr())
172     return false;
173 
174   lldb::DisassemblerSP disasm_sp(Disassembler::FindPluginForTarget(
175       exe_ctx.GetTargetRef(), arch, flavor, plugin_name));
176   if (!disasm_sp)
177     return false;
178 
179   const bool force_live_memory = true;
180   size_t bytes_disassembled = disasm_sp->ParseInstructions(
181       exe_ctx.GetTargetRef(), address, limit, &strm, force_live_memory);
182   if (bytes_disassembled == 0)
183     return false;
184 
185   disasm_sp->PrintInstructions(debugger, arch, exe_ctx,
186                                mixed_source_and_assembly,
187                                num_mixed_context_lines, options, strm);
188   return true;
189 }
190 
191 Disassembler::SourceLine
GetFunctionDeclLineEntry(const SymbolContext & sc)192 Disassembler::GetFunctionDeclLineEntry(const SymbolContext &sc) {
193   if (!sc.function)
194     return {};
195 
196   if (!sc.line_entry.IsValid())
197     return {};
198 
199   LineEntry prologue_end_line = sc.line_entry;
200   FileSpec func_decl_file;
201   uint32_t func_decl_line;
202   sc.function->GetStartLineSourceInfo(func_decl_file, func_decl_line);
203 
204   if (func_decl_file != prologue_end_line.GetFile() &&
205       func_decl_file != prologue_end_line.original_file_sp->GetSpecOnly())
206     return {};
207 
208   SourceLine decl_line;
209   decl_line.file = func_decl_file;
210   decl_line.line = func_decl_line;
211   // TODO: Do we care about column on these entries?  If so, we need to plumb
212   // that through GetStartLineSourceInfo.
213   decl_line.column = 0;
214   return decl_line;
215 }
216 
AddLineToSourceLineTables(SourceLine & line,std::map<FileSpec,std::set<uint32_t>> & source_lines_seen)217 void Disassembler::AddLineToSourceLineTables(
218     SourceLine &line,
219     std::map<FileSpec, std::set<uint32_t>> &source_lines_seen) {
220   if (line.IsValid()) {
221     auto source_lines_seen_pos = source_lines_seen.find(line.file);
222     if (source_lines_seen_pos == source_lines_seen.end()) {
223       std::set<uint32_t> lines;
224       lines.insert(line.line);
225       source_lines_seen.emplace(line.file, lines);
226     } else {
227       source_lines_seen_pos->second.insert(line.line);
228     }
229   }
230 }
231 
ElideMixedSourceAndDisassemblyLine(const ExecutionContext & exe_ctx,const SymbolContext & sc,SourceLine & line)232 bool Disassembler::ElideMixedSourceAndDisassemblyLine(
233     const ExecutionContext &exe_ctx, const SymbolContext &sc,
234     SourceLine &line) {
235 
236   // TODO: should we also check target.process.thread.step-avoid-libraries ?
237 
238   const RegularExpression *avoid_regex = nullptr;
239 
240   // Skip any line #0 entries - they are implementation details
241   if (line.line == 0)
242     return true;
243 
244   ThreadSP thread_sp = exe_ctx.GetThreadSP();
245   if (thread_sp) {
246     avoid_regex = thread_sp->GetSymbolsToAvoidRegexp();
247   } else {
248     TargetSP target_sp = exe_ctx.GetTargetSP();
249     if (target_sp) {
250       Status error;
251       OptionValueSP value_sp = target_sp->GetDebugger().GetPropertyValue(
252           &exe_ctx, "target.process.thread.step-avoid-regexp", error);
253       if (value_sp && value_sp->GetType() == OptionValue::eTypeRegex) {
254         OptionValueRegex *re = value_sp->GetAsRegex();
255         if (re) {
256           avoid_regex = re->GetCurrentValue();
257         }
258       }
259     }
260   }
261   if (avoid_regex && sc.symbol != nullptr) {
262     const char *function_name =
263         sc.GetFunctionName(Mangled::ePreferDemangledWithoutArguments)
264             .GetCString();
265     if (function_name && avoid_regex->Execute(function_name)) {
266       // skip this source line
267       return true;
268     }
269   }
270   // don't skip this source line
271   return false;
272 }
273 
PrintInstructions(Debugger & debugger,const ArchSpec & arch,const ExecutionContext & exe_ctx,bool mixed_source_and_assembly,uint32_t num_mixed_context_lines,uint32_t options,Stream & strm)274 void Disassembler::PrintInstructions(Debugger &debugger, const ArchSpec &arch,
275                                      const ExecutionContext &exe_ctx,
276                                      bool mixed_source_and_assembly,
277                                      uint32_t num_mixed_context_lines,
278                                      uint32_t options, Stream &strm) {
279   // We got some things disassembled...
280   size_t num_instructions_found = GetInstructionList().GetSize();
281 
282   const uint32_t max_opcode_byte_size =
283       GetInstructionList().GetMaxOpcocdeByteSize();
284   SymbolContext sc;
285   SymbolContext prev_sc;
286   AddressRange current_source_line_range;
287   const Address *pc_addr_ptr = nullptr;
288   StackFrame *frame = exe_ctx.GetFramePtr();
289 
290   TargetSP target_sp(exe_ctx.GetTargetSP());
291   SourceManager &source_manager =
292       target_sp ? target_sp->GetSourceManager() : debugger.GetSourceManager();
293 
294   if (frame) {
295     pc_addr_ptr = &frame->GetFrameCodeAddress();
296   }
297   const uint32_t scope =
298       eSymbolContextLineEntry | eSymbolContextFunction | eSymbolContextSymbol;
299   const bool use_inline_block_range = false;
300 
301   const FormatEntity::Entry *disassembly_format = nullptr;
302   FormatEntity::Entry format;
303   if (exe_ctx.HasTargetScope()) {
304     disassembly_format =
305         exe_ctx.GetTargetRef().GetDebugger().GetDisassemblyFormat();
306   } else {
307     FormatEntity::Parse("${addr}: ", format);
308     disassembly_format = &format;
309   }
310 
311   // First pass: step through the list of instructions, find how long the
312   // initial addresses strings are, insert padding in the second pass so the
313   // opcodes all line up nicely.
