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flutter / third_party / perfetto / aa45fe0022ec856ce626c7abd1e9e7ec698670b5 / . / src / trace_processor / proto_trace_parser.cc
blob: c969241700440915d9831d7b0c0091d0cb373726 [file] [log] [blame]
/*
* Copyright (C) 2018 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 "src/trace_processor/proto_trace_parser.h"
#include <string.h>
#include <string>
#include "perfetto/base/logging.h"
#include "perfetto/base/string_view.h"
#include "perfetto/base/utils.h"
#include "perfetto/protozero/proto_decoder.h"
#include "perfetto/traced/sys_stats_counters.h"
#include "src/trace_processor/event_tracker.h"
#include "src/trace_processor/process_tracker.h"
#include "src/trace_processor/slice_tracker.h"
#include "src/trace_processor/trace_processor_context.h"
#include "perfetto/trace/trace.pb.h"
#include "perfetto/trace/trace_packet.pb.h"
namespace perfetto {
namespace trace_processor {
// We have to handle trace_marker events of a few different types:
// 1. some random text
// 2. B|1636|pokeUserActivity
// 3. E|1636
// 4. C|1636|wq:monitor|0
bool ParseSystraceTracePoint(base::StringView str, SystraceTracePoint* out) {
// THIS char* IS NOT NULL TERMINATED.
const char* s = str.data();
size_t len = str.size();
// If str matches '[BEC]\|[0-9]+[\|\n]' set tid_length to the length of
// the number. Otherwise return false.
if (s[1] != '|' && s[1] != '\n')
return false;
if (s[0] != 'B' && s[0] != 'E' && s[0] != 'C')
return false;
size_t tid_length = 0;
for (size_t i = 2; i < len; i++) {
if (s[i] == '|' || s[i] == '\n') {
tid_length = i - 2;
break;
}
if (s[i] < '0' || s[i] > '9')
return false;
}
if (tid_length == 0) {
out->tid = 0;
} else {
std::string tid_str(s + 2, tid_length);
out->tid = static_cast<uint32_t>(std::stoi(tid_str.c_str()));
}
out->phase = s[0];
switch (s[0]) {
case 'B': {
size_t name_index = 2 + tid_length + 1;
out->name = base::StringView(s + name_index, len - name_index);
return true;
}
case 'E': {
return true;
}
case 'C': {
size_t name_index = 2 + tid_length + 1;
size_t name_length = 0;
for (size_t i = name_index; i < len; i++) {
if (s[i] == '|' || s[i] == '\n') {
name_length = i - name_index;
break;
}
}
out->name = base::StringView(s + name_index, name_length);
size_t value_index = name_index + name_length + 1;
char value_str[32];
strcpy(value_str, s + value_index);
out->value = std::stod(value_str);
return true;
}
default:
return false;
}
}
using protozero::ProtoDecoder;
ProtoTraceParser::ProtoTraceParser(TraceProcessorContext* context)
: context_(context),
utid_name_id_(context->storage->InternString("utid")),
cpu_freq_name_id_(context->storage->InternString("cpufreq")),
cpu_idle_name_id_(context->storage->InternString("cpuidle")),
num_forks_name_id_(context->storage->InternString("num_forks")),
num_irq_total_name_id_(context->storage->InternString("num_irq_total")),
num_softirq_total_name_id_(
context->storage->InternString("num_softirq_total")),
num_irq_name_id_(context->storage->InternString("num_irq")),
num_softirq_name_id_(context->storage->InternString("num_softirq")),
cpu_times_user_ns_id_(
context->storage->InternString("cpu.times.user_ns")),
cpu_times_user_ice_ns_id_(
context->storage->InternString("cpu.times.user_ice_ns")),
cpu_times_system_mode_ns_id_(
context->storage->InternString("cpu.times.system_mode_ns")),
cpu_times_idle_ns_id_(
context->storage->InternString("cpu.times.idle_ns")),
cpu_times_io_wait_ns_id_(
