llvm-project/llvm/lib/Support/Timer.cpp

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//===-- Timer.cpp - Interval Timing Support -------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
/// \file Interval Timing implementation.
//
//===----------------------------------------------------------------------===//
#include "llvm/Support/Timer.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/ManagedStatic.h"
#include "llvm/Support/Mutex.h"
#include "llvm/Support/Process.h"
Annotate timeline in Instruments with passes and other timed regions. Summary: Instruments is a useful tool for finding performance issues in LLVM but it can be difficult to identify regions of interest on the timeline that we can use to filter the profiler or allocations instrument. Xcode 10 and the latest macOS/iOS/etc. added support for the os_signpost() API which allows us to annotate the timeline with information that's meaningful to LLVM. This patch causes timer start and end events to emit signposts. When used with -time-passes, this causes the passes to be annotated on the Instruments timeline. In addition to visually showing the duration of passes on the timeline, it also allows us to filter the profile and allocations instrument down to an individual pass allowing us to find the issues within that pass without being drowned out by the noise from other parts of the compiler. Using this in conjunction with the Time Profiler (in high frequency mode) and the Allocations instrument is how I found the SparseBitVector that should have been a BitVector and the DenseMap that could be replaced by a sorted vector a couple months ago. I added NamedRegionTimers to TableGen and used the resulting annotations to identify the slow portions of the Register Info Emitter. Some of these were placed according to educated guesses while others were placed according to hot functions from a previous profile. From there I filtered the profile to a slow portion and the aforementioned issues stood out in the profile. To use this feature enable LLVM_SUPPORT_XCODE_SIGNPOSTS in CMake and run the compiler under Instruments with -time-passes like so: instruments -t 'Time Profiler' bin/llc -time-passes -o - input.ll' Then open the resulting trace in Instruments. There was a talk at WWDC 2018 that explained the feature which can be found at https://developer.apple.com/videos/play/wwdc2018/405/ if you'd like to know more about it. Reviewers: bogner Reviewed By: bogner Subscribers: jdoerfert, mgorny, kristina, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D52954 llvm-svn: 354365
2019-02-20 02:18:31 +08:00
#include "llvm/Support/Signposts.h"
#include "llvm/Support/YAMLTraits.h"
#include "llvm/Support/raw_ostream.h"
#include <limits>
using namespace llvm;
// This ugly hack is brought to you courtesy of constructor/destructor ordering
// being unspecified by C++. Basically the problem is that a Statistic object
// gets destroyed, which ends up calling 'GetLibSupportInfoOutputFile()'
// (below), which calls this function. LibSupportInfoOutputFilename used to be
// a global variable, but sometimes it would get destroyed before the Statistic,
// causing havoc to ensue. We "fix" this by creating the string the first time
// it is needed and never destroying it.
static ManagedStatic<std::string> LibSupportInfoOutputFilename;
static std::string &getLibSupportInfoOutputFilename() {
return *LibSupportInfoOutputFilename;
}
static ManagedStatic<sys::SmartMutex<true> > TimerLock;
Annotate timeline in Instruments with passes and other timed regions. Summary: Instruments is a useful tool for finding performance issues in LLVM but it can be difficult to identify regions of interest on the timeline that we can use to filter the profiler or allocations instrument. Xcode 10 and the latest macOS/iOS/etc. added support for the os_signpost() API which allows us to annotate the timeline with information that's meaningful to LLVM. This patch causes timer start and end events to emit signposts. When used with -time-passes, this causes the passes to be annotated on the Instruments timeline. In addition to visually showing the duration of passes on the timeline, it also allows us to filter the profile and allocations instrument down to an individual pass allowing us to find the issues within that pass without being drowned out by the noise from other parts of the compiler. Using this in conjunction with the Time Profiler (in high frequency mode) and the Allocations instrument is how I found the SparseBitVector that should have been a BitVector and the DenseMap that could be replaced by a sorted vector a couple months ago. I added NamedRegionTimers to TableGen and used the resulting annotations to identify the slow portions of the Register Info Emitter. Some of these were placed according to educated guesses while others were placed according to hot functions from a previous profile. From there I filtered the profile to a slow portion and the aforementioned issues stood out in the profile. To use this feature enable LLVM_SUPPORT_XCODE_SIGNPOSTS in CMake and run the compiler under Instruments with -time-passes like so: instruments -t 'Time Profiler' bin/llc -time-passes -o - input.ll' Then open the resulting trace in Instruments. There was a talk at WWDC 2018 that explained the feature which can be found at https://developer.apple.com/videos/play/wwdc2018/405/ if you'd like to know more about it. Reviewers: bogner Reviewed By: bogner Subscribers: jdoerfert, mgorny, kristina, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D52954 llvm-svn: 354365
2019-02-20 02:18:31 +08:00
/// Allows llvm::Timer to emit signposts when supported.
static ManagedStatic<SignpostEmitter> Signposts;
namespace {
static cl::opt<bool>
TrackSpace("track-memory", cl::desc("Enable -time-passes memory "
"tracking (this may be slow)"),
cl::Hidden);
static cl::opt<std::string, true>
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InfoOutputFilename("info-output-file", cl::value_desc("filename"),
cl::desc("File to append -stats and -timer output to"),
cl::Hidden, cl::location(getLibSupportInfoOutputFilename()));
}
std::unique_ptr<raw_fd_ostream> llvm::CreateInfoOutputFile() {
const std::string &OutputFilename = getLibSupportInfoOutputFilename();
if (OutputFilename.empty())
return std::make_unique<raw_fd_ostream>(2, false); // stderr.
if (OutputFilename == "-")
return std::make_unique<raw_fd_ostream>(1, false); // stdout.