314 
315   // Also build up the source line mapping if this is mixed source & assembly
316   // mode. Calculate the source line for each assembly instruction (eliding
317   // inlined functions which the user wants to skip).
318 
319   std::map<FileSpec, std::set<uint32_t>> source_lines_seen;
320   Symbol *previous_symbol = nullptr;
321 
322   size_t address_text_size = 0;
323   for (size_t i = 0; i < num_instructions_found; ++i) {
324     Instruction *inst = GetInstructionList().GetInstructionAtIndex(i).get();
325     if (inst) {
326       const Address &addr = inst->GetAddress();
327       ModuleSP module_sp(addr.GetModule());
328       if (module_sp) {
329         const SymbolContextItem resolve_mask = eSymbolContextFunction |
330                                                eSymbolContextSymbol |
331                                                eSymbolContextLineEntry;
332         uint32_t resolved_mask =
333             module_sp->ResolveSymbolContextForAddress(addr, resolve_mask, sc);
334         if (resolved_mask) {
335           StreamString strmstr;
336           Debugger::FormatDisassemblerAddress(disassembly_format, &sc, nullptr,
337                                               &exe_ctx, &addr, strmstr);
338           size_t cur_line = strmstr.GetSizeOfLastLine();
339           if (cur_line > address_text_size)
340             address_text_size = cur_line;
341 
342           // Add entries to our "source_lines_seen" map+set which list which
343           // sources lines occur in this disassembly session.  We will print
344           // lines of context around a source line, but we don't want to print
345           // a source line that has a line table entry of its own - we'll leave
346           // that source line to be printed when it actually occurs in the
347           // disassembly.
348 
349           if (mixed_source_and_assembly && sc.line_entry.IsValid()) {
350             if (sc.symbol != previous_symbol) {
351               SourceLine decl_line = GetFunctionDeclLineEntry(sc);
352               if (!ElideMixedSourceAndDisassemblyLine(exe_ctx, sc, decl_line))
353                 AddLineToSourceLineTables(decl_line, source_lines_seen);
354             }
355             if (sc.line_entry.IsValid()) {
356               SourceLine this_line;
357               this_line.file = sc.line_entry.GetFile();
358               this_line.line = sc.line_entry.line;
359               this_line.column = sc.line_entry.column;
360               if (!ElideMixedSourceAndDisassemblyLine(exe_ctx, sc, this_line))
361                 AddLineToSourceLineTables(this_line, source_lines_seen);
362             }
363           }
364         }
365         sc.Clear(false);
366       }
367     }
368   }
369 
370   previous_symbol = nullptr;
371   SourceLine previous_line;
372   for (size_t i = 0; i < num_instructions_found; ++i) {
373     Instruction *inst = GetInstructionList().GetInstructionAtIndex(i).get();
374 
375     if (inst) {
376       const Address &addr = inst->GetAddress();
377       const bool inst_is_at_pc = pc_addr_ptr && addr == *pc_addr_ptr;
378       SourceLinesToDisplay source_lines_to_display;
379 
380       prev_sc = sc;
381 
382       ModuleSP module_sp(addr.GetModule());
383       if (module_sp) {
384         uint32_t resolved_mask = module_sp->ResolveSymbolContextForAddress(
385             addr, eSymbolContextEverything, sc);
386         if (resolved_mask) {
387           if (mixed_source_and_assembly) {
388 
389             // If we've started a new function (non-inlined), print all of the
390             // source lines from the function declaration until the first line
391             // table entry - typically the opening curly brace of the function.
392             if (previous_symbol != sc.symbol) {
393               // The default disassembly format puts an extra blank line
394               // between functions - so when we're displaying the source
395               // context for a function, we don't want to add a blank line
396               // after the source context or we'll end up with two of them.
397               if (previous_symbol != nullptr)
398                 source_lines_to_display.print_source_context_end_eol = false;
399 
400               previous_symbol = sc.symbol;
401               if (sc.function && sc.line_entry.IsValid()) {
402                 LineEntry prologue_end_line = sc.line_entry;
403                 if (!ElideMixedSourceAndDisassemblyLine(exe_ctx, sc,
404                                                         prologue_end_line)) {
405                   FileSpec func_decl_file;
406                   uint32_t func_decl_line;
407                   sc.function->GetStartLineSourceInfo(func_decl_file,
408                                                       func_decl_line);
409                   if (func_decl_file == prologue_end_line.GetFile() ||
410                       func_decl_file ==
411                           prologue_end_line.original_file_sp->GetSpecOnly()) {
412                     // Add all the lines between the function declaration and
413                     // the first non-prologue source line to the list of lines
414                     // to print.
415                     for (uint32_t lineno = func_decl_line;
416                          lineno <= prologue_end_line.line; lineno++) {
417                       SourceLine this_line;
418                       this_line.file = func_decl_file;
419                       this_line.line = lineno;
420                       source_lines_to_display.lines.push_back(this_line);
421                     }
422                     // Mark the last line as the "current" one.  Usually this
423                     // is the open curly brace.
424                     if (source_lines_to_display.lines.size() > 0)
425                       source_lines_to_display.current_source_line =
426                           source_lines_to_display.lines.size() - 1;
427                   }
428                 }
429               }
430               sc.GetAddressRange(scope, 0, use_inline_block_range,
431                                  current_source_line_range);
432             }
433 
434             // If we've left a previous source line's address range, print a
435             // new source line
436             if (!current_source_line_range.ContainsFileAddress(addr)) {
437               sc.GetAddressRange(scope, 0, use_inline_block_range,
438                                  current_source_line_range);
439 
440               if (sc != prev_sc && sc.comp_unit && sc.line_entry.IsValid()) {
441                 SourceLine this_line;
442                 this_line.file = sc.line_entry.GetFile();
443                 this_line.line = sc.line_entry.line;
444 
445                 if (!ElideMixedSourceAndDisassemblyLine(exe_ctx, sc,
446                                                         this_line)) {
447                   // Only print this source line if it is different from the
448                   // last source line we printed.  There may have been inlined
449                   // functions between these lines that we elided, resulting in
450                   // the same line being printed twice in a row for a
451                   // contiguous block of assembly instructions.