context->storage->InternString("cpu.times.io_wait_ns")),
cpu_times_irq_ns_id_(context->storage->InternString("cpu.times.irq_ns")),
cpu_times_softirq_ns_id_(
context->storage->InternString("cpu.times.softirq_ns")),
ion_heap_grow_id_(context->storage->InternString("ion_heap_grow")),
ion_heap_shrink_id_(context->storage->InternString("ion_heap_shrink")),
signal_deliver_id_(context->storage->InternString("signal_deliver")),
signal_generate_id_(context->storage->InternString("signal_generate")),
batt_charge_id_(context->storage->InternString("batt.charge_uah")),
batt_capacity_id_(context->storage->InternString("batt.capacity_pct")),
batt_current_id_(context->storage->InternString("batt.current_ua")),
batt_current_avg_id_(
context->storage->InternString("batt.current.avg_ua")),
oom_score_adj_id_(context->storage->InternString("oom_score_adj")) {
for (const auto& name : BuildMeminfoCounterNames()) {
meminfo_strs_id_.emplace_back(context->storage->InternString(name));
}
for (const auto& name : BuildVmstatCounterNames()) {
vmstat_strs_id_.emplace_back(context->storage->InternString(name));
}
rss_members_.emplace_back(
context->storage->InternString("rss_stat.mm_filepages"));
rss_members_.emplace_back(
context->storage->InternString("rss_stat.mm_anonpages"));
rss_members_.emplace_back(
context->storage->InternString("rss_stat.mm_swapents"));
rss_members_.emplace_back(
context->storage->InternString("rss_stat.mm_shmempages"));
rss_members_.emplace_back(
context->storage->InternString("rss_stat.unknown")); // Keep this last.
using MemCounters = protos::ProcessStats::MemCounters;
proc_mem_counter_names_[MemCounters::kVmSizeKbFieldNumber] =
context->storage->InternString("mem.virt");
proc_mem_counter_names_[MemCounters::kVmRssKbFieldNumber] =
context->storage->InternString("mem.rss");
proc_mem_counter_names_[MemCounters::kRssAnonKbFieldNumber] =
context->storage->InternString("mem.rss.anon");
proc_mem_counter_names_[MemCounters::kRssFileKbFieldNumber] =
context->storage->InternString("mem.rss.file");
proc_mem_counter_names_[MemCounters::kRssShmemKbFieldNumber] =
context->storage->InternString("mem.rss.shmem");
proc_mem_counter_names_[MemCounters::kVmSwapKbFieldNumber] =
context->storage->InternString("mem.swap");
proc_mem_counter_names_[MemCounters::kVmLockedKbFieldNumber] =
context->storage->InternString("mem.locked");
proc_mem_counter_names_[MemCounters::kVmHwmKbFieldNumber] =
context->storage->InternString("mem.rss.watermark");
}
ProtoTraceParser::~ProtoTraceParser() = default;
void ProtoTraceParser::ParseTracePacket(int64_t ts, TraceBlobView packet) {
ProtoDecoder decoder(packet.data(), packet.length());
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::TracePacket::kProcessTreeFieldNumber: {
const size_t fld_off = packet.offset_of(fld.data());
ParseProcessTree(packet.slice(fld_off, fld.size()));
break;
}
case protos::TracePacket::kProcessStatsFieldNumber: {
const size_t fld_off = packet.offset_of(fld.data());
ParseProcessStats(ts, packet.slice(fld_off, fld.size()));
break;
}
case protos::TracePacket::kSysStatsFieldNumber: {
const size_t fld_off = packet.offset_of(fld.data());
ParseSysStats(ts, packet.slice(fld_off, fld.size()));
break;
}
case protos::TracePacket::kBatteryFieldNumber: {
const size_t fld_off = packet.offset_of(fld.data());
ParseBatteryCounters(ts, packet.slice(fld_off, fld.size()));
break;
}
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseSysStats(int64_t ts, TraceBlobView stats) {