// Append mode is used because the info output file is opened and closed
// each time -stats or -time-passes wants to print output to it. To
// compensate for this, the test-suite Makefiles have code to delete the
// info output file before running commands which write to it.
std::error_code EC;
auto Result = std::make_unique<raw_fd_ostream>(
OutputFilename, EC, sys::fs::OF_Append | sys::fs::OF_Text);
if (!EC)
return Result;
errs() << "Error opening info-output-file '"
<< OutputFilename << " for appending!\n";
return std::make_unique<raw_fd_ostream>(2, false); // stderr.
}
namespace {
struct CreateDefaultTimerGroup {
static void *call() {
return new TimerGroup("misc", "Miscellaneous Ungrouped Timers");
}
};
} // namespace
static ManagedStatic<TimerGroup, CreateDefaultTimerGroup> DefaultTimerGroup;
static TimerGroup *getDefaultTimerGroup() { return &*DefaultTimerGroup; }
//===----------------------------------------------------------------------===//
// Timer Implementation
//===----------------------------------------------------------------------===//
void Timer::init(StringRef TimerName, StringRef TimerDescription) {
init(TimerName, TimerDescription, *getDefaultTimerGroup());
}
void Timer::init(StringRef TimerName, StringRef TimerDescription,
TimerGroup &tg) {
assert(!TG && "Timer already initialized");
Name.assign(TimerName.begin(), TimerName.end());
Description.assign(TimerDescription.begin(), TimerDescription.end());
Running = Triggered = false;
TG = &tg;
TG->addTimer(*this);
}
Timer::~Timer() {
if (!TG) return; // Never initialized, or already cleared.
TG->removeTimer(*this);
}
static inline size_t getMemUsage() {
if (!TrackSpace) return 0;
return sys::Process::GetMallocUsage();
}
TimeRecord TimeRecord::getCurrentTime(bool Start) {
using Seconds = std::chrono::duration<double, std::ratio<1>>;
TimeRecord Result;
sys::TimePoint<> now;
std::chrono::nanoseconds user, sys;
if (Start) {
Result.MemUsed = getMemUsage();
sys::Process::GetTimeUsage(now, user, sys);
} else {
sys::Process::GetTimeUsage(now, user, sys);
Result.MemUsed = getMemUsage();
}
Result.WallTime = Seconds(now.time_since_epoch()).count();
Result.UserTime = Seconds(user).count();
Result.SystemTime = Seconds(sys).count();
return Result;
}
void Timer::startTimer() {
assert(!Running && "Cannot start a running timer");
Running = Triggered = true;
Annotate timeline in Instruments with passes and other timed regions. Summary: Instruments is a useful tool for finding performance issues in LLVM but it can be difficult to identify regions of interest on the timeline that we can use to filter the profiler or allocations instrument. Xcode 10 and the latest macOS/iOS/etc. added support for the os_signpost() API which allows us to annotate the timeline with information that's meaningful to LLVM. This patch causes timer start and end events to emit signposts. When used with -time-passes, this causes the passes to be annotated on the Instruments timeline. In addition to visually showing the duration of passes on the timeline, it also allows us to filter the profile and allocations instrument down to an individual pass allowing us to find the issues within that pass without being drowned out by the noise from other parts of the compiler. Using this in conjunction with the Time Profiler (in high frequency mode) and the Allocations instrument is how I found the SparseBitVector that should have been a BitVector and the DenseMap that could be replaced by a sorted vector a couple months ago. I added NamedRegionTimers to TableGen and used the resulting annotations to identify the slow portions of the Register Info Emitter. Some of these were placed according to educated guesses while others were placed according to hot functions from a previous profile. From there I filtered the profile to a slow portion and the aforementioned issues stood out in the profile. To use this feature enable LLVM_SUPPORT_XCODE_SIGNPOSTS in CMake and run the compiler under Instruments with -time-passes like so: instruments -t 'Time Profiler' bin/llc -time-passes -o - input.ll' Then open the resulting trace in Instruments. There was a talk at WWDC 2018 that explained the feature which can be found at https://developer.apple.com/videos/play/wwdc2018/405/ if you'd like to know more about it. Reviewers: bogner Reviewed By: bogner Subscribers: jdoerfert, mgorny, kristina, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D52954 llvm-svn: 354365
2019-02-20 02:18:31 +08:00
Signposts->startTimerInterval(this);
StartTime = TimeRecord::getCurrentTime(true);
}
void Timer::stopTimer() {
assert(Running && "Cannot stop a paused timer");
Running = false;
Time += TimeRecord::getCurrentTime(false);
Time -= StartTime;
Annotate timeline in Instruments with passes and other timed regions. Summary: Instruments is a useful tool for finding performance issues in LLVM but it can be difficult to identify regions of interest on the timeline that we can use to filter the profiler or allocations instrument. Xcode 10 and the latest macOS/iOS/etc. added support for the os_signpost() API which allows us to annotate the timeline with information that's meaningful to LLVM. This patch causes timer start and end events to emit signposts. When used with -time-passes, this causes the passes to be annotated on the Instruments timeline. In addition to visually showing the duration of passes on the timeline, it also allows us to filter the profile and allocations instrument down to an individual pass allowing us to find the issues within that pass without being drowned out by the noise from other parts of the compiler. Using this in conjunction with the Time Profiler (in high frequency mode) and the Allocations instrument is how I found the SparseBitVector that should have been a BitVector and the DenseMap that could be replaced by a sorted vector a couple months ago. I added NamedRegionTimers to TableGen and used the resulting annotations to identify the slow portions of the Register Info Emitter. Some of these were placed according to educated guesses while others were placed according to hot functions from a previous profile. From there I filtered the profile to a slow portion and the aforementioned