452                   if (this_line != previous_line) {
453 
454                     std::vector<uint32_t> previous_lines;
455                     for (uint32_t i = 0;
456                          i < num_mixed_context_lines &&
457                          (this_line.line - num_mixed_context_lines) > 0;
458                          i++) {
459                       uint32_t line =
460                           this_line.line - num_mixed_context_lines + i;
461                       auto pos = source_lines_seen.find(this_line.file);
462                       if (pos != source_lines_seen.end()) {
463                         if (pos->second.count(line) == 1) {
464                           previous_lines.clear();
465                         } else {
466                           previous_lines.push_back(line);
467                         }
468                       }
469                     }
470                     for (size_t i = 0; i < previous_lines.size(); i++) {
471                       SourceLine previous_line;
472                       previous_line.file = this_line.file;
473                       previous_line.line = previous_lines[i];
474                       auto pos = source_lines_seen.find(previous_line.file);
475                       if (pos != source_lines_seen.end()) {
476                         pos->second.insert(previous_line.line);
477                       }
478                       source_lines_to_display.lines.push_back(previous_line);
479                     }
480 
481                     source_lines_to_display.lines.push_back(this_line);
482                     source_lines_to_display.current_source_line =
483                         source_lines_to_display.lines.size() - 1;
484 
485                     for (uint32_t i = 0; i < num_mixed_context_lines; i++) {
486                       SourceLine next_line;
487                       next_line.file = this_line.file;
488                       next_line.line = this_line.line + i + 1;
489                       auto pos = source_lines_seen.find(next_line.file);
490                       if (pos != source_lines_seen.end()) {
491                         if (pos->second.count(next_line.line) == 1)
492                           break;
493                         pos->second.insert(next_line.line);
494                       }
495                       source_lines_to_display.lines.push_back(next_line);
496                     }
497                   }
498                   previous_line = this_line;
499                 }
500               }
501             }
502           }
503         } else {
504           sc.Clear(true);
505         }
506       }
507 
508       if (source_lines_to_display.lines.size() > 0) {
509         strm.EOL();
510         for (size_t idx = 0; idx < source_lines_to_display.lines.size();
511              idx++) {
512           SourceLine ln = source_lines_to_display.lines[idx];
513           const char *line_highlight = "";
514           if (inst_is_at_pc && (options & eOptionMarkPCSourceLine)) {
515             line_highlight = "->";
516           } else if (idx == source_lines_to_display.current_source_line) {
517             line_highlight = "**";
518           }
519           source_manager.DisplaySourceLinesWithLineNumbers(
520               ln.file, ln.line, ln.column, 0, 0, line_highlight, &strm);
521         }
522         if (source_lines_to_display.print_source_context_end_eol)
523           strm.EOL();
524       }
525 
526       const bool show_bytes = (options & eOptionShowBytes) != 0;
527       const bool show_control_flow_kind =
528           (options & eOptionShowControlFlowKind) != 0;
529       inst->Dump(&strm, max_opcode_byte_size, true, show_bytes,
530                  show_control_flow_kind, &exe_ctx, &sc, &prev_sc, nullptr,
531                  address_text_size);
532       strm.EOL();
533     } else {
534       break;
535     }
536   }
537 }
538 
Disassemble(Debugger & debugger,const ArchSpec & arch,StackFrame & frame,Stream & strm)539 bool Disassembler::Disassemble(Debugger &debugger, const ArchSpec &arch,
540                                StackFrame &frame, Stream &strm) {
541   AddressRange range;
542   SymbolContext sc(
543       frame.GetSymbolContext(eSymbolContextFunction | eSymbolContextSymbol));
544   if (sc.function) {
545     range = sc.function->GetAddressRange();
546   } else if (sc.symbol && sc.symbol->ValueIsAddress()) {
547     range.GetBaseAddress() = sc.symbol->GetAddressRef();
548     range.SetByteSize(sc.symbol->GetByteSize());
549   } else {
550     range.GetBaseAddress() = frame.GetFrameCodeAddress();
551   }
552 
553     if (range.GetBaseAddress().IsValid() && range.GetByteSize() == 0)
554       range.SetByteSize(DEFAULT_DISASM_BYTE_SIZE);
555 
556     Disassembler::Limit limit = {Disassembler::Limit::Bytes,
557                                  range.GetByteSize()};
558     if (limit.value == 0)
559       limit.value = DEFAULT_DISASM_BYTE_SIZE;
560 
561     return Disassemble(debugger, arch, nullptr, nullptr, frame,
562                        range.GetBaseAddress(), limit, false, 0, 0, strm);
563 }
564 
Instruction(const Address & address,AddressClass addr_class)565 Instruction::Instruction(const Address &address, AddressClass addr_class)
566     : m_address(address), m_address_class(addr_class), m_opcode(),
567       m_calculated_strings(false) {}
568 
569 Instruction::~Instruction() = default;
570 
GetAddressClass()571 AddressClass Instruction::GetAddressClass() {
572   if (m_address_class == AddressClass::eInvalid)
573     m_address_class = m_address.GetAddressClass();
574   return m_address_class;
575 }
576 
GetNameForInstructionControlFlowKind(lldb::InstructionControlFlowKind instruction_control_flow_kind)577 const char *Instruction::GetNameForInstructionControlFlowKind(
578     lldb::InstructionControlFlowKind instruction_control_flow_kind) {
579   switch (instruction_control_flow_kind) {
580   case eInstructionControlFlowKindUnknown:
581     return "unknown";
582   case eInstructionControlFlowKindOther:
583     return "other";
584   case eInstructionControlFlowKindCall:
585     return "call";
586   case eInstructionControlFlowKindReturn:
587     return "return";
588   case eInstructionControlFlowKindJump:
589     return "jump";
590   case eInstructionControlFlowKindCondJump:
591     return "cond jump";
592   case eInstructionControlFlowKindFarCall:
593     return "far call";
594   case eInstructionControlFlowKindFarReturn:
595     return "far return";
596   case eInstructionControlFlowKindFarJump:
597     return "far jump";
598   }
599   llvm_unreachable("Fully covered switch above!");
600 }
601 
Dump(lldb_private::Stream * s,uint32_t max_opcode_byte_size,bool show_address,bool show_bytes,bool show_control_flow_kind,const ExecutionContext * exe_ctx,const SymbolContext * sym_ctx,const SymbolContext * prev_sym_ctx,const FormatEntity::Entry * disassembly_addr_format,size_t max_address_text_size)602 void Instruction::Dump(lldb_private::Stream *s, uint32_t max_opcode_byte_size,
603                        bool show_address, bool show_bytes,
604                        bool show_control_flow_kind,
605                        const ExecutionContext *exe_ctx,
606                        const SymbolContext *sym_ctx,
607                        const SymbolContext *prev_sym_ctx,
608                        const FormatEntity::Entry *disassembly_addr_format,
609                        size_t max_address_text_size) {
610   size_t opcode_column_width = 7;
611   const size_t operand_column_width = 25;
612 
613   CalculateMnemonicOperandsAndCommentIfNeeded(exe_ctx);
614 
615   StreamString ss;
616 
617   if (show_address) {
618     Debugger::FormatDisassemblerAddress(disassembly_addr_format, sym_ctx,
619                                         prev_sym_ctx, exe_ctx, &m_address, ss);
620     ss.FillLastLineToColumn(max_address_text_size, ' ');
621   }
622 
623   if (show_bytes) {
624     if (m_opcode.GetType() == Opcode::eTypeBytes) {
625       // x86_64 and i386 are the only ones that use bytes right now so pad out
626       // the byte dump to be able to always show 15 bytes (3 chars each) plus a
627       // space
628       if (max_opcode_byte_size > 0)
629         m_opcode.Dump(&ss, max_opcode_byte_size * 3 + 1);
630       else
631         m_opcode.Dump(&ss, 15 * 3 + 1);
632     } else {
633       // Else, we have ARM or MIPS which can show up to a uint32_t 0x00000000
634       // (10 spaces) plus two for padding...