ProtoDecoder decoder(stats.data(), stats.length());
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SysStats::kMeminfoFieldNumber: {
const size_t fld_off = stats.offset_of(fld.data());
ParseMemInfo(ts, stats.slice(fld_off, fld.size()));
break;
}
case protos::SysStats::kVmstatFieldNumber: {
const size_t fld_off = stats.offset_of(fld.data());
ParseVmStat(ts, stats.slice(fld_off, fld.size()));
break;
}
case protos::SysStats::kCpuStatFieldNumber: {
const size_t fld_off = stats.offset_of(fld.data());
ParseCpuTimes(ts, stats.slice(fld_off, fld.size()));
break;
}
case protos::SysStats::kNumIrqFieldNumber: {
const size_t fld_off = stats.offset_of(fld.data());
ParseIrqCount(ts, stats.slice(fld_off, fld.size()),
/*is_softirq=*/false);
break;
}
case protos::SysStats::kNumSoftirqFieldNumber: {
const size_t fld_off = stats.offset_of(fld.data());
ParseIrqCount(ts, stats.slice(fld_off, fld.size()),
/*is_softirq=*/true);
break;
}
case protos::SysStats::kNumForksFieldNumber: {
context_->event_tracker->PushCounter(
ts, fld.as_uint32(), num_forks_name_id_, 0, RefType::kRefNoRef);
break;
}
case protos::SysStats::kNumIrqTotalFieldNumber: {
context_->event_tracker->PushCounter(
ts, fld.as_uint32(), num_irq_total_name_id_, 0, RefType::kRefNoRef);
break;
}
case protos::SysStats::kNumSoftirqTotalFieldNumber: {
context_->event_tracker->PushCounter(ts, fld.as_uint32(),
num_softirq_total_name_id_, 0,
RefType::kRefNoRef);
break;
}
default:
break;
}
}
}
void ProtoTraceParser::ParseIrqCount(int64_t ts,
TraceBlobView irq,
bool is_soft) {
ProtoDecoder decoder(irq.data(), irq.length());
uint32_t key = 0;
uint32_t value = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SysStats::InterruptCount::kIrqFieldNumber:
key = fld.as_uint32();
break;
case protos::SysStats::InterruptCount::kCountFieldNumber:
value = fld.as_uint32();
break;
}
}
RefType ref_type = is_soft ? RefType::kRefIrq : RefType::kRefSoftIrq;
StringId name_id = is_soft ? num_irq_name_id_ : num_softirq_name_id_;
context_->event_tracker->PushCounter(ts, value, name_id, key, ref_type);
}
void ProtoTraceParser::ParseMemInfo(int64_t ts, TraceBlobView mem) {
ProtoDecoder decoder(mem.data(), mem.length());
uint32_t key = 0;
uint32_t value = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SysStats::MeminfoValue::kKeyFieldNumber:
key = fld.as_uint32();
break;
case protos::SysStats::MeminfoValue::kValueFieldNumber:
value = fld.as_uint32();
break;
}
}
if (PERFETTO_UNLIKELY(key >= meminfo_strs_id_.size())) {
PERFETTO_ELOG("MemInfo key %d is not recognized.", key);
return;
}
context_->event_tracker->PushCounter(ts, value, meminfo_strs_id_[key], 0,
RefType::kRefNoRef);
}
void ProtoTraceParser::ParseVmStat(int64_t ts, TraceBlobView stat) {
ProtoDecoder decoder(stat.data(), stat.length());
uint32_t key = 0;
uint32_t value = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SysStats::VmstatValue::kKeyFieldNumber:
key = fld.as_uint32();
break;
case protos::SysStats::VmstatValue::kValueFieldNumber:
value = fld.as_uint32();
break;
}
}
if (PERFETTO_UNLIKELY(key >= vmstat_strs_id_.size())) {
PERFETTO_ELOG("VmStat key %d is not recognized.", key);
return;
}
context_->event_tracker->PushCounter(ts, value, vmstat_strs_id_[key], 0,
RefType::kRefNoRef);
}
void ProtoTraceParser::ParseCpuTimes(int64_t ts, TraceBlobView cpu_times) {
ProtoDecoder decoder(cpu_times.data(), cpu_times.length());
uint64_t raw_cpu = 0;
uint32_t value = 0;
// Speculate on CPU being first.
