/* * 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 "record.h" #include #include #include #include #include #include "dso.h" #include "OfflineUnwinder.h" #include "perf_regs.h" #include "tracing.h" #include "utils.h" using namespace simpleperf; static std::string RecordTypeToString(int record_type) { static std::unordered_map record_type_names = { {PERF_RECORD_MMAP, "mmap"}, {PERF_RECORD_LOST, "lost"}, {PERF_RECORD_COMM, "comm"}, {PERF_RECORD_EXIT, "exit"}, {PERF_RECORD_THROTTLE, "throttle"}, {PERF_RECORD_UNTHROTTLE, "unthrottle"}, {PERF_RECORD_FORK, "fork"}, {PERF_RECORD_READ, "read"}, {PERF_RECORD_SAMPLE, "sample"}, {PERF_RECORD_BUILD_ID, "build_id"}, {PERF_RECORD_MMAP2, "mmap2"}, {PERF_RECORD_AUX, "aux"}, {PERF_RECORD_TRACING_DATA, "tracing_data"}, {PERF_RECORD_AUXTRACE_INFO, "auxtrace_info"}, {PERF_RECORD_AUXTRACE, "auxtrace"}, {SIMPLE_PERF_RECORD_KERNEL_SYMBOL, "kernel_symbol"}, {SIMPLE_PERF_RECORD_DSO, "dso"}, {SIMPLE_PERF_RECORD_SYMBOL, "symbol"}, {SIMPLE_PERF_RECORD_EVENT_ID, "event_id"}, {SIMPLE_PERF_RECORD_CALLCHAIN, "callchain"}, {SIMPLE_PERF_RECORD_UNWINDING_RESULT, "unwinding_result"}, {SIMPLE_PERF_RECORD_TRACING_DATA, "tracing_data"}, }; auto it = record_type_names.find(record_type); if (it != record_type_names.end()) { return it->second; } return android::base::StringPrintf("unknown(%d)", record_type); } template <> void MoveToBinaryFormat(const RecordHeader& data, char*& p) { data.MoveToBinaryFormat(p); } SampleId::SampleId() { memset(this, 0, sizeof(SampleId)); } // Return sample_id size in binary format. size_t SampleId::CreateContent(const perf_event_attr& attr, uint64_t event_id) { sample_id_all = attr.sample_id_all; sample_type = attr.sample_type; id_data.id = event_id; // Other data are not necessary. TODO: Set missing SampleId data. return Size(); } void SampleId::ReadFromBinaryFormat(const perf_event_attr& attr, const char* p, const char* end) { sample_id_all = attr.sample_id_all; sample_type = attr.sample_type; if (sample_id_all) { if (sample_type & PERF_SAMPLE_TID) { MoveFromBinaryFormat(tid_data, p); } if (sample_type & PERF_SAMPLE_TIME) { MoveFromBinaryFormat(time_data, p); } if (sample_type & PERF_SAMPLE_ID) { MoveFromBinaryFormat(id_data, p); } if (sample_type & PERF_SAMPLE_STREAM_ID) { MoveFromBinaryFormat(stream_id_data, p); } if (sample_type & PERF_SAMPLE_CPU) { MoveFromBinaryFormat(cpu_data, p); } if (sample_type & PERF_SAMPLE_IDENTIFIER) { MoveFromBinaryFormat(id_data, p); } } CHECK_LE(p, end); if (p < end) { LOG(DEBUG) << "Record SampleId part has " << end - p << " bytes left\n"; } } void SampleId::WriteToBinaryFormat(char*& p) const { if (sample_id_all) { if (sample_type & PERF_SAMPLE_TID) { MoveToBinaryFormat(tid_data, p); } if (sample_type & PERF_SAMPLE_TIME) { MoveToBinaryFormat(time_data, p); } if (sample_type & PERF_SAMPLE_ID) { MoveToBinaryFormat(id_data, p); } if (sample_type & PERF_SAMPLE_STREAM_ID) { MoveToBinaryFormat(stream_id_data, p); } if (sample_type & PERF_SAMPLE_CPU) { MoveToBinaryFormat(cpu_data, p); } } } void SampleId::Dump(size_t indent) const { if (sample_id_all) { if (sample_type & PERF_SAMPLE_TID) { PrintIndented(indent, "sample_id: pid %u, tid %u\n", tid_data.pid, tid_data.tid); } if (sample_type & PERF_SAMPLE_TIME) { PrintIndented(indent, "sample_id: time %" PRId64 "\n", time_data.time); } if (sample_type & (PERF_SAMPLE_ID | PERF_SAMPLE_IDENTIFIER)) { PrintIndented(indent, "sample_id: id %" PRId64 "\n", id_data.id); } if (sample_type & PERF_SAMPLE_STREAM_ID) { PrintIndented(indent, "sample_id: stream_id %" PRId64 "\n", stream_id_data.stream_id); } if (sample_type & PERF_SAMPLE_CPU) { PrintIndented(indent, "sample_id: cpu %u, res %u\n", cpu_data.cpu, cpu_data.res); } } } size_t SampleId::Size() const { size_t size = 0; if (sample_id_all) { if (sample_type & PERF_SAMPLE_TID) { size += sizeof(PerfSampleTidType); } if (sample_type & PERF_SAMPLE_TIME) { size += sizeof(PerfSampleTimeType); } if (sample_type & PERF_SAMPLE_ID) { size += sizeof(PerfSampleIdType); } if (sample_type & PERF_SAMPLE_STREAM_ID) { size += sizeof(PerfSampleStreamIdType); } if (sample_type & PERF_SAMPLE_CPU) { size += sizeof(PerfSampleCpuType); } if (sample_type & PERF_SAMPLE_IDENTIFIER) { size += sizeof(PerfSampleIdType); } } return size; } Record::Record(Record&& other) noexcept { header = other.header; sample_id = other.sample_id; binary_ = other.binary_; own_binary_ = other.own_binary_; other.binary_ = nullptr; other.own_binary_ = false; } void Record::Dump(size_t indent) const { PrintIndented(indent, "record %s: type %u, misc %u, size %u\n", RecordTypeToString(type()).c_str(), type(), misc(), size()); DumpData(indent + 1); sample_id.Dump(indent + 1); } uint64_t Record::Timestamp() const { return sample_id.time_data.time; } uint32_t Record::Cpu() const { return sample_id.cpu_data.cpu; } uint64_t Record::Id() const { return sample_id.id_data.id; } void Record::UpdateBinary(char* new_binary) { if (own_binary_) { delete[] binary_; } own_binary_ = true; binary_ = new_binary; } MmapRecord::MmapRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); p += sizeof(*data); filename = p; p += Align(strlen(filename) + 1, 8); CHECK_LE(p, end); sample_id.ReadFromBinaryFormat(attr, p, end); } MmapRecord::MmapRecord(const perf_event_attr& attr, bool in_kernel, uint32_t pid, uint32_t tid, uint64_t addr, uint64_t len, uint64_t pgoff, const std::string& filename, uint64_t event_id, uint64_t time) { SetTypeAndMisc(PERF_RECORD_MMAP, in_kernel ? PERF_RECORD_MISC_KERNEL : PERF_RECORD_MISC_USER); sample_id.CreateContent(attr, event_id); sample_id.time_data.time = time; MmapRecordDataType data; data.pid = pid; data.tid = tid; data.addr = addr; data.len = len; data.pgoff = pgoff; SetDataAndFilename(data, filename); } void MmapRecord::SetDataAndFilename(const MmapRecordDataType& data, const std::string& filename) { SetSize(header_size() + sizeof(data) + Align(filename.size() + 1, 8) + sample_id.Size()); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); this->data = reinterpret_cast(p); MoveToBinaryFormat(data, p); this->filename = p; strcpy(p, filename.c_str()); p += Align(filename.size() + 1, 8); sample_id.WriteToBinaryFormat(p); UpdateBinary(new_binary); } void MmapRecord::DumpData(size_t indent) const { PrintIndented(indent, "pid %u, tid %u, addr 0x%" PRIx64 ", len 0x%" PRIx64 "\n", data->pid, data->tid, data->addr, data->len); PrintIndented(indent, "pgoff 0x%" PRIx64 ", filename %s\n", data->pgoff, filename); } Mmap2Record::Mmap2Record(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); p += sizeof(*data); filename = p; p += Align(strlen(filename) + 1, 8); CHECK_LE(p, end); sample_id.ReadFromBinaryFormat(attr, p, end); } Mmap2Record::Mmap2Record(const perf_event_attr& attr, bool in_kernel, uint32_t pid, uint32_t tid, uint64_t addr, uint64_t len, uint64_t pgoff, uint32_t prot, const std::string& filename, uint64_t event_id, uint64_t time) { SetTypeAndMisc(PERF_RECORD_MMAP2, in_kernel ? PERF_RECORD_MISC_KERNEL : PERF_RECORD_MISC_USER); sample_id.CreateContent(attr, event_id); sample_id.time_data.time = time; Mmap2RecordDataType data; data.pid = pid; data.tid = tid; data.addr = addr; data.len = len; data.pgoff = pgoff; data.prot = prot; SetDataAndFilename(data, filename); } void Mmap2Record::SetDataAndFilename(const Mmap2RecordDataType& data, const std::string& filename) { SetSize(header_size() + sizeof(data) + Align(filename.size() + 1, 8) + sample_id.Size()); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); this->data = reinterpret_cast(p); MoveToBinaryFormat(data, p); this->filename = p; strcpy(p, filename.c_str()); p += Align(filename.size() + 1, 8); sample_id.WriteToBinaryFormat(p); UpdateBinary(new_binary); } void Mmap2Record::DumpData(size_t indent) const { PrintIndented(indent, "pid %u, tid %u, addr 0x%" PRIx64 ", len 0x%" PRIx64 "\n", data->pid, data->tid, data->addr, data->len); PrintIndented(indent, "pgoff 0x%" PRIx64 ", maj %u, min %u, ino %" PRId64 ", ino_generation %" PRIu64 "\n", data->pgoff, data->maj, data->min, data->ino, data->ino_generation); PrintIndented(indent, "prot %u, flags %u, filename %s\n", data->prot, data->flags, filename); } CommRecord::CommRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); p += sizeof(*data); comm = p; p += Align(strlen(p) + 1, 8); CHECK_LE(p, end); sample_id.ReadFromBinaryFormat(attr, p, end); } CommRecord::CommRecord(const perf_event_attr& attr, uint32_t pid, uint32_t tid, const std::string& comm, uint64_t event_id, uint64_t time) { SetTypeAndMisc(PERF_RECORD_COMM, 0); CommRecordDataType data; data.pid = pid; data.tid = tid; size_t sample_id_size = sample_id.CreateContent(attr, event_id); sample_id.time_data.time = time; SetSize(header_size() + sizeof(data) + Align(comm.size() + 1, 8) + sample_id_size); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); this->data = reinterpret_cast(p); MoveToBinaryFormat(data, p); this->comm = p; strcpy(p, comm.c_str()); p += Align(comm.size() + 1, 8); sample_id.WriteToBinaryFormat(p); UpdateBinary(new_binary); } void CommRecord::SetCommandName(const std::string& name) { if (name.compare(comm) == 0) { return; } // The kernel uses a 8-byte aligned space to store command name. Follow it here to allow the same // reading code. size_t old_name_len = Align(strlen(comm) + 1, 8); size_t new_name_len = Align(name.size() + 1, 8); size_t new_size = size() - old_name_len + new_name_len; char* new_binary = new char[new_size]; char* p = new_binary; header.size = new_size; MoveToBinaryFormat(header, p); MoveToBinaryFormat(*data, p); data = reinterpret_cast(p - sizeof(CommRecordDataType)); comm = p; strcpy(p, name.c_str()); p += new_name_len; sample_id.WriteToBinaryFormat(p); CHECK_EQ(p, new_binary + new_size); UpdateBinary(new_binary); } void CommRecord::DumpData(size_t indent) const { PrintIndented(indent, "pid %u, tid %u, comm %s\n", data->pid, data->tid, comm); } ExitOrForkRecord::ExitOrForkRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); p += sizeof(*data); CHECK_LE(p, end); sample_id.ReadFromBinaryFormat(attr, p, end); } void ExitOrForkRecord::DumpData(size_t indent) const { PrintIndented(indent, "pid %u, ppid %u, tid %u, ptid %u\n", data->pid, data->ppid, data->tid, data->ptid); } ForkRecord::ForkRecord(const perf_event_attr& attr, uint32_t pid, uint32_t tid, uint32_t ppid, uint32_t ptid, uint64_t event_id) { SetTypeAndMisc(PERF_RECORD_FORK, 0); ExitOrForkRecordDataType data; data.pid = pid; data.ppid = ppid; data.tid = tid; data.ptid = ptid; data.time = 0; size_t sample_id_size = sample_id.CreateContent(attr, event_id); SetSize(header_size() + sizeof(data) + sample_id_size); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); this->data = reinterpret_cast(p); MoveToBinaryFormat(data, p); sample_id.WriteToBinaryFormat(p); UpdateBinary(new_binary); } LostRecord::LostRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(id, p); MoveFromBinaryFormat(lost, p); CHECK_LE(p, end); sample_id.ReadFromBinaryFormat(attr, p, end); } void LostRecord::DumpData(size_t indent) const { PrintIndented(indent, "id %" PRIu64 ", lost %" PRIu64 "\n", id, lost); } SampleRecord::SampleRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); sample_type = attr.sample_type; // Set a default id value to report correctly even if ID is not recorded. id_data.id = 0; if (sample_type & PERF_SAMPLE_IDENTIFIER) { MoveFromBinaryFormat(id_data, p); } if (sample_type & PERF_SAMPLE_IP) { MoveFromBinaryFormat(ip_data, p); } if (sample_type & PERF_SAMPLE_TID) { MoveFromBinaryFormat(tid_data, p); } if (sample_type & PERF_SAMPLE_TIME) { MoveFromBinaryFormat(time_data, p); } if (sample_type & PERF_SAMPLE_ADDR) { MoveFromBinaryFormat(addr_data, p); } if (sample_type & PERF_SAMPLE_ID) { MoveFromBinaryFormat(id_data, p); } if (sample_type & PERF_SAMPLE_STREAM_ID) { MoveFromBinaryFormat(stream_id_data, p); } if (sample_type & PERF_SAMPLE_CPU) { MoveFromBinaryFormat(cpu_data, p); } if (sample_type & PERF_SAMPLE_PERIOD) { MoveFromBinaryFormat(period_data, p); } if (sample_type & PERF_SAMPLE_CALLCHAIN) { MoveFromBinaryFormat(callchain_data.ip_nr, p); callchain_data.ips = reinterpret_cast(p); p += callchain_data.ip_nr * sizeof(uint64_t); } if (sample_type & PERF_SAMPLE_RAW) { MoveFromBinaryFormat(raw_data.size, p); raw_data.data = p; p += raw_data.size; } if (sample_type & PERF_SAMPLE_BRANCH_STACK) { MoveFromBinaryFormat(branch_stack_data.stack_nr, p); branch_stack_data.stack = reinterpret_cast(p); p += branch_stack_data.stack_nr * sizeof(BranchStackItemType); } if (sample_type & PERF_SAMPLE_REGS_USER) { MoveFromBinaryFormat(regs_user_data.abi, p); if (regs_user_data.abi == 0) { regs_user_data.reg_mask = 0; } else { regs_user_data.reg_mask = attr.sample_regs_user; size_t bit_nr = __builtin_popcountll(regs_user_data.reg_mask); regs_user_data.reg_nr = bit_nr; regs_user_data.regs = reinterpret_cast(p); p += bit_nr * sizeof(uint64_t); } } if (sample_type & PERF_SAMPLE_STACK_USER) { MoveFromBinaryFormat(stack_user_data.size, p); if (stack_user_data.size == 0) { stack_user_data.dyn_size = 0; } else { stack_user_data.data = p; p += stack_user_data.size; MoveFromBinaryFormat(stack_user_data.dyn_size, p); } } // TODO: Add parsing of other PERF_SAMPLE_*. CHECK_LE(p, end); if (p < end) { LOG(DEBUG) << "Record has " << end - p << " bytes left\n"; } } SampleRecord::SampleRecord(const perf_event_attr& attr, uint64_t id, uint64_t ip, uint32_t pid, uint32_t tid, uint64_t time, uint32_t cpu, uint64_t period, const std::vector& ips, const std::vector& stack, uint64_t dyn_stack_size) { SetTypeAndMisc(PERF_RECORD_SAMPLE, PERF_RECORD_MISC_USER); sample_type = attr.sample_type; CHECK_EQ(0u, sample_type & ~(PERF_SAMPLE_IP | PERF_SAMPLE_TID | PERF_SAMPLE_TIME | PERF_SAMPLE_ID | PERF_SAMPLE_CPU | PERF_SAMPLE_PERIOD | PERF_SAMPLE_CALLCHAIN | PERF_SAMPLE_REGS_USER | PERF_SAMPLE_STACK_USER)); ip_data.ip = ip; tid_data.pid = pid; tid_data.tid = tid; time_data.time = time; id_data.id = id; cpu_data.cpu = cpu; cpu_data.res = 0; period_data.period = period; callchain_data.ip_nr = ips.size(); raw_data.size = 0; branch_stack_data.stack_nr = 0; regs_user_data.abi = 0; regs_user_data.reg_mask = 0; regs_user_data.reg_nr = 0; stack_user_data.size = stack.size(); stack_user_data.dyn_size = dyn_stack_size; uint32_t size = header_size(); if (sample_type & PERF_SAMPLE_IP) { size += sizeof(ip_data); } if (sample_type & PERF_SAMPLE_TID) { size += sizeof(tid_data); } if (sample_type & PERF_SAMPLE_TIME) { size += sizeof(time_data); } if (sample_type & PERF_SAMPLE_ID) { size += sizeof(id_data); } if (sample_type & PERF_SAMPLE_CPU) { size += sizeof(cpu_data); } if (sample_type & PERF_SAMPLE_PERIOD) { size += sizeof(period_data); } if (sample_type & PERF_SAMPLE_CALLCHAIN) { size += sizeof(uint64_t) * (ips.size() + 1); } if (sample_type & PERF_SAMPLE_REGS_USER) { size += sizeof(uint64_t); } if (sample_type & PERF_SAMPLE_STACK_USER) { size += sizeof(uint64_t) + (stack.empty() ? 