635       if (max_opcode_byte_size > 0)
636         m_opcode.Dump(&ss, max_opcode_byte_size * 3 + 1);
637       else
638         m_opcode.Dump(&ss, 12);
639     }
640   }
641 
642   if (show_control_flow_kind) {
643     lldb::InstructionControlFlowKind instruction_control_flow_kind =
644         GetControlFlowKind(exe_ctx);
645     ss.Printf("%-12s", GetNameForInstructionControlFlowKind(
646                            instruction_control_flow_kind));
647   }
648 
649   bool show_color = false;
650   if (exe_ctx) {
651     if (TargetSP target_sp = exe_ctx->GetTargetSP()) {
652       show_color = target_sp->GetDebugger().GetUseColor();
653     }
654   }
655   const size_t opcode_pos = ss.GetSizeOfLastLine();
656   const std::string &opcode_name =
657       show_color ? m_markup_opcode_name : m_opcode_name;
658   const std::string &mnemonics = show_color ? m_markup_mnemonics : m_mnemonics;
659 
660   // The default opcode size of 7 characters is plenty for most architectures
661   // but some like arm can pull out the occasional vqrshrun.s16.  We won't get
662   // consistent column spacing in these cases, unfortunately. Also note that we
663   // need to directly use m_opcode_name here (instead of opcode_name) so we
664   // don't include color codes as characters.
665   if (m_opcode_name.length() >= opcode_column_width) {
666     opcode_column_width = m_opcode_name.length() + 1;
667   }
668 
669   ss.PutCString(opcode_name);
670   ss.FillLastLineToColumn(opcode_pos + opcode_column_width, ' ');
671   ss.PutCString(mnemonics);
672 
673   if (!m_comment.empty()) {
674     ss.FillLastLineToColumn(
675         opcode_pos + opcode_column_width + operand_column_width, ' ');
676     ss.PutCString(" ; ");
677     ss.PutCString(m_comment);
678   }
679   s->PutCString(ss.GetString());
680 }
681 
DumpEmulation(const ArchSpec & arch)682 bool Instruction::DumpEmulation(const ArchSpec &arch) {
683   std::unique_ptr<EmulateInstruction> insn_emulator_up(
684       EmulateInstruction::FindPlugin(arch, eInstructionTypeAny, nullptr));
685   if (insn_emulator_up) {
686     insn_emulator_up->SetInstruction(GetOpcode(), GetAddress(), nullptr);
687     return insn_emulator_up->EvaluateInstruction(0);
688   }
689 
690   return false;
691 }
692 
CanSetBreakpoint()693 bool Instruction::CanSetBreakpoint () {
694   return !HasDelaySlot();
695 }
696 
HasDelaySlot()697 bool Instruction::HasDelaySlot() {
698   // Default is false.
699   return false;
700 }
701 
ReadArray(FILE * in_file,Stream & out_stream,OptionValue::Type data_type)702 OptionValueSP Instruction::ReadArray(FILE *in_file, Stream &out_stream,
703                                      OptionValue::Type data_type) {
704   bool done = false;
705   char buffer[1024];
706 
707   auto option_value_sp = std::make_shared<OptionValueArray>(1u << data_type);
708 
709   int idx = 0;
710   while (!done) {
711     if (!fgets(buffer, 1023, in_file)) {
712       out_stream.Printf(
713           "Instruction::ReadArray:  Error reading file (fgets).\n");
714       option_value_sp.reset();
715       return option_value_sp;
716     }
717 
718     std::string line(buffer);
719 
720     size_t len = line.size();
721     if (line[len - 1] == '\n') {
722       line[len - 1] = '\0';
723       line.resize(len - 1);
724     }
725 
726     if ((line.size() == 1) && line[0] == ']') {
727       done = true;
728       line.clear();
729     }
730 
731     if (!line.empty()) {
732       std::string value;
733       static RegularExpression g_reg_exp(
734           llvm::StringRef("^[ \t]*([^ \t]+)[ \t]*$"));
735       llvm::SmallVector<llvm::StringRef, 2> matches;
736       if (g_reg_exp.Execute(line, &matches))
737         value = matches[1].str();
738       else
739         value = line;
740 
741       OptionValueSP data_value_sp;
742       switch (data_type) {
743       case OptionValue::eTypeUInt64:
744         data_value_sp = std::make_shared<OptionValueUInt64>(0, 0);
745         data_value_sp->SetValueFromString(value);
746         break;
747       // Other types can be added later as needed.
