/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "thread_tree.h" #include #include #include #include #include "perf_event.h" #include "record.h" namespace simpleperf { bool MapComparator::operator()(const MapEntry* map1, const MapEntry* map2) const { if (map1->start_addr != map2->start_addr) { return map1->start_addr < map2->start_addr; } // Compare map->len instead of map->get_end_addr() here. Because we set map's // len to std::numeric_limits::max() in FindMapByAddr(), which makes // map->get_end_addr() overflow. if (map1->len != map2->len) { return map1->len < map2->len; } if (map1->time != map2->time) { return map1->time < map2->time; } return false; } void ThreadTree::SetThreadName(int pid, int tid, const std::string& comm) { ThreadEntry* thread = FindThreadOrNew(pid, tid); if (comm != thread->comm) { thread_comm_storage_.push_back( std::unique_ptr(new std::string(comm))); thread->comm = thread_comm_storage_.back()->c_str(); } } void ThreadTree::ForkThread(int pid, int tid, int ppid, int ptid) { ThreadEntry* parent = FindThreadOrNew(ppid, ptid); ThreadEntry* child = FindThreadOrNew(pid, tid); child->comm = parent->comm; if (pid != ppid) { // Copy maps from parent process. *child->maps = *parent->maps; } } ThreadEntry* ThreadTree::FindThreadOrNew(int pid, int tid) { auto it = thread_tree_.find(tid); if (it == thread_tree_.end()) { return CreateThread(pid, tid); } else { if (pid != it->second.get()->pid) { // TODO: b/22185053. LOG(DEBUG) << "unexpected (pid, tid) pair: expected (" << it->second.get()->pid << ", " << tid << "), actual (" << pid << ", " << tid << ")"; } } return it->second.get(); } ThreadEntry* ThreadTree::CreateThread(int pid, int tid) { MapSet* maps = nullptr; if (pid == tid) { maps = new MapSet; map_set_storage_.push_back(std::unique_ptr(maps)); } else { // Share maps among threads in the same thread group. ThreadEntry* process = FindThreadOrNew(pid, pid); maps = process->maps; } ThreadEntry* thread = new ThreadEntry{ pid, tid, "unknown", maps, }; auto pair = thread_tree_.insert(std::make_pair(tid, std::unique_ptr(thread))); CHECK(pair.second); return thread; } void ThreadTree::AddKernelMap(uint64_t start_addr, uint64_t len, uint64_t pgoff, uint64_t time, const std::string& filename) { // kernel map len can be 0 when record command is not run in supervisor mode. if (len == 0) { return; } Dso* dso = FindKernelDsoOrNew(filename); MapEntry* map = AllocateMap(MapEntry(start_addr, len, pgoff, time, dso, true)); FixOverlappedMap(&kernel_maps_, map); auto pair = kernel_maps_.insert(map); CHECK(pair.second); } Dso* ThreadTree::FindKernelDsoOrNew(const std::string& filename) { if (filename == DEFAULT_KERNEL_MMAP_NAME || filename == DEFAULT_KERNEL_MMAP_NAME_PERF) { return kernel_dso_.get(); } auto it = module_dso_tree_.find(filename); if (it == module_dso_tree_.end()) { module_dso_tree_[filename] = Dso::CreateDso(DSO_KERNEL_MODULE, filename); it = module_dso_tree_.find(filename); } return it->second.get(); } void ThreadTree::AddThreadMap(int pid, int tid, uint64_t start_addr, uint64_t len, uint64_t pgoff, uint64_t time, const std::string& filename) { ThreadEntry* thread = FindThreadOrNew(pid, tid); Dso* dso = FindUserDsoOrNew(filename, start_addr); MapEntry* map = AllocateMap(MapEntry(start_addr, len, pgoff, time, dso, false)); FixOverlappedMap(thread->maps, map); auto pair = thread->maps->insert(map); CHECK(pair.second); } Dso* ThreadTree::FindUserDsoOrNew(const std::string& filename, uint64_t start_addr) { auto it = user_dso_tree_.find(filename); if (it == user_dso_tree_.end()) { bool force_64bit = start_addr > UINT_MAX; user_dso_tree_[filename] = Dso::CreateDso(DSO_ELF_FILE, filename, force_64bit); it = user_dso_tree_.find(filename); } return it->second.get(); } MapEntry* ThreadTree::AllocateMap(const MapEntry& value) { MapEntry* map = new MapEntry(value); map_storage_.push_back(std::unique_ptr(map)); return map; } void ThreadTree::FixOverlappedMap(MapSet* maps, const MapEntry* map) { for (auto it = maps->begin(); it != maps->end();) { if ((*it)->start_addr >= map->get_end_addr()) { // No more overlapped maps. break; } if ((*it)->get_end_addr() <= map->start_addr) { ++it; } else { MapEntry* old = *it; if (old->start_addr < map->start_addr) { MapEntry* before = AllocateMap( MapEntry(old->start_addr, map->start_addr - old->start_addr, old->pgoff, old->time, old->dso, old->in_kernel)); maps->insert(before); } if (old->get_end_addr() > map->get_end_addr()) { MapEntry* after = AllocateMap(MapEntry( map->get_end_addr(), old->get_end_addr() - map->get_end_addr(), map->get_end_addr() - old->start_addr + old->pgoff, old->time, old->dso, old->in_kernel)); maps->insert(after); } it = maps->erase(it); } } } static bool IsAddrInMap(uint64_t addr, const MapEntry* map) { return (addr >= map->start_addr && addr < map->get_end_addr()); } static MapEntry* FindMapByAddr(const MapSet& maps, uint64_t addr) { // Construct a map_entry which is strictly after the searched map_entry, based // on MapComparator. MapEntry find_map(addr, std::numeric_limits::max(), 0, std::numeric_limits::max(), nullptr, false); auto it = maps.upper_bound(&find_map); if (it != maps.begin() && IsAddrInMap(addr, *--it)) { return *it; } return nullptr; } const MapEntry* ThreadTree::FindMap(const ThreadEntry* thread, uint64_t ip, bool in_kernel) { MapEntry* result = nullptr; if (!in_kernel) { result = FindMapByAddr(*thread->maps, ip); } else { result = FindMapByAddr(kernel_maps_, ip); } return result != nullptr ? result : &unknown_map_; } const MapEntry* ThreadTree::FindMap(const ThreadEntry* thread, uint64_t ip) { MapEntry* result = FindMapByAddr(*thread->maps, ip); if (result != nullptr) { return result; } result = FindMapByAddr(kernel_maps_, ip); return result != nullptr ? result : &unknown_map_; } const Symbol* ThreadTree::FindSymbol(const MapEntry* map, uint64_t ip, uint64_t* pvaddr_in_file, Dso** pdso) { uint64_t vaddr_in_file; Dso* dso = map->dso; vaddr_in_file = ip - map->start_addr + map->dso->MinVirtualAddress(); const Symbol* symbol = dso->FindSymbol(vaddr_in_file); if (symbol == nullptr && map->in_kernel && dso != kernel_dso_.get()) { // It is in a kernel module, but we can't find the kernel module file, or // the kernel module file contains no symbol. Try finding the symbol in // /proc/kallsyms. vaddr_in_file = ip; dso = kernel_dso_.get(); symbol = dso->FindSymbol(vaddr_in_file); } if (symbol == nullptr) { if (show_ip_for_unknown_symbol_) { std::string name = android::base::StringPrintf( "%s%s[+%" PRIx64 "]", (show_mark_for_unknown_symbol_ ? "*" : ""), dso->FileName().c_str(), vaddr_in_file); dso->AddUnknownSymbol(vaddr_in_file, name); symbol = dso->FindSymbol(vaddr_in_file); CHECK(symbol != nullptr); } else { symbol = &unknown_symbol_; } } if (pvaddr_in_file != nullptr) { *pvaddr_in_file = vaddr_in_file; } if (pdso != nullptr) { *pdso = dso; } return symbol; } const Symbol* ThreadTree::FindKernelSymbol(uint64_t ip) { const MapEntry* map = FindMap(nullptr, ip, true); return FindSymbol(map, ip, nullptr); } void ThreadTree::ClearThreadAndMap() { thread_tree_.clear(); thread_comm_storage_.clear(); map_set_storage_.clear(); kernel_maps_.clear(); map_storage_.clear(); } void ThreadTree::AddDsoInfo(const std::string& file_path, uint32_t file_type, uint64_t min_vaddr, std::vector* symbols) { DsoType dso_type = static_cast(file_type); Dso* dso = nullptr; if (dso_type == DSO_KERNEL || dso_type == DSO_KERNEL_MODULE) { dso = FindKernelDsoOrNew(file_path); } else { dso = FindUserDsoOrNew(file_path); } dso->SetMinVirtualAddress(min_vaddr); dso->SetSymbols(symbols); } void ThreadTree::Update(const Record& record) { if (record.type() == PERF_RECORD_MMAP) { const MmapRecord& r = *static_cast(&record); if (r.InKernel()) { AddKernelMap(r.data->addr, r.data->len, r.data->pgoff, r.sample_id.time_data.time, r.filename); } else { AddThreadMap(r.data->pid, r.data->tid, r.data->addr, r.data->len, r.data->pgoff, r.sample_id.time_data.time, r.filename); } } else if (record.type() == PERF_RECORD_MMAP2) { const Mmap2Record& r = *static_cast(&record); if (r.InKernel()) { AddKernelMap(r.data->addr, r.data->len, r.data->pgoff, r.sample_id.time_data.time, r.filename); } else { std::string filename = (r.filename == DEFAULT_EXECNAME_FOR_THREAD_MMAP) ? "[unknown]" : r.filename; AddThreadMap(r.data->pid, r.data->tid, r.data->addr, r.data->len, r.data->pgoff, r.sample_id.time_data.time, filename); } } else if (record.type() == PERF_RECORD_COMM) { const CommRecord& r = *static_cast(&record); SetThreadName(r.data->pid, r.data->tid, r.comm); } else if (record.type() == PERF_RECORD_FORK) { const ForkRecord& r = *static_cast(&record); ForkThread(r.data->pid, r.data->tid, r.data->ppid, r.data->ptid); } else if (record.type() == SIMPLE_PERF_RECORD_KERNEL_SYMBOL) { const auto& r = *static_cast(&record); Dso::SetKallsyms(std::move(r.kallsyms)); } } std::vector ThreadTree::GetAllDsos() const { std::vector result; result.push_back(kernel_dso_.get()); for (auto& p : module_dso_tree_) { result.push_back(p.second.get()); } for (auto& p : user_dso_tree_) { result.push_back(p.second.get()); } result.push_back(unknown_dso_.get()); return result; } } // namespace simpleperf