0 : stack.size() + sizeof(uint64_t)); } SetSize(size); char* new_binary = new char[size]; char* p = new_binary; MoveToBinaryFormat(header, p); if (sample_type & PERF_SAMPLE_IP) { MoveToBinaryFormat(ip_data, p); } if (sample_type & PERF_SAMPLE_TID) { MoveToBinaryFormat(tid_data, p); } if (sample_type & PERF_SAMPLE_TIME) { MoveToBinaryFormat(time_data, p); } if (sample_type & PERF_SAMPLE_ID) { MoveToBinaryFormat(id_data, p); } if (sample_type & PERF_SAMPLE_CPU) { MoveToBinaryFormat(cpu_data, p); } if (sample_type & PERF_SAMPLE_PERIOD) { MoveToBinaryFormat(period_data, p); } if (sample_type & PERF_SAMPLE_CALLCHAIN) { MoveToBinaryFormat(callchain_data.ip_nr, p); callchain_data.ips = reinterpret_cast(p); MoveToBinaryFormat(ips.data(), ips.size(), p); } if (sample_type & PERF_SAMPLE_REGS_USER) { MoveToBinaryFormat(regs_user_data.abi, p); } if (sample_type & PERF_SAMPLE_STACK_USER) { MoveToBinaryFormat(stack_user_data.size, p); if (stack_user_data.size > 0) { stack_user_data.data = p; MoveToBinaryFormat(stack.data(), stack_user_data.size, p); MoveToBinaryFormat(stack_user_data.dyn_size, p); } } CHECK_EQ(p, new_binary + size); UpdateBinary(new_binary); } void SampleRecord::ReplaceRegAndStackWithCallChain(const std::vector& ips) { uint32_t size_added_in_callchain = sizeof(uint64_t) * (ips.size() + 1); uint32_t size_reduced_in_reg_stack = regs_user_data.reg_nr * sizeof(uint64_t) + stack_user_data.size + sizeof(uint64_t); uint32_t new_size = size() + size_added_in_callchain - size_reduced_in_reg_stack; BuildBinaryWithNewCallChain(new_size, ips); } bool SampleRecord::ExcludeKernelCallChain() { if (!(sample_type & PERF_SAMPLE_CALLCHAIN)) { return true; } size_t i; for (i = 0; i < callchain_data.ip_nr; ++i) { if (callchain_data.ips[i] == PERF_CONTEXT_USER) { break; } // Erase kernel callchain. callchain_data.ips[i] = PERF_CONTEXT_USER; } while (++i < callchain_data.ip_nr) { if (callchain_data.ips[i] < PERF_CONTEXT_MAX) { // Change the sample to make it hit the user space ip address. ip_data.ip = callchain_data.ips[i]; if (sample_type & PERF_SAMPLE_IP) { *reinterpret_cast(binary_ + header_size()) = ip_data.ip; } header.misc = (header.misc & ~PERF_RECORD_MISC_CPUMODE_MASK) | PERF_RECORD_MISC_USER; reinterpret_cast(binary_)->misc = header.misc; return true; } } return false; } bool SampleRecord::HasUserCallChain() const { if ((sample_type & PERF_SAMPLE_CALLCHAIN) == 0) { return false; } bool in_user_context = !InKernel(); for (size_t i = 0; i < callchain_data.ip_nr; ++i) { if (in_user_context && callchain_data.ips[i] < PERF_CONTEXT_MAX) { return true; } if (callchain_data.ips[i] == PERF_CONTEXT_USER) { in_user_context = true; } } return false; } void SampleRecord::UpdateUserCallChain(const std::vector& user_ips) { size_t kernel_ip_count = 0; for (size_t i = 0; i < callchain_data.ip_nr; ++i) { if (callchain_data.ips[i] == PERF_CONTEXT_USER) { break; } kernel_ip_count++; } if (kernel_ip_count + 1 + user_ips.size() <= callchain_data.ip_nr) { // Callchain isn't changed. return; } size_t new_size = size() + (kernel_ip_count + 1 + user_ips.size() - callchain_data.ip_nr) * sizeof(uint64_t); callchain_data.ip_nr = kernel_ip_count; BuildBinaryWithNewCallChain(new_size, user_ips); } void SampleRecord::BuildBinaryWithNewCallChain(uint32_t new_size, const std::vector& ips) { size_t callchain_pos = reinterpret_cast(callchain_data.ips) - binary_ - sizeof(uint64_t); char* new_binary = binary_; if (new_size > size()) { new_binary = new char[new_size]; memcpy(new_binary, binary_, callchain_pos); } char* p = new_binary; SetSize(new_size); MoveToBinaryFormat(header, p); p = new_binary + new_size; if (sample_type & PERF_SAMPLE_STACK_USER) { stack_user_data.size = 0; p -= sizeof(uint64_t); memcpy(p, &stack_user_data.size, sizeof(uint64_t)); } if (sample_type & PERF_SAMPLE_REGS_USER) { regs_user_data.abi = 0; p -= sizeof(uint64_t); memcpy(p, ®s_user_data.abi, sizeof(uint64_t)); } if (sample_type & PERF_SAMPLE_BRANCH_STACK) { p -= branch_stack_data.stack_nr * sizeof(BranchStackItemType); memcpy(p, branch_stack_data.stack, branch_stack_data.stack_nr * sizeof(BranchStackItemType)); branch_stack_data.stack = reinterpret_cast(p); p -= sizeof(uint64_t); memcpy(p, &branch_stack_data.stack_nr, sizeof(uint64_t)); } if (sample_type & PERF_SAMPLE_RAW) { p -= raw_data.size; memcpy(p, raw_data.data, raw_data.size); raw_data.data = p; p -= sizeof(uint32_t); memcpy(p, &raw_data.size, sizeof(uint32_t)); } uint64_t* p64 = reinterpret_cast(p); p64 -= ips.size(); memcpy(p64, ips.data(), ips.size() * sizeof(uint64_t)); *--p64 = PERF_CONTEXT_USER; if (callchain_data.ip_nr > 0) { p64 -= callchain_data.ip_nr; memcpy(p64, callchain_data.ips, callchain_data.ip_nr * sizeof(uint64_t)); } callchain_data.ips = p64; callchain_data.ip_nr += 1 + ips.size(); *--p64 = callchain_data.ip_nr; CHECK_EQ(callchain_pos, static_cast(reinterpret_cast(p64) - new_binary)) << "record time " << time_data.time; if (new_binary != binary_) { UpdateBinary(new_binary); } } void SampleRecord::DumpData(size_t indent) const { PrintIndented(indent, "sample_type: 0x%" PRIx64 "\n", sample_type); if (sample_type & PERF_SAMPLE_IP) { PrintIndented(indent, "ip %p\n", reinterpret_cast(ip_data.ip)); } if (sample_type & PERF_SAMPLE_TID) { PrintIndented(indent, "pid %u, tid %u\n", tid_data.pid, tid_data.tid); } if (sample_type & PERF_SAMPLE_TIME) { PrintIndented(indent, "time %" PRId64 "\n", time_data.time); } if (sample_type & PERF_SAMPLE_ADDR) { PrintIndented(indent, "addr %p\n", reinterpret_cast(addr_data.addr)); } if (sample_type & (PERF_SAMPLE_ID | PERF_SAMPLE_IDENTIFIER)) { PrintIndented(indent, "id %" PRId64 "\n", id_data.id); } if (sample_type & PERF_SAMPLE_STREAM_ID) { PrintIndented(indent, "stream_id %" PRId64 "\n", stream_id_data.stream_id); } if (sample_type & PERF_SAMPLE_CPU) { PrintIndented(indent, "cpu %u, res %u\n", cpu_data.cpu, cpu_data.res); } if (sample_type & PERF_SAMPLE_PERIOD) { PrintIndented(indent, "period %" PRId64 "\n", period_data.period); } if (sample_type & PERF_SAMPLE_CALLCHAIN) { PrintIndented(indent, "callchain nr=%" PRIu64 "\n", callchain_data.ip_nr); for (uint64_t i = 0; i < callchain_data.ip_nr; ++i) { PrintIndented(indent + 1, "0x%" PRIx64 "\n", callchain_data.ips[i]); } } if (sample_type & PERF_SAMPLE_RAW) { PrintIndented(indent, "raw size=%zu\n", raw_data.size); const uint32_t* data = reinterpret_cast(raw_data.data); size_t size = raw_data.size / sizeof(uint32_t); for (size_t i = 0; i < size; ++i) { PrintIndented(indent + 1, "0x%08x (%zu)\n", data[i], data[i]); } } if (sample_type & PERF_SAMPLE_BRANCH_STACK) { PrintIndented(indent, "branch_stack nr=%" PRIu64 "\n", branch_stack_data.stack_nr); for (uint64_t i = 0; i < branch_stack_data.stack_nr; ++i) { auto& item = branch_stack_data.stack[i]; PrintIndented(indent + 1, "from 0x%" PRIx64 ", to 0x%" PRIx64 ", flags 0x%" PRIx64 "\n", item.from, item.to, item.flags); } } if (sample_type & PERF_SAMPLE_REGS_USER) { PrintIndented(indent, "user regs: abi=%" PRId64 "\n", regs_user_data.abi); for (size_t i = 0, pos = 0; i < 64; ++i) { if ((regs_user_data.reg_mask >> i) & 1) { PrintIndented( indent + 1, "reg (%s) 0x%016" PRIx64 "\n", GetRegName(i, ScopedCurrentArch::GetCurrentArch()).c_str(), regs_user_data.regs[pos++]); } } } if (sample_type & PERF_SAMPLE_STACK_USER) { PrintIndented(indent, "user stack: size %zu dyn_size %" PRIu64 "\n", stack_user_data.size, stack_user_data.dyn_size); const uint64_t* p = reinterpret_cast(stack_user_data.data); const uint64_t* end = p + (stack_user_data.size / sizeof(uint64_t)); while (p < end) { PrintIndented(indent + 1, ""); for (size_t i = 0; i < 4 && p < end; ++i, ++p) { printf(" %016" PRIx64, *p); } printf("\n"); } printf("\n"); } } uint64_t SampleRecord::Timestamp() const { return time_data.time; } uint32_t SampleRecord::Cpu() const { return cpu_data.cpu; } uint64_t SampleRecord::Id() const { return id_data.id; } void SampleRecord::AdjustCallChainGeneratedByKernel() { // The kernel stores return addrs in the callchain, but we want the addrs of call instructions // along the callchain. uint64_t* ips = callchain_data.ips; uint64_t context = header.misc == PERF_RECORD_MISC_KERNEL ? PERF_CONTEXT_KERNEL : PERF_CONTEXT_USER; bool first_frame = true; for (size_t i = 0; i < callchain_data.ip_nr; ++i) { if (ips[i] < PERF_CONTEXT_MAX) { if (first_frame) { first_frame = false; } else { if (ips[i] < 2) { // A wrong ip address, erase it. ips[i] = context; } else { // Here we want to change the return addr to the addr of the previous instruction. We // don't need to find the exact start addr of the previous instruction. A location in // [start_addr_of_call_inst, start_addr_of_next_inst) is enough. #if defined(__arm__) || defined(__aarch64__) // If we are built for arm/aarch64, this may be a callchain of thumb code. For thumb code, // the real instruction addr is (ip & ~1), and ip - 2 can used to hit the address range // of the previous instruction. For non thumb code, any addr in [ip - 4, ip - 1] is fine. ips[i] -= 2; #else ips[i]--; #endif } } } else { context = ips[i]; } } } std::vector SampleRecord::GetCallChain(size_t* kernel_ip_count) const { std::vector ips; bool in_kernel = InKernel(); ips.push_back(ip_data.ip); *kernel_ip_count = in_kernel ? 1 : 0; if ((sample_type & PERF_SAMPLE_CALLCHAIN) == 0) { return ips; } bool first_ip = true; for (uint64_t i = 0; i < callchain_data.ip_nr; ++i) { uint64_t ip = callchain_data.ips[i]; if (ip >= PERF_CONTEXT_MAX) { switch (ip) { case PERF_CONTEXT_KERNEL: CHECK(in_kernel) << "User space callchain followed by kernel callchain."; break; case PERF_CONTEXT_USER: in_kernel = false; break; default: LOG(DEBUG) << "Unexpected perf_context in callchain: " << std::hex << ip << std::dec; } } else { if (first_ip) { first_ip = false; // Remove duplication with sample ip. if (ip == ip_data.ip) { continue; } } ips.push_back(ip); if (in_kernel) { ++*kernel_ip_count; } } } return ips; } AuxRecord::AuxRecord(const perf_event_attr& attr, char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); p += sizeof(DataType); sample_id.ReadFromBinaryFormat(attr, p, end); } void AuxRecord::DumpData(size_t indent) const { PrintIndented(indent, "aux_offset %" PRIu64 "\n", data->aux_offset); PrintIndented(indent, "aux_size %" PRIu64 "\n", data->aux_size); PrintIndented(indent, "flags 0x%" PRIx64 "\n", data->flags); } BuildIdRecord::BuildIdRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(pid, p); build_id = BuildId(p, BUILD_ID_SIZE); p += Align(build_id.Size(), 8); filename = p; p += Align(strlen(filename) + 1, 64); CHECK_EQ(p, end); } void BuildIdRecord::DumpData(size_t indent) const { PrintIndented(indent, "pid %u\n", pid); PrintIndented(indent, "build_id %s\n", build_id.ToString().c_str()); PrintIndented(indent, "filename %s\n", filename); } BuildIdRecord::BuildIdRecord(bool in_kernel, pid_t pid, const BuildId& build_id, const std::string& filename) { SetTypeAndMisc(PERF_RECORD_BUILD_ID, in_kernel ? PERF_RECORD_MISC_KERNEL : PERF_RECORD_MISC_USER); this->pid = pid; this->build_id = build_id; SetSize(header_size() + sizeof(pid) + Align(build_id.Size(), 8) + Align(filename.size() + 1, 64)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(pid, p); memcpy(p, build_id.Data(), build_id.Size()); p += Align(build_id.Size(), 8); this->filename = p; strcpy(p, filename.c_str()); UpdateBinary(new_binary); } AuxTraceInfoRecord::AuxTraceInfoRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); data = reinterpret_cast(p); CHECK_EQ(data->aux_type, AUX_TYPE_ETM); CHECK_EQ(data->version, 0); for (uint32_t i = 0; i < data->nr_cpu; ++i) { CHECK_EQ(data->etm4_info[i].magic, MAGIC_ETM4); } p += sizeof(DataType) + data->nr_cpu * sizeof(ETM4Info); CHECK_EQ(p, end); } AuxTraceInfoRecord::AuxTraceInfoRecord(const DataType& data, const std::vector& etm4_info) { SetTypeAndMisc(PERF_RECORD_AUXTRACE_INFO, 0); SetSize(header_size() + sizeof(DataType) + sizeof(ETM4Info) * etm4_info.size()); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); this->data = reinterpret_cast(p); MoveToBinaryFormat(data, p); for (auto& etm4 : etm4_info) { MoveToBinaryFormat(etm4, p); } UpdateBinary(new_binary); } void AuxTraceInfoRecord::DumpData(size_t indent) const { PrintIndented(indent, "aux_type %u\n", data->aux_type); PrintIndented(indent, "version %" PRIu64 "\n", data->version); PrintIndented(indent, "nr_cpu %u\n", data->nr_cpu); PrintIndented(indent, "pmu_type %u\n", data->pmu_type); PrintIndented(indent, "snapshot %" PRIu64 "\n", data->snapshot); indent++; for (int i = 0; i < data->nr_cpu; i++) { const ETM4Info& e = data->etm4_info[i]; PrintIndented(indent, "magic 0x%" PRIx64 "\n", e.magic); PrintIndented(indent, "cpu %" PRIu64 "\n", e.cpu); PrintIndented(indent, "trcconfigr 0x%" PRIx64 "\n", e.trcconfigr); PrintIndented(indent, "trctraceidr 0x%" PRIx64 "\n", e.trctraceidr); PrintIndented(indent, "trcidr0 0x%" PRIx64 "\n", e.trcidr0); PrintIndented(indent, "trcidr1 0x%" PRIx64 "\n", e.trcidr1); PrintIndented(indent, "trcidr2 0x%" PRIx64 "\n", e.trcidr2); PrintIndented(indent, "trcidr8 0x%" PRIx64 "\n", e.trcidr8); PrintIndented(indent, "trcauthstatus 0x%" PRIx64 "\n", e.trcauthstatus); } } AuxTraceRecord::AuxTraceRecord(char* p) : Record(p) { const char* end = p + header.size; p += header_size(); data = reinterpret_cast(p); p += sizeof(DataType); CHECK_EQ(p, end); } AuxTraceRecord::AuxTraceRecord(uint64_t aux_size, uint64_t offset, uint32_t idx, uint32_t tid, uint32_t cpu) { SetTypeAndMisc(PERF_RECORD_AUXTRACE, 0); SetSize(header_size() + sizeof(DataType)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); data = reinterpret_cast(p); data->aux_size = aux_size; data->offset = offset; data->reserved0 = 0; data->idx = idx; data->tid = tid; data->cpu = cpu; data->reserved1 = 0; UpdateBinary(new_binary); } void AuxTraceRecord::DumpData(size_t indent) const { PrintIndented(indent, "aux_size %" PRIu64 "\n", data->aux_size); PrintIndented(indent, "offset %" PRIu64 "\n", data->offset); PrintIndented(indent, "idx %u\n", data->idx); PrintIndented(indent, "tid %u\n", data->tid); PrintIndented(indent, "cpu %u\n", data->cpu); PrintIndented(indent, "location.file_offset %" PRIu64 "\n", location.file_offset); } KernelSymbolRecord::KernelSymbolRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(kallsyms_size, p); kallsyms = p; p += Align(kallsyms_size, 8); CHECK_EQ(p, end); } void KernelSymbolRecord::DumpData(size_t indent) const { PrintIndented(indent, "kallsyms: %s\n", std::string(kallsyms, kallsyms + kallsyms_size).c_str()); } KernelSymbolRecord::KernelSymbolRecord(const std::string& kallsyms) { SetTypeAndMisc(SIMPLE_PERF_RECORD_KERNEL_SYMBOL, 0); kallsyms_size = kallsyms.size(); SetSize(header_size() + 4 + Align(kallsyms.size(), 8)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(kallsyms_size, p); this->kallsyms = p; memcpy(p, kallsyms.data(), kallsyms_size); UpdateBinary(new_binary); } DsoRecord::DsoRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(dso_type, p); MoveFromBinaryFormat(dso_id, p); MoveFromBinaryFormat(min_vaddr, p); dso_name = p; p += Align(strlen(dso_name) + 1, 8); CHECK_EQ(p, end); } DsoRecord::DsoRecord(uint64_t dso_type, uint64_t dso_id, const std::string& dso_name, uint64_t min_vaddr) { SetTypeAndMisc(SIMPLE_PERF_RECORD_DSO, 0); this->dso_type = dso_type; this->dso_id = dso_id; this->min_vaddr = min_vaddr; SetSize(header_size() + 3 * sizeof(uint64_t) + Align(dso_name.size() + 