748       default:
749         data_value_sp = std::make_shared<OptionValueString>(value.c_str(), "");
750         break;
751       }
752 
753       option_value_sp->GetAsArray()->InsertValue(idx, data_value_sp);
754       ++idx;
755     }
756   }
757 
758   return option_value_sp;
759 }
760 
ReadDictionary(FILE * in_file,Stream & out_stream)761 OptionValueSP Instruction::ReadDictionary(FILE *in_file, Stream &out_stream) {
762   bool done = false;
763   char buffer[1024];
764 
765   auto option_value_sp = std::make_shared<OptionValueDictionary>();
766   static constexpr llvm::StringLiteral encoding_key("data_encoding");
767   OptionValue::Type data_type = OptionValue::eTypeInvalid;
768 
769   while (!done) {
770     // Read the next line in the file
771     if (!fgets(buffer, 1023, in_file)) {
772       out_stream.Printf(
773           "Instruction::ReadDictionary: Error reading file (fgets).\n");
774       option_value_sp.reset();
775       return option_value_sp;
776     }
777 
778     // Check to see if the line contains the end-of-dictionary marker ("}")
779     std::string line(buffer);
780 
781     size_t len = line.size();
782     if (line[len - 1] == '\n') {
783       line[len - 1] = '\0';
784       line.resize(len - 1);
785     }
786 
787     if ((line.size() == 1) && (line[0] == '}')) {
788       done = true;
789       line.clear();
790     }
791 
792     // Try to find a key-value pair in the current line and add it to the
793     // dictionary.
794     if (!line.empty()) {
795       static RegularExpression g_reg_exp(llvm::StringRef(
796           "^[ \t]*([a-zA-Z_][a-zA-Z0-9_]*)[ \t]*=[ \t]*(.*)[ \t]*$"));
797 
798       llvm::SmallVector<llvm::StringRef, 3> matches;
799 
800       bool reg_exp_success = g_reg_exp.Execute(line, &matches);
801       std::string key;
802       std::string value;
803       if (reg_exp_success) {
804         key = matches[1].str();
805         value = matches[2].str();
806       } else {
807         out_stream.Printf("Instruction::ReadDictionary: Failure executing "
808                           "regular expression.\n");
809         option_value_sp.reset();
810         return option_value_sp;
811       }
812 
813       // Check value to see if it's the start of an array or dictionary.
814 
815       lldb::OptionValueSP value_sp;
816       assert(value.empty() == false);
817       assert(key.empty() == false);
818 
819       if (value[0] == '{') {
820         assert(value.size() == 1);
821         // value is a dictionary
822         value_sp = ReadDictionary(in_file, out_stream);
823         if (!value_sp) {
824           option_value_sp.reset();
825           return option_value_sp;
826         }
827       } else if (value[0] == '[') {
828         assert(value.size() == 1);
829         // value is an array
830         value_sp = ReadArray(in_file, out_stream, data_type);
831         if (!value_sp) {
832           option_value_sp.reset();
833           return option_value_sp;
834         }
835         // We've used the data_type to read an array; re-set the type to
836         // Invalid
837         data_type = OptionValue::eTypeInvalid;
838       } else if ((value[0] == '0') && (value[1] == 'x')) {
839         value_sp = std::make_shared<OptionValueUInt64>(0, 0);
840         value_sp->SetValueFromString(value);
841       } else {
842         size_t len = value.size();
843         if ((value[0] == '"') && (value[len - 1] == '"'))
844           value = value.substr(1, len - 2);
845         value_sp = std::make_shared<OptionValueString>(value.c_str(), "");
846       }
847 
848       if (key == encoding_key) {
849         // A 'data_encoding=..." is NOT a normal key-value pair; it is meta-data
850         // indicating the data type of an upcoming array (usually the next bit
851         // of data to be read in).
852         if (llvm::StringRef(value) == "uint32_t")
853           data_type = OptionValue::eTypeUInt64;
854       } else
855         option_value_sp->GetAsDictionary()->SetValueForKey(key, value_sp,
856                                                            false);
857     }
858   }
859 
860   return option_value_sp;
861 }
862 
TestEmulation(Stream & out_stream,const char * file_name)863 bool Instruction::TestEmulation(Stream &out_stream, const char *file_name) {
864   if (!file_name) {
865     out_stream.Printf("Instruction::TestEmulation:  Missing file_name.");
866     return false;
867   }
868   FILE *test_file = FileSystem::Instance().Fopen(file_name, "r");
869   if (!test_file) {
870     out_stream.Printf(
871         "Instruction::TestEmulation: Attempt to open test file failed.");
872     return false;
873   }
874 
875   char buffer[256];
876   if (!fgets(buffer, 255, test_file)) {
877     out_stream.Printf(
878         "Instruction::TestEmulation: Error reading first line of test file.\n");
879     fclose(test_file);
880     return false;
881   }
882 
883   if (strncmp(buffer, "InstructionEmulationState={", 27) != 0) {
884     out_stream.Printf("Instructin::TestEmulation: Test file does not contain "
885                       "emulation state dictionary\n");
886     fclose(test_file);
887     return false;
888   }
889 
890   // Read all the test information from the test file into an
891   // OptionValueDictionary.