constexpr auto kCpuFieldTag = protozero::proto_utils::MakeTagVarInt(
protos::SysStats::CpuTimes::kCpuIdFieldNumber);
if (cpu_times.length() > 2 && cpu_times.data()[0] == kCpuFieldTag &&
cpu_times.data()[1] < 0x80) {
raw_cpu = cpu_times.data()[1];
} else {
if (!PERFETTO_LIKELY((
decoder.FindIntField<protos::SysStats::CpuTimes::kCpuIdFieldNumber>(
&raw_cpu)))) {
PERFETTO_ELOG("CPU field not found in CpuTimes");
return;
}
}
int64_t cpu = static_cast<int64_t>(raw_cpu);
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SysStats::CpuTimes::kUserNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(ts, value, cpu_times_user_ns_id_,
cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kUserIceNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(
ts, value, cpu_times_user_ice_ns_id_, cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kSystemModeNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(
ts, value, cpu_times_system_mode_ns_id_, cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kIdleNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(ts, value, cpu_times_idle_ns_id_,
cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kIoWaitNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(
ts, value, cpu_times_io_wait_ns_id_, cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kIrqNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(ts, value, cpu_times_irq_ns_id_,
cpu, RefType::kRefCpuId);
break;
}
case protos::SysStats::CpuTimes::kSoftirqNsFieldNumber: {
value = fld.as_uint32();
context_->event_tracker->PushCounter(
ts, value, cpu_times_softirq_ns_id_, cpu, RefType::kRefCpuId);
break;
}
default:
break;
}
}
}
void ProtoTraceParser::ParseProcessTree(TraceBlobView pstree) {
ProtoDecoder decoder(pstree.data(), pstree.length());
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
const size_t fld_off = pstree.offset_of(fld.data());
switch (fld.id) {
case protos::ProcessTree::kProcessesFieldNumber: {
ParseProcess(pstree.slice(fld_off, fld.size()));
break;
}
case protos::ProcessTree::kThreadsFieldNumber: {
ParseThread(pstree.slice(fld_off, fld.size()));
break;
}
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseProcessStats(int64_t ts, TraceBlobView stats) {
ProtoDecoder decoder(stats.data(), stats.length());
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
const size_t fld_off = stats.offset_of(fld.data());
switch (fld.id) {
case protos::ProcessStats::kMemCountersFieldNumber: {
ParseProcMemCounters(ts, stats.slice(fld_off, fld.size()));
break;
}
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseProcMemCounters(int64_t ts,
TraceBlobView proc_stat) {
ProtoDecoder decoder(proc_stat.data(), proc_stat.length());
uint32_t pid = 0;
// Maps a process counter field it to its value.
// E.g., 4 := 1024 -> "mem.rss.anon" := 1024.
std::array<uint64_t, kProcMemCounterSize> counter_values{};
std::array<uint8_t, kProcMemCounterSize> has_counter{};
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::ProcessStats::MemCounters::kPidFieldNumber:
pid = fld.as_uint32();
break;
default:
if (fld.id < counter_values.size()) {
// Memory counters are in KB, keep values in bytes in the trace
// processor.
counter_values[fld.id] = fld.as_uint64() * 1024;
has_counter[fld.id] = 1;
} else {
PERFETTO_ELOG("Skipping unknown process counters %" PRIu32, fld.id);
}
}
}
UniqueTid utid = context_->process_tracker->UpdateThread(ts, pid, 0);
// Skip field_id 0 (invalid) and 1 (pid).
for (size_t field_id = 2; field_id < counter_values.size(); field_id++) {
if (!has_counter[field_id])
continue;
// Lookup the interned string id from the field name using the
// pre-cached |proc_mem_counter_names_| map.