1, 8)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(dso_type, p); MoveToBinaryFormat(dso_id, p); MoveToBinaryFormat(min_vaddr, p); this->dso_name = p; strcpy(p, dso_name.c_str()); UpdateBinary(new_binary); } void DsoRecord::DumpData(size_t indent) const { PrintIndented(indent, "dso_type: %s(%" PRIu64 ")\n", DsoTypeToString(static_cast(dso_type)), dso_type); PrintIndented(indent, "dso_id: %" PRIu64 "\n", dso_id); PrintIndented(indent, "min_vaddr: 0x%" PRIx64 "\n", min_vaddr); PrintIndented(indent, "dso_name: %s\n", dso_name); } SymbolRecord::SymbolRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(addr, p); MoveFromBinaryFormat(len, p); MoveFromBinaryFormat(dso_id, p); name = p; p += Align(strlen(name) + 1, 8); CHECK_EQ(p, end); } SymbolRecord::SymbolRecord(uint64_t addr, uint64_t len, const std::string& name, uint64_t dso_id) { SetTypeAndMisc(SIMPLE_PERF_RECORD_SYMBOL, 0); this->addr = addr; this->len = len; this->dso_id = dso_id; SetSize(header_size() + 3 * sizeof(uint64_t) + Align(name.size() + 1, 8)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(addr, p); MoveToBinaryFormat(len, p); MoveToBinaryFormat(dso_id, p); this->name = p; strcpy(p, name.c_str()); UpdateBinary(new_binary); } void SymbolRecord::DumpData(size_t indent) const { PrintIndented(indent, "name: %s\n", name); PrintIndented(indent, "addr: 0x%" PRIx64 "\n", addr); PrintIndented(indent, "len: 0x%" PRIx64 "\n", len); PrintIndented(indent, "dso_id: %" PRIu64 "\n", dso_id); } TracingDataRecord::TracingDataRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(data_size, p); data = p; p += Align(data_size, 64); CHECK_EQ(p, end); } TracingDataRecord::TracingDataRecord(const std::vector& tracing_data) { SetTypeAndMisc(SIMPLE_PERF_RECORD_TRACING_DATA, 0); data_size = tracing_data.size(); SetSize(header_size() + sizeof(uint32_t) + Align(tracing_data.size(), 64)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(data_size, p); data = p; memcpy(p, tracing_data.data(), data_size); UpdateBinary(new_binary); } void TracingDataRecord::DumpData(size_t indent) const { Tracing tracing(std::vector(data, data + data_size)); tracing.Dump(indent); } EventIdRecord::EventIdRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(count, p); data = reinterpret_cast(p); p += sizeof(data[0]) * count; CHECK_EQ(p, end); } EventIdRecord::EventIdRecord(const std::vector& data) { SetTypeAndMisc(SIMPLE_PERF_RECORD_EVENT_ID, 0); SetSize(header_size() + sizeof(uint64_t) * (1 + data.size())); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); count = data.size() / 2; MoveToBinaryFormat(count, p); this->data = reinterpret_cast(p); memcpy(p, data.data(), sizeof(uint64_t) * data.size()); UpdateBinary(new_binary); } void EventIdRecord::DumpData(size_t indent) const { PrintIndented(indent, "count: %" PRIu64 "\n", count); for (size_t i = 0; i < count; ++i) { PrintIndented(indent, "attr_id[%" PRIu64 "]: %" PRIu64 "\n", i, data[i].attr_id); PrintIndented(indent, "event_id[%" PRIu64 "]: %" PRIu64 "\n", i, data[i].event_id); } } CallChainRecord::CallChainRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(pid, p); MoveFromBinaryFormat(tid, p); MoveFromBinaryFormat(chain_type, p); MoveFromBinaryFormat(time, p); MoveFromBinaryFormat(ip_nr, p); ips = reinterpret_cast(p); p += ip_nr * sizeof(uint64_t); sps = reinterpret_cast(p); p += ip_nr * sizeof(uint64_t); CHECK_EQ(p, end); } CallChainRecord::CallChainRecord(pid_t pid, pid_t tid, CallChainJoiner::ChainType type, uint64_t time, const std::vector& ips, const std::vector& sps) { CHECK_EQ(ips.size(), sps.size()); SetTypeAndMisc(SIMPLE_PERF_RECORD_CALLCHAIN, 0); this->pid = pid; this->tid = tid; this->chain_type = static_cast(type); this->time = time; this->ip_nr = ips.size(); SetSize(header_size() + (4 + ips.size() * 2) * sizeof(uint64_t)); char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(this->pid, p); MoveToBinaryFormat(this->tid, p); MoveToBinaryFormat(this->chain_type, p); MoveToBinaryFormat(this->time, p); MoveToBinaryFormat(this->ip_nr, p); this->ips = reinterpret_cast(p); MoveToBinaryFormat(ips.data(), ips.size(), p); this->sps = reinterpret_cast(p); MoveToBinaryFormat(sps.data(), sps.size(), p); UpdateBinary(new_binary); } void CallChainRecord::DumpData(size_t indent) const { const char* type_name = ""; switch (chain_type) { case CallChainJoiner::ORIGINAL_OFFLINE: type_name = "ORIGINAL_OFFLINE"; break; case CallChainJoiner::ORIGINAL_REMOTE: type_name = "ORIGINAL_REMOTE"; break; case CallChainJoiner::JOINED_OFFLINE: type_name = "JOINED_OFFLINE"; break; case CallChainJoiner::JOINED_REMOTE: type_name = "JOINED_REMOTE"; break; } PrintIndented(indent, "pid %u\n", pid); PrintIndented(indent, "tid %u\n", tid); PrintIndented(indent, "chain_type %s\n", type_name); PrintIndented(indent, "time %" PRIu64 "\n", time); PrintIndented(indent, "ip_nr %" PRIu64 "\n", ip_nr); for (size_t i = 0; i < ip_nr; ++i) { PrintIndented(indent + 1, "ip 0x%" PRIx64 ", sp 0x%" PRIx64 "\n", ips[i], sps[i]); } } UnwindingResultRecord::UnwindingResultRecord(char* p) : Record(p) { const