// Copyright (c) 2010 Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // source_line_resolver_base.cc: Implementation of SourceLineResolverBase. // // See source_line_resolver_base.h and source_line_resolver_base_types.h for // more documentation. // // Author: Siyang Xie (lambxsy@google.com) #include #include #include #include #include #include "google_breakpad/processor/source_line_resolver_base.h" #include "processor/source_line_resolver_base_types.h" #include "processor/module_factory.h" using std::map; using std::make_pair; namespace google_breakpad { SourceLineResolverBase::SourceLineResolverBase( ModuleFactory* module_factory) : modules_(new ModuleMap), corrupt_modules_(new ModuleSet), memory_buffers_(new MemoryMap), module_factory_(module_factory) { } SourceLineResolverBase::~SourceLineResolverBase() { ModuleMap::iterator it; // Iterate through ModuleMap and delete all loaded modules. for (it = modules_->begin(); it != modules_->end(); ++it) { // Delete individual module. delete it->second; } // Delete the map of modules. delete modules_; modules_ = NULL; // Delete the set of corrupt modules. delete corrupt_modules_; corrupt_modules_ = NULL; MemoryMap::iterator iter = memory_buffers_->begin(); for (; iter != memory_buffers_->end(); ++iter) { delete [] iter->second; } // Delete the map of memory buffers. delete memory_buffers_; memory_buffers_ = NULL; delete module_factory_; module_factory_ = NULL; } bool SourceLineResolverBase::ReadSymbolFile(const string& map_file, char** symbol_data, size_t* symbol_data_size) { if (symbol_data == NULL || symbol_data_size == NULL) { BPLOG(ERROR) << "Could not Read file into Null memory pointer"; return false; } struct stat buf; int error_code = stat(map_file.c_str(), &buf); if (error_code == -1) { string error_string; error_code = ErrnoString(&error_string); BPLOG(ERROR) << "Could not open " << map_file << ", error " << error_code << ": " << error_string; return false; } off_t file_size = buf.st_size; // Allocate memory for file contents, plus a null terminator // since we may use strtok() on the contents. *symbol_data_size = file_size + 1; *symbol_data = new char[file_size + 1]; if (*symbol_data == NULL) { BPLOG(ERROR) << "Could not allocate memory for " << map_file; return false; } BPLOG(INFO) << "Opening " << map_file; FILE* f = fopen(map_file.c_str(), "rt"); if (!f) { string error_string; error_code = ErrnoString(&error_string); BPLOG(ERROR) << "Could not open " << map_file << ", error " << error_code << ": " << error_string; delete [] (*symbol_data); *symbol_data = NULL; return false; } AutoFileCloser closer(f); int items_read = 0; items_read = fread(*symbol_data, 1, file_size, f); if (items_read != file_size) { string error_string; error_code = ErrnoString(&error_string); BPLOG(ERROR) << "Could not slurp " << map_file << ", error " << error_code << ": " << error_string; delete [] (*symbol_data); *symbol_data = NULL; return false; } (*symbol_data)[file_size] = '\0'; return true; } bool SourceLineResolverBase::LoadModule(const CodeModule* module, const string& map_file) { if (module == NULL) return false; // Make sure we don't already have a module with the given name. if (modules_->find(module->code_file()) != modules_->end()) { BPLOG(INFO) << "Symbols for module " << module->code_file() << " already loaded"; return false; } BPLOG(INFO) << "Loading symbols for module " << module->code_file() << " from " << map_file; char* memory_buffer; size_t memory_buffer_size; if (!ReadSymbolFile(map_file, &memory_buffer, &memory_buffer_size)) return false; BPLOG(INFO) << "Read symbol file " << map_file << " succeeded"; bool load_result = LoadModuleUsingMemoryBuffer(module, memory_buffer, memory_buffer_size); if (load_result && !ShouldDeleteMemoryBufferAfterLoadModule()) { // memory_buffer has to stay alive as long as the module. memory_buffers_->insert(make_pair(module->code_file(), memory_buffer)); } else { delete [] memory_buffer; } return load_result; } bool SourceLineResolverBase::LoadModuleUsingMapBuffer( const CodeModule* module, const string& map_buffer) { if (module == NULL) return false; // Make sure we don't already have a module with the given name. if (modules_->find(module->code_file()) != modules_->end()) { BPLOG(INFO) << "Symbols for module " << module->code_file() << " already