StringId name = proc_mem_counter_names_[field_id];
uint64_t value = counter_values[field_id];
auto row_id = context_->event_tracker->PushCounter(
ts, value, name, utid, RefType::kRefUtidLookupUpid);
context_->storage->mutable_args()->AddArg(row_id, utid_name_id_,
utid_name_id_, utid);
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseThread(TraceBlobView thread) {
ProtoDecoder decoder(thread.data(), thread.length());
uint32_t tid = 0;
uint32_t tgid = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::ProcessTree::Thread::kTidFieldNumber:
tid = fld.as_uint32();
break;
case protos::ProcessTree::Thread::kTgidFieldNumber:
tgid = fld.as_uint32();
break;
default:
break;
}
}
context_->process_tracker->UpdateThread(tid, tgid);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseProcess(TraceBlobView process) {
ProtoDecoder decoder(process.data(), process.length());
uint32_t pid = 0;
base::StringView process_name;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::ProcessTree::Process::kPidFieldNumber:
pid = fld.as_uint32();
break;
case protos::ProcessTree::Process::kCmdlineFieldNumber:
if (process_name.empty())
process_name = fld.as_string();
break;
default:
break;
}
}
context_->process_tracker->UpdateProcess(pid, process_name);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseFtracePacket(uint32_t cpu,
int64_t timestamp,
TraceBlobView ftrace) {
ProtoDecoder decoder(ftrace.data(), ftrace.length());
uint32_t pid = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::FtraceEvent::kPidFieldNumber: {
pid = fld.as_uint32();
break;
}
case protos::FtraceEvent::kSchedSwitchFieldNumber: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseSchedSwitch(cpu, timestamp, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kCpuFrequency: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseCpuFreq(timestamp, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kCpuIdle: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseCpuIdle(timestamp, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kPrintFieldNumber: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParsePrint(cpu, timestamp, pid, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kRssStatFieldNumber: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseRssStat(timestamp, pid, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kIonHeapGrow: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseIonHeapGrow(timestamp, pid, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kIonHeapShrink: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseIonHeapShrink(timestamp, pid, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kSignalGenerate: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseSignalGenerate(timestamp, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kSignalDeliver: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseSignalDeliver(timestamp, pid, ftrace.slice(fld_off, fld.size()));
break;
}
case protos::FtraceEvent::kOomScoreAdjUpdate: {
PERFETTO_DCHECK(timestamp > 0);
const size_t fld_off = ftrace.offset_of(fld.data());
ParseOOMScoreAdjUpdate(timestamp, ftrace.slice(fld_off, fld.size()));
break;
}
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseSignalDeliver(int64_t timestamp,
uint32_t pid,
TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t sig = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SignalDeliverFtraceEvent::kSigFieldNumber:
sig = fld.as_uint32();
break;
}
}
auto* instants = context_->storage->mutable_instants();
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
instants->AddInstantEvent(timestamp, signal_deliver_id_, sig, utid,
RefType::kRefUtid);
}
// This event has both the pid of the thread that sent the signal and the
// destination of the signal. Currently storing the pid of the destination.
void ProtoTraceParser::ParseSignalGenerate(int64_t timestamp,
TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t pid = 0;
uint32_t sig = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SignalGenerateFtraceEvent::kPidFieldNumber:
pid = fld.as_uint32();
break;
case protos::SignalGenerateFtraceEvent::kSigFieldNumber:
sig = fld.as_uint32();
break;
}
}
auto* instants = context_->storage->mutable_instants();
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
instants->AddInstantEvent(timestamp, signal_generate_id_, sig, utid,
RefType::kRefUtid);
}
void ProtoTraceParser::ParseLowmemoryKill(int64_t timestamp,
TraceBlobView view) {
// TODO(taylori): Store the pagecache_size, pagecache_limit and free fields
// in an args table
ProtoDecoder decoder(view.data(), view.length());
uint32_t pid = 0;
base::StringView comm;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::LowmemoryKillFtraceEvent::kPidFieldNumber:
pid = fld.as_uint32();
break;
case protos::LowmemoryKillFtraceEvent::kCommFieldNumber:
comm = fld.as_string();
break;
}
}
// TODO(taylori): Move the comm to the args table once it exists.
