/*
* 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 <limits>
#include <android-base/logging.h>
#include "environment.h"
#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<uint64_t>::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::AddThread(int pid, int tid, const std::string& comm) {
auto it = thread_tree_.find(tid);
if (it == thread_tree_.end()) {
ThreadEntry* thread = new ThreadEntry{
pid, tid,
"unknown", // comm
std::set<MapEntry*, MapComparator>(), // maps
};
auto pair = thread_tree_.insert(std::make_pair(tid, std::unique_ptr<ThreadEntry>(thread)));
CHECK(pair.second);
it = pair.first;
}
thread_comm_storage_.push_back(std::unique_ptr<std::string>(new std::string(comm)));
it->second->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;
child->maps = parent->maps;
}
ThreadEntry* ThreadTree::FindThreadOrNew(int pid, int tid) {
auto it = thread_tree_.find(tid);
if (it == thread_tree_.end()) {
AddThread(pid, tid, "unknown");
it = thread_tree_.find(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();
}
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));
FixOverlappedMap(&kernel_map_tree_, map);
auto pair = kernel_map_tree_.insert(map);
CHECK(pair.second);
}
Dso* ThreadTree::FindKernelDsoOrNew(const std::string& filename) {
if (filename == DEFAULT_KERNEL_MMAP_NAME) {
if (kernel_dso_ == nullptr) {
kernel_dso_ = Dso::CreateDso(DSO_KERNEL);
}
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);
MapEntry* map = AllocateMap(MapEntry(start_addr, len, pgoff, time, dso));
FixOverlappedMap(&thread->maps, map);
auto pair = thread->maps.insert(map);
CHECK(pair.second);
}
Dso* ThreadTree::FindUserDsoOrNew(const std::string& filename) {
auto it = user_dso_tree_.find(filename);
if (it == user_dso_tree_.end()) {
user_dso_tree_[filename] = Dso::CreateDso(DSO_ELF_FILE, filename);
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<MapEntry>(map));
return map;
}
void ThreadTree::FixOverlappedMap(std::set<MapEntry*, MapComparator>* map_set, const MapEntry* map) {
for (auto it = map_set->begin(); it != map_set->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));
map_set->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));
map_set->insert(after);
}
it = map_set->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 std::set<MapEntry*, MapComparator>& 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<uint64_t>::max(), 0,
std::numeric_limits<uint64_t>::max(), nullptr);
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_map_tree_, ip);
}
return result != nullptr ? result : &unknown_map_;
}
const Symbol* ThreadTree::FindSymbol(const MapEntry* map, uint64_t ip) {
uint64_t vaddr_in_file;
if (map->dso == kernel_dso_.get()) {
vaddr_in_file = ip;
} else {
vaddr_in_file = ip - map->start_addr + map->dso->MinVirtualAddress();
}
const Symbol* symbol = map->dso->FindSymbol(vaddr_in_file);
if (symbol == nullptr) {
symbol = &unknown_symbol_;
}
return symbol;
}
void ThreadTree::Clear() {
thread_tree_.clear();
thread_comm_storage_.clear();
kernel_map_tree_.clear();
map_storage_.clear();
kernel_dso_.reset();
module_dso_tree_.clear();
user_dso_tree_.clear();
}
} // namespace simpleperf
void BuildThreadTree(const Record& record, ThreadTree* thread_tree) {
if (record.header.type == PERF_RECORD_MMAP) {
const MmapRecord& r = *static_cast<const MmapRecord*>(&record);
if ((r.header.misc & PERF_RECORD_MISC_CPUMODE_MASK) == PERF_RECORD_MISC_KERNEL) {
thread_tree->AddKernelMap(r.data.addr, r.data.len, r.data.pgoff, r.sample_id.time_data.time,
r.filename);
} else {
thread_tree->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.header.type == PERF_RECORD_MMAP2) {
const Mmap2Record& r = *static_cast<const Mmap2Record*>(&record);
if ((r.header.misc & PERF_RECORD_MISC_CPUMODE_MASK) == PERF_RECORD_MISC_KERNEL) {
thread_tree->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;
thread_tree->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.header.type == PERF_RECORD_COMM) {
const CommRecord& r = *static_cast<const CommRecord*>(&record);
thread_tree->AddThread(r.data.pid, r.data.tid, r.comm);
} else if (record.header.type == PERF_RECORD_FORK) {
const ForkRecord& r = *static_cast<const ForkRecord*>(&record);
thread_tree->ForkThread(r.data.pid, r.data.tid, r.data.ppid, r.data.ptid);
}
}