char* end = p + size(); p += header_size(); MoveFromBinaryFormat(time, p); MoveFromBinaryFormat(unwinding_result.used_time, p); uint64_t stop_reason; MoveFromBinaryFormat(stop_reason, p); unwinding_result.stop_reason = static_cast(stop_reason); MoveFromBinaryFormat(unwinding_result.stop_info, p); MoveFromBinaryFormat(unwinding_result.stack_start, p); MoveFromBinaryFormat(unwinding_result.stack_end, p); CHECK_EQ(p, end); } UnwindingResultRecord::UnwindingResultRecord(uint64_t time, const UnwindingResult& unwinding_result) { SetTypeAndMisc(SIMPLE_PERF_RECORD_UNWINDING_RESULT, 0); SetSize(header_size() + 6 * sizeof(uint64_t)); this->time = time; this->unwinding_result = unwinding_result; char* new_binary = new char[size()]; char* p = new_binary; MoveToBinaryFormat(header, p); MoveToBinaryFormat(this->time, p); MoveToBinaryFormat(unwinding_result.used_time, p); uint64_t stop_reason = unwinding_result.stop_reason; MoveToBinaryFormat(stop_reason, p); MoveToBinaryFormat(unwinding_result.stop_info, p); MoveToBinaryFormat(unwinding_result.stack_start, p); MoveToBinaryFormat(unwinding_result.stack_end, p); UpdateBinary(new_binary); } void UnwindingResultRecord::DumpData(size_t indent) const { PrintIndented(indent, "time %" PRIu64 "\n", time); PrintIndented(indent, "used_time %" PRIu64 "\n", unwinding_result.used_time); static std::unordered_map map = { {UnwindingResult::UNKNOWN_REASON, "UNKNOWN_REASON"}, {UnwindingResult::EXCEED_MAX_FRAMES_LIMIT, "EXCEED_MAX_FRAME_LIMIT"}, {UnwindingResult::ACCESS_REG_FAILED, "ACCESS_REG_FAILED"}, {UnwindingResult::ACCESS_STACK_FAILED, "ACCESS_STACK_FAILED"}, {UnwindingResult::ACCESS_MEM_FAILED, "ACCESS_MEM_FAILED"}, {UnwindingResult::FIND_PROC_INFO_FAILED, "FIND_PROC_INFO_FAILED"}, {UnwindingResult::EXECUTE_DWARF_INSTRUCTION_FAILED, "EXECUTE_DWARF_INSTRUCTION_FAILED"}, {UnwindingResult::DIFFERENT_ARCH, "DIFFERENT_ARCH"}, {UnwindingResult::MAP_MISSING, "MAP_MISSING"}, }; PrintIndented(indent, "stop_reason %s\n", map[unwinding_result.stop_reason].c_str()); if (unwinding_result.stop_reason == UnwindingResult::ACCESS_REG_FAILED) { PrintIndented(indent, "regno %" PRIu64 "\n", unwinding_result.stop_info); } else if (unwinding_result.stop_reason == UnwindingResult::ACCESS_STACK_FAILED || unwinding_result.stop_reason == UnwindingResult::ACCESS_MEM_FAILED) { PrintIndented(indent, "addr 0x%" PRIx64 "\n", unwinding_result.stop_info); } PrintIndented(indent, "stack_start 0x%" PRIx64 "\n", unwinding_result.stack_start); PrintIndented(indent, "stack_end 0x%" PRIx64 "\n", unwinding_result.stack_end); } UnknownRecord::UnknownRecord(char* p) : Record(p) { p += header_size(); data = p; } void UnknownRecord::DumpData(size_t) const {} std::unique_ptr ReadRecordFromBuffer(const perf_event_attr& attr, uint32_t type, char* p) { switch (type) { case PERF_RECORD_MMAP: return std::unique_ptr(new MmapRecord(attr, p)); case PERF_RECORD_MMAP2: return std::unique_ptr(new Mmap2Record(attr, p)); case PERF_RECORD_COMM: return std::unique_ptr(new CommRecord(attr, p)); case PERF_RECORD_EXIT: return std::unique_ptr(new ExitRecord(attr, p)); case PERF_RECORD_FORK: return std::unique_ptr(new ForkRecord(attr, p)); case PERF_RECORD_LOST: return std::unique_ptr(new LostRecord(attr, p)); case PERF_RECORD_SAMPLE: return std::unique_ptr(new SampleRecord(attr, p)); case PERF_RECORD_AUX: return std::unique_ptr(new AuxRecord(attr, p)); case PERF_RECORD_TRACING_DATA: return std::unique_ptr(new TracingDataRecord(p)); case PERF_RECORD_AUXTRACE_INFO: return std::unique_ptr(new AuxTraceInfoRecord(p)); case PERF_RECORD_AUXTRACE: return std::unique_ptr(new AuxTraceRecord(p)); case SIMPLE_PERF_RECORD_KERNEL_SYMBOL: return std::unique_ptr(new KernelSymbolRecord(p)); case SIMPLE_PERF_RECORD_DSO: return std::unique_ptr(new DsoRecord(p)); case SIMPLE_PERF_RECORD_SYMBOL: return std::unique_ptr(new SymbolRecord(p)); case SIMPLE_PERF_RECORD_EVENT_ID: return std::unique_ptr(new EventIdRecord(p)); case SIMPLE_PERF_RECORD_CALLCHAIN: return std::unique_ptr(new CallChainRecord(p)); case SIMPLE_PERF_RECORD_UNWINDING_RESULT: return std::unique_ptr(new UnwindingResultRecord(p)); case SIMPLE_PERF_RECORD_TRACING_DATA: return std::unique_ptr(new TracingDataRecord(p)); default: return std::unique_ptr(new UnknownRecord(p)); } } std::unique_ptr ReadRecordFromOwnedBuffer(const perf_event_attr& attr, uint32_t type, char* p) { std::unique_ptr record = ReadRecordFromBuffer(attr, type, p); if (record != nullptr) { record->OwnBinary(); } else { delete[] p; } return record; } std::vector> ReadRecordsFromBuffer( const perf_event_attr& attr, char* buf, size_t buf_size) { std::vector> result; char* p = buf; char* end = buf + buf_size; while (p < end) { RecordHeader header(p); CHECK_LE(p + header.size, end); CHECK_NE(0u, header.size); result.push_back(ReadRecordFromBuffer(attr, header.type, p)); p += header.size; } return result; } std::unique_ptr ReadRecordFromBuffer(const perf_event_attr& attr, char* p) { auto header = reinterpret_cast(p); return ReadRecordFromBuffer(attr, header->type, p); }