loaded"; return false; } size_t memory_buffer_size = map_buffer.size() + 1; char* memory_buffer = new char[memory_buffer_size]; if (memory_buffer == NULL) { BPLOG(ERROR) << "Could not allocate memory for " << module->code_file(); return false; } // Can't use strcpy, as the data may contain '\0's before the end. memcpy(memory_buffer, map_buffer.c_str(), map_buffer.size()); memory_buffer[map_buffer.size()] = '\0'; bool load_result = LoadModuleUsingMemoryBuffer(module, memory_buffer, memory_buffer_size); if (load_result && !ShouldDeleteMemoryBufferAfterLoadModule()) { // memory_buffer has to stay alive as long as the module. memory_buffers_->insert(make_pair(module->code_file(), memory_buffer)); } else { delete [] memory_buffer; } return load_result; } bool SourceLineResolverBase::LoadModuleUsingMemoryBuffer( const CodeModule* module, char* memory_buffer, size_t memory_buffer_size) { if (!module) return false; // Make sure we don't already have a module with the given name. if (modules_->find(module->code_file()) != modules_->end()) { BPLOG(INFO) << "Symbols for module " << module->code_file() << " already loaded"; return false; } BPLOG(INFO) << "Loading symbols for module " << module->code_file() << " from memory buffer"; Module* basic_module = module_factory_->CreateModule(module->code_file()); // Ownership of memory is NOT transfered to Module::LoadMapFromMemory(). if (!basic_module->LoadMapFromMemory(memory_buffer, memory_buffer_size)) { BPLOG(ERROR) << "Too many error while parsing symbol data for module " << module->code_file(); // Returning false from here would be an indication that the symbols for // this module are missing which would be wrong. Intentionally fall through // and add the module to both the modules_ and the corrupt_modules_ lists. assert(basic_module->IsCorrupt()); } modules_->insert(make_pair(module->code_file(), basic_module)); if (basic_module->IsCorrupt()) { corrupt_modules_->insert(module->code_file()); } return true; } bool SourceLineResolverBase::ShouldDeleteMemoryBufferAfterLoadModule() { return true; } void SourceLineResolverBase::UnloadModule(const CodeModule* code_module) { if (!code_module) return; ModuleMap::iterator mod_iter = modules_->find(code_module->code_file()); if (mod_iter != modules_->end()) { Module* symbol_module = mod_iter->second; delete symbol_module; corrupt_modules_->erase(mod_iter->first); modules_->erase(mod_iter); } if (ShouldDeleteMemoryBufferAfterLoadModule()) { // No-op. Because we never store any memory buffers. } else { // There may be a buffer stored locally, we need to find and delete it. MemoryMap::iterator iter = memory_buffers_->find(code_module->code_file()); if (iter != memory_buffers_->end()) { delete [] iter->second; memory_buffers_->erase(iter); } } } bool SourceLineResolverBase::HasModule(const CodeModule* module) { if (!module) return false; return modules_->find(module->code_file()) != modules_->end(); } bool SourceLineResolverBase::IsModuleCorrupt(const CodeModule* module) { if (!module) return false; return corrupt_modules_->find(module->code_file()) != corrupt_modules_->end(); } void SourceLineResolverBase::FillSourceLineInfo(StackFrame* frame) { if (frame->module) { ModuleMap::const_iterator it = modules_->find(frame->module->code_file()); if (it != modules_->end()) { it->second->LookupAddress(frame); } } } WindowsFrameInfo* SourceLineResolverBase::FindWindowsFrameInfo( const StackFrame* frame) { if (frame->module) { ModuleMap::const_iterator it = modules_->find(frame->module->code_file()); if (it != modules_->end()) { return it->second->FindWindowsFrameInfo(frame); } } return NULL; } CFIFrameInfo* SourceLineResolverBase::FindCFIFrameInfo( const StackFrame* frame) { if (frame->module) { ModuleMap::const_iterator it = modules_->find(frame->module->code_file()); if (it != modules_->end()) { return it->second->FindCFIFrameInfo(frame); } } return NULL; } bool SourceLineResolverBase::CompareString::operator()( const string& s1, const string& s2) const { return strcmp(s1.c_str(), s2.c_str()) < 0; } bool SourceLineResolverBase::Module::ParseCFIRuleSet( const string& rule_set, CFIFrameInfo* frame_info) const { CFIFrameInfoParseHandler handler(frame_info); CFIRuleParser parser(&handler); return parser.Parse(rule_set); } } // namespace google_breakpad