892 
893   OptionValueSP data_dictionary_sp(ReadDictionary(test_file, out_stream));
894   if (!data_dictionary_sp) {
895     out_stream.Printf(
896         "Instruction::TestEmulation:  Error reading Dictionary Object.\n");
897     fclose(test_file);
898     return false;
899   }
900 
901   fclose(test_file);
902 
903   OptionValueDictionary *data_dictionary =
904       data_dictionary_sp->GetAsDictionary();
905   static constexpr llvm::StringLiteral description_key("assembly_string");
906   static constexpr llvm::StringLiteral triple_key("triple");
907 
908   OptionValueSP value_sp = data_dictionary->GetValueForKey(description_key);
909 
910   if (!value_sp) {
911     out_stream.Printf("Instruction::TestEmulation:  Test file does not "
912                       "contain description string.\n");
913     return false;
914   }
915 
916   SetDescription(value_sp->GetValueAs<llvm::StringRef>().value_or(""));
917 
918   value_sp = data_dictionary->GetValueForKey(triple_key);
919   if (!value_sp) {
920     out_stream.Printf(
921         "Instruction::TestEmulation: Test file does not contain triple.\n");
922     return false;
923   }
924 
925   ArchSpec arch;
926   arch.SetTriple(
927       llvm::Triple(value_sp->GetValueAs<llvm::StringRef>().value_or("")));
928 
929   bool success = false;
930   std::unique_ptr<EmulateInstruction> insn_emulator_up(
931       EmulateInstruction::FindPlugin(arch, eInstructionTypeAny, nullptr));
932   if (insn_emulator_up)
933     success =
934         insn_emulator_up->TestEmulation(out_stream, arch, data_dictionary);
935 
936   if (success)
937     out_stream.Printf("Emulation test succeeded.");
938   else
939     out_stream.Printf("Emulation test failed.");
940 
941   return success;
942 }
943 
Emulate(const ArchSpec & arch,uint32_t evaluate_options,void * baton,EmulateInstruction::ReadMemoryCallback read_mem_callback,EmulateInstruction::WriteMemoryCallback write_mem_callback,EmulateInstruction::ReadRegisterCallback read_reg_callback,EmulateInstruction::WriteRegisterCallback write_reg_callback)944 bool Instruction::Emulate(
945     const ArchSpec &arch, uint32_t evaluate_options, void *baton,
946     EmulateInstruction::ReadMemoryCallback read_mem_callback,
947     EmulateInstruction::WriteMemoryCallback write_mem_callback,
948     EmulateInstruction::ReadRegisterCallback read_reg_callback,
949     EmulateInstruction::WriteRegisterCallback write_reg_callback) {
950   std::unique_ptr<EmulateInstruction> insn_emulator_up(
951       EmulateInstruction::FindPlugin(arch, eInstructionTypeAny, nullptr));
952   if (insn_emulator_up) {
953     insn_emulator_up->SetBaton(baton);
954     insn_emulator_up->SetCallbacks(read_mem_callback, write_mem_callback,
955                                    read_reg_callback, write_reg_callback);
956     insn_emulator_up->SetInstruction(GetOpcode(), GetAddress(), nullptr);
957     return insn_emulator_up->EvaluateInstruction(evaluate_options);
958   }
959 
960   return false;
961 }
962 
GetData(DataExtractor & data)963 uint32_t Instruction::GetData(DataExtractor &data) {
964   return m_opcode.GetData(data);
965 }
966 
InstructionList()967 InstructionList::InstructionList() : m_instructions() {}
968 
969 InstructionList::~InstructionList() = default;
970 
GetSize() const971 size_t InstructionList::GetSize() const { return m_instructions.size(); }
972 
GetMaxOpcocdeByteSize() const973 uint32_t InstructionList::GetMaxOpcocdeByteSize() const {
974   uint32_t max_inst_size = 0;
975   collection::const_iterator pos, end;
976   for (pos = m_instructions.begin(), end = m_instructions.end(); pos != end;
977        ++pos) {
978     uint32_t inst_size = (*pos)->GetOpcode().GetByteSize();
979     if (max_inst_size < inst_size)
980       max_inst_size = inst_size;
981   }
982   return max_inst_size;
983 }
984 
GetInstructionAtIndex(size_t idx) const985 InstructionSP InstructionList::GetInstructionAtIndex(size_t idx) const {
986   InstructionSP inst_sp;
987   if (idx < m_instructions.size())
988     inst_sp = m_instructions[idx];
989   return inst_sp;
990 }
991 
GetInstructionAtAddress(const Address & address)992 InstructionSP InstructionList::GetInstructionAtAddress(const Address &address) {
993   uint32_t index = GetIndexOfInstructionAtAddress(address);
994   if (index != UINT32_MAX)
995     return GetInstructionAtIndex(index);
996   return nullptr;
997 }
998 
Dump(Stream * s,bool show_address,bool show_bytes,bool show_control_flow_kind,const ExecutionContext * exe_ctx)999 void InstructionList::Dump(Stream *s, bool show_address, bool show_bytes,
1000                            bool show_control_flow_kind,
1001                            const ExecutionContext *exe_ctx) {
1002   const uint32_t max_opcode_byte_size = GetMaxOpcocdeByteSize();
1003   collection::const_iterator pos, begin, end;
1004 
1005   const FormatEntity::Entry *disassembly_format = nullptr;
1006   FormatEntity::Entry format;
1007   if (exe_ctx && exe_ctx->HasTargetScope()) {
1008     disassembly_format =
1009         exe_ctx->GetTargetRef().GetDebugger().GetDisassemblyFormat();
1010   } else {
1011     FormatEntity::Parse("${addr}: ", format);
1012     disassembly_format = &format;
1013   }
1014 
1015   for (begin = m_instructions.begin(), end = m_instructions.end(), pos = begin;
1016        pos != end; ++pos) {
1017     if (pos != begin)
1018       s->EOL();
1019     (*pos)->Dump(s, max_opcode_byte_size, show_address, show_bytes,
1020                  show_control_flow_kind, exe_ctx, nullptr, nullptr,