StringId name = context_->storage->InternString(
base::StringView("mem.lmk." + comm.ToStdString()));
auto* instants = context_->storage->mutable_instants();
// Storing the pid of the event that is lmk-ed.
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
instants->AddInstantEvent(timestamp, 0, name, utid, RefType::kRefUtid);
}
void ProtoTraceParser::ParseRssStat(int64_t timestamp,
uint32_t pid,
TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
const auto kRssStatUnknown = static_cast<uint32_t>(rss_members_.size()) - 1;
uint32_t member = kRssStatUnknown;
uint32_t size = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::RssStatFtraceEvent::kMemberFieldNumber:
member = fld.as_uint32();
break;
case protos::RssStatFtraceEvent::kSizeFieldNumber:
size = fld.as_uint32();
break;
}
}
if (member >= rss_members_.size()) {
// TODO(lalitm): this import error should be exposed in the stats.
member = kRssStatUnknown;
}
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
context_->event_tracker->PushCounter(timestamp, size, rss_members_[member],
utid, RefType::kRefUtidLookupUpid);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseIonHeapGrow(int64_t timestamp,
uint32_t pid,
TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t value = 0;
// TODO(b/118300811): The heap name pointer cannot be read. Read once it
// has been fixed.
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::IonHeapGrowFtraceEvent::kTotalAllocatedFieldNumber:
value = fld.as_uint32();
break;
}
}
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
context_->event_tracker->PushCounter(timestamp, value, ion_heap_grow_id_,
utid, RefType::kRefUtid);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseIonHeapShrink(int64_t timestamp,
uint32_t pid,
TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t value = 0;
// TODO(b/118300811): The heap name pointer cannot be read. Read once it
// has been fixed.
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::IonHeapShrinkFtraceEvent::kTotalAllocatedFieldNumber:
value = fld.as_uint32();
break;
}
}
UniqueTid utid = context_->process_tracker->UpdateThread(timestamp, pid, 0);
context_->event_tracker->PushCounter(timestamp, value, ion_heap_shrink_id_,
utid, RefType::kRefUtid);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseCpuFreq(int64_t timestamp, TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t cpu_affected = 0;
uint32_t new_freq = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::CpuFrequencyFtraceEvent::kCpuIdFieldNumber:
cpu_affected = fld.as_uint32();
break;
case protos::CpuFrequencyFtraceEvent::kStateFieldNumber:
new_freq = fld.as_uint32();
break;
}
}
context_->event_tracker->PushCounter(timestamp, new_freq, cpu_freq_name_id_,
cpu_affected, RefType::kRefCpuId);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseCpuIdle(int64_t timestamp, TraceBlobView view) {
ProtoDecoder decoder(view.data(), view.length());
uint32_t cpu_affected = 0;
uint32_t new_state = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::CpuIdleFtraceEvent::kCpuIdFieldNumber:
cpu_affected = fld.as_uint32();
break;
case protos::CpuIdleFtraceEvent::kStateFieldNumber:
new_state = fld.as_uint32();
break;
}
}
context_->event_tracker->PushCounter(timestamp, new_state, cpu_idle_name_id_,
cpu_affected, RefType::kRefCpuId);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseSchedSwitch(uint32_t cpu,
int64_t timestamp,
TraceBlobView sswitch) {
ProtoDecoder decoder(sswitch.data(), sswitch.length());