1021                  disassembly_format, 0);
1022   }
1023 }
1024 
Clear()1025 void InstructionList::Clear() { m_instructions.clear(); }
1026 
Append(lldb::InstructionSP & inst_sp)1027 void InstructionList::Append(lldb::InstructionSP &inst_sp) {
1028   if (inst_sp)
1029     m_instructions.push_back(inst_sp);
1030 }
1031 
1032 uint32_t
GetIndexOfNextBranchInstruction(uint32_t start,bool ignore_calls,bool * found_calls) const1033 InstructionList::GetIndexOfNextBranchInstruction(uint32_t start,
1034                                                  bool ignore_calls,
1035                                                  bool *found_calls) const {
1036   size_t num_instructions = m_instructions.size();
1037 
1038   uint32_t next_branch = UINT32_MAX;
1039 
1040   if (found_calls)
1041     *found_calls = false;
1042   for (size_t i = start; i < num_instructions; i++) {
1043     if (m_instructions[i]->DoesBranch()) {
1044       if (ignore_calls && m_instructions[i]->IsCall()) {
1045         if (found_calls)
1046           *found_calls = true;
1047         continue;
1048       }
1049       next_branch = i;
1050       break;
1051     }
1052   }
1053 
1054   return next_branch;
1055 }
1056 
1057 uint32_t
GetIndexOfInstructionAtAddress(const Address & address)1058 InstructionList::GetIndexOfInstructionAtAddress(const Address &address) {
1059   size_t num_instructions = m_instructions.size();
1060   uint32_t index = UINT32_MAX;
1061   for (size_t i = 0; i < num_instructions; i++) {
1062     if (m_instructions[i]->GetAddress() == address) {
1063       index = i;
1064       break;
1065     }
1066   }
1067   return index;
1068 }
1069 
1070 uint32_t
GetIndexOfInstructionAtLoadAddress(lldb::addr_t load_addr,Target & target)1071 InstructionList::GetIndexOfInstructionAtLoadAddress(lldb::addr_t load_addr,
1072                                                     Target &target) {
1073   Address address;
1074   address.SetLoadAddress(load_addr, &target);
1075   return GetIndexOfInstructionAtAddress(address);
1076 }
1077 
ParseInstructions(Target & target,Address start,Limit limit,Stream * error_strm_ptr,bool force_live_memory)1078 size_t Disassembler::ParseInstructions(Target &target, Address start,
1079                                        Limit limit, Stream *error_strm_ptr,
1080                                        bool force_live_memory) {
1081   m_instruction_list.Clear();
1082 
1083   if (!start.IsValid())
1084     return 0;
1085 
1086   start = ResolveAddress(target, start);
1087 
1088   addr_t byte_size = limit.value;
1089   if (limit.kind == Limit::Instructions)
1090     byte_size *= m_arch.GetMaximumOpcodeByteSize();
1091   auto data_sp = std::make_shared<DataBufferHeap>(byte_size, '\0');
1092 
1093   Status error;
1094   lldb::addr_t load_addr = LLDB_INVALID_ADDRESS;
1095   const size_t bytes_read =
1096       target.ReadMemory(start, data_sp->GetBytes(), data_sp->GetByteSize(),
1097                         error, force_live_memory, &load_addr);
1098   const bool data_from_file = load_addr == LLDB_INVALID_ADDRESS;
1099 
1100   if (bytes_read == 0) {
1101     if (error_strm_ptr) {
1102       if (const char *error_cstr = error.AsCString())
1103         error_strm_ptr->Printf("error: %s\n", error_cstr);
1104     }
1105     return 0;
1106   }
1107 
1108   if (bytes_read != data_sp->GetByteSize())
1109     data_sp->SetByteSize(bytes_read);
1110   DataExtractor data(data_sp, m_arch.GetByteOrder(),
1111                      m_arch.GetAddressByteSize());
1112   return DecodeInstructions(start, data, 0,
1113                             limit.kind == Limit::Instructions ? limit.value
1114                                                               : UINT32_MAX,
1115                             false, data_from_file);
1116 }
1117 
1118 // Disassembler copy constructor
Disassembler(const ArchSpec & arch,const char * flavor)1119 Disassembler::Disassembler(const ArchSpec &arch, const char *flavor)
1120     : m_arch(arch), m_instruction_list(), m_flavor() {
1121   if (flavor == nullptr)
1122     m_flavor.assign("default");
1123   else
1124     m_flavor.assign(flavor);
1125 
1126   // If this is an arm variant that can only include thumb (T16, T32)
1127   // instructions, force the arch triple to be "thumbv.." instead of "armv..."
1128   if (arch.IsAlwaysThumbInstructions()) {
1129     std::string thumb_arch_name(arch.GetTriple().getArchName().str());
1130     // Replace "arm" with "thumb" so we get all thumb variants correct
1131     if (thumb_arch_name.size() > 3) {
1132       thumb_arch_name.erase(0, 3);
1133       thumb_arch_name.insert(0, "thumb");
1134     }
1135     m_arch.SetTriple(thumb_arch_name.c_str());
1136   }
1137 }
1138 
1139 Disassembler::~Disassembler() = default;
1140 
GetInstructionList()1141 InstructionList &Disassembler::GetInstructionList() {
1142   return m_instruction_list;
1143 }
1144 
GetInstructionList() const1145 const InstructionList &Disassembler::GetInstructionList() const {
1146   return m_instruction_list;
1147 }
1148 
1149 // Class PseudoInstruction
1150 
PseudoInstruction()1151 PseudoInstruction::PseudoInstruction()
1152     : Instruction(Address(), AddressClass::eUnknown), m_description() {}
1153 
1154 PseudoInstruction::~PseudoInstruction() = default;
1155 
DoesBranch()1156 bool PseudoInstruction::DoesBranch() {
1157   // This is NOT a valid question for a pseudo instruction.
1158   return false;
1159 }
1160 
HasDelaySlot()1161 bool PseudoInstruction::HasDelaySlot() {
1162   // This is NOT a valid question for a pseudo instruction.
1163   return false;
1164 }
1165 
IsLoad()1166 bool PseudoInstruction::IsLoad() { return false; }
1167 
IsAuthenticated()1168 bool PseudoInstruction::IsAuthenticated() { return false; }
1169 
Decode(const lldb_private::Disassembler & disassembler,const lldb_private::DataExtractor & data,lldb::offset_t data_offset)1170 size_t PseudoInstruction::Decode(const lldb_private::Disassembler &disassembler,
1171                                  const lldb_private::DataExtractor &data,
1172                                  lldb::offset_t data_offset) {
1173   return m_opcode.GetByteSize();
1174 }
1175 
SetOpcode(size_t opcode_size,void * opcode_data)1176 void PseudoInstruction::SetOpcode(size_t opcode_size, void *opcode_data) {
1177   if (!opcode_data)
1178     return;
1179 
1180   switch (opcode_size) {
1181   case 8: {
1182     uint8_t value8 = *((uint8_t *)opcode_data);
1183     m_opcode.SetOpcode8(value8, eByteOrderInvalid);
1184     break;
1185   }
1186   case 16: {
1187     uint16_t value16 = *((uint16_t *)opcode_data);
1188     m_opcode.SetOpcode16(value16, eByteOrderInvalid);
1189     break;
1190   }
1191   case 32: {
1192     uint32_t value32 = *((uint32_t *)opcode_data);
1193     m_opcode.SetOpcode32(value32, eByteOrderInvalid);
1194     break;
1195   }
1196   case 64: {
1197     uint64_t value64 = *((uint64_t *)opcode_data);
1198     m_opcode.SetOpcode64(value64, eByteOrderInvalid);
1199     break;
1200   }
1201   default:
1202     break;
1203   }
1204 }
1205 
SetDescription(llvm::StringRef description)1206 void PseudoInstruction::SetDescription(llvm::StringRef description) {
1207   m_description = std::string(description);
1208 }
1209 
BuildRegister(ConstString & r)1210 Instruction::Operand Instruction::Operand::BuildRegister(ConstString &r) {
1211   Operand ret;
1212   ret.m_type = Type::Register;
1213   ret.m_register = r;
1214   return ret;
1215 }
1216 
BuildImmediate(lldb::addr_t imm,bool neg)1217 Instruction::Operand Instruction::Operand::BuildImmediate(lldb::addr_t imm,
1218                                                           bool neg) {
1219   Operand ret;
1220   ret.m_type = Type::Immediate;
1221   ret.m_immediate = imm;
1222   ret.m_negative = neg;
1223   return ret;
1224 }
1225 
BuildImmediate(int64_t imm)1226 Instruction::Operand Instruction::Operand::BuildImmediate(int64_t imm) {
1227   Operand ret;
1228   ret.m_type = Type::Immediate;
1229   if (imm < 0) {
1230     ret.m_immediate = -imm;
1231     ret.m_negative = true;
1232   } else {
1233     ret.m_immediate = imm;
1234     ret.m_negative = false;
1235   }
1236   return ret;
1237 }
1238 
1239 Instruction::Operand
BuildDereference(const Operand & ref)1240 Instruction::Operand::BuildDereference(const Operand &ref) {
1241   Operand ret;
1242   ret.m_type = Type::Dereference;
1243   ret.m_children = {ref};
1244   return ret;
1245 }
1246 
BuildSum(const Operand & lhs,const Operand & rhs)1247 Instruction::Operand Instruction::Operand::BuildSum(const Operand &lhs,
1248                                                     const Operand &rhs) {
1249   Operand ret;
1250   ret.m_type = Type::Sum;
1251   ret.m_children = {lhs, rhs};
1252   return ret;
1253 }
1254 
BuildProduct(const Operand & lhs,const Operand & rhs)1255 Instruction::Operand Instruction::Operand::BuildProduct(const Operand &lhs,
1256                                                         const Operand &rhs) {
1257   Operand ret;
1258   ret.m_type = Type::Product;
1259   ret.m_children = {lhs, rhs};
1260   return ret;
1261 }
1262 
1263 std::function<bool(const Instruction::Operand &)>
MatchBinaryOp(std::function<bool (const Instruction::Operand &)> base,std::function<bool (const Instruction::Operand &)> left,std::function<bool (const Instruction::Operand &)> right)1264 lldb_private::OperandMatchers::MatchBinaryOp(
1265     std::function<bool(const Instruction::Operand &)> base,
1266     std::function<bool(const Instruction::Operand &)> left,
1267     std::function<bool(const Instruction::Operand &)> right) {
1268   return [base, left, right](const Instruction::Operand &op) -> bool {
1269     return (base(op) && op.m_children.size() == 2 &&
1270             ((left(op.m_children[0]) && right(op.m_children[1])) ||
1271              (left(op.m_children[1]) && right(op.m_children[0]))));
1272   };
1273 }
1274 
1275 std::function<bool(const Instruction::Operand &)>
MatchUnaryOp(std::function<bool (const Instruction::Operand &)> base,std::function<bool (const Instruction::Operand &)> child)1276 lldb_private::OperandMatchers::MatchUnaryOp(
1277     std::function<bool(const Instruction::Operand &)> base,
1278     std::function<bool(const Instruction::Operand &)> child) {
1279   return [base, child](const Instruction::Operand &op) -> bool {
1280     return (base(op) && op.m_children.size() == 1 && child(op.m_children[0]));
1281   };
1282 }
1283 
1284 std::function<bool(const Instruction::Operand &)>
MatchRegOp(const RegisterInfo & info)1285 lldb_private::OperandMatchers::MatchRegOp(const RegisterInfo &info) {
1286   return [&info](const Instruction::Operand &op) {
1287     return (op.m_type == Instruction::Operand::Type::Register &&
1288             (op.m_register == ConstString(info.name) ||
1289              op.m_register == ConstString(info.alt_name)));
1290   };
1291 }
1292 
1293 std::function<bool(const Instruction::Operand &)>
FetchRegOp(ConstString & reg)1294 lldb_private::OperandMatchers::FetchRegOp(ConstString &reg) {
1295   return [&reg](const Instruction::Operand &op) {
1296     if (op.m_type != Instruction::Operand::Type::Register) {
1297       return false;
1298     }
1299     reg = op.m_register;
1300     return true;
1301   };
1302 }
1303 
1304 std::function<bool(const Instruction::Operand &)>
MatchImmOp(int64_t imm)1305 lldb_private::OperandMatchers::MatchImmOp(int64_t imm) {
1306   return [imm](const Instruction::Operand &op) {
1307     return (op.m_type == Instruction::Operand::Type::Immediate &&
1308             ((op.m_negative && op.m_immediate == (uint64_t)-imm) ||
1309              (!op.m_negative && op.m_immediate == (uint64_t)imm)));
1310   };
1311 }
1312 
1313 std::function<bool(const Instruction::Operand &)>
FetchImmOp(int64_t & imm)1314 lldb_private::OperandMatchers::FetchImmOp(int64_t &imm) {
1315   return [&imm](const Instruction::Operand &op) {
1316     if (op.m_type != Instruction::Operand::Type::Immediate) {
1317       return false;
1318     }
1319     if (op.m_negative) {
1320       imm = -((int64_t)op.m_immediate);
1321     } else {
1322       imm = ((int64_t)op.m_immediate);
1323     }
1324     return true;
1325   };
1326 }
1327 
1328 std::function<bool(const Instruction::Operand &)>
MatchOpType(Instruction::Operand::Type type)1329 lldb_private::OperandMatchers::MatchOpType(Instruction::Operand::Type type) {
1330   return [type](const Instruction::Operand &op) { return op.m_type == type; };
1331 }
1332