uint32_t prev_pid = 0;
uint32_t prev_state = 0;
base::StringView next_comm;
uint32_t next_pid = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::SchedSwitchFtraceEvent::kPrevPidFieldNumber:
prev_pid = fld.as_uint32();
break;
case protos::SchedSwitchFtraceEvent::kPrevStateFieldNumber:
prev_state = fld.as_uint32();
break;
case protos::SchedSwitchFtraceEvent::kNextPidFieldNumber:
next_pid = fld.as_uint32();
break;
case protos::SchedSwitchFtraceEvent::kNextCommFieldNumber:
next_comm = fld.as_string();
break;
default:
break;
}
}
context_->event_tracker->PushSchedSwitch(cpu, timestamp, prev_pid, prev_state,
next_pid, next_comm);
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParsePrint(uint32_t,
int64_t timestamp,
uint32_t pid,
TraceBlobView print) {
ProtoDecoder decoder(print.data(), print.length());
base::StringView buf{};
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
if (fld.id == protos::PrintFtraceEvent::kBufFieldNumber) {
buf = fld.as_string();
break;
}
}
SystraceTracePoint point{};
if (!ParseSystraceTracePoint(buf, &point))
return;
switch (point.phase) {
case 'B': {
StringId name_id = context_->storage->InternString(point.name);
context_->slice_tracker->BeginAndroid(timestamp, pid, point.tid,
0 /*cat_id*/, name_id);
break;
}
case 'E': {
context_->slice_tracker->EndAndroid(timestamp, pid, point.tid);
break;
}
case 'C': {
UniqueTid utid =
context_->process_tracker->UpdateThread(timestamp, point.tid, 0);
StringId name_id = context_->storage->InternString(point.name);
context_->event_tracker->PushCounter(timestamp, point.value, name_id,
utid, RefType::kRefUtid);
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseBatteryCounters(int64_t ts, TraceBlobView battery) {
ProtoDecoder decoder(battery.data(), battery.length());
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::BatteryCounters::kChargeCounterUahFieldNumber:
context_->event_tracker->PushCounter(
ts, fld.as_int64(), batt_charge_id_, 0, RefType::kRefNoRef);
break;
case protos::BatteryCounters::kCapacityPercentFieldNumber:
context_->event_tracker->PushCounter(
ts, static_cast<double>(fld.as_float()), batt_capacity_id_, 0,
RefType::kRefNoRef);
break;
case protos::BatteryCounters::kCurrentUaFieldNumber:
context_->event_tracker->PushCounter(
ts, fld.as_int64(), batt_current_id_, 0, RefType::kRefNoRef);
break;
case protos::BatteryCounters::kCurrentAvgUaFieldNumber:
context_->event_tracker->PushCounter(
ts, fld.as_int64(), batt_current_avg_id_, 0, RefType::kRefNoRef);
break;
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
}
void ProtoTraceParser::ParseOOMScoreAdjUpdate(int64_t ts,
TraceBlobView oom_update) {
ProtoDecoder decoder(oom_update.data(), oom_update.length());
uint32_t pid = 0;
int16_t oom_adj = 0;
for (auto fld = decoder.ReadField(); fld.id != 0; fld = decoder.ReadField()) {
switch (fld.id) {
case protos::OomScoreAdjUpdateFtraceEvent::kOomScoreAdjFieldNumber:
// TODO(b/120618641): The int16_t static cast is required because of the
// linked negative varint encoding bug.
oom_adj = static_cast<int16_t>(fld.as_int32());
break;
case protos::OomScoreAdjUpdateFtraceEvent::kPidFieldNumber:
pid = fld.as_uint32();
break;
case protos::OomScoreAdjUpdateFtraceEvent::kCommFieldNumber:
default:
break;
}
}
PERFETTO_DCHECK(decoder.IsEndOfBuffer());
UniquePid upid = context_->process_tracker->UpdateProcess(pid);
context_->event_tracker->PushCounter(ts, oom_adj, oom_score_adj_id_, upid,
RefType::kRefUpid);
}
} // namespace trace_processor
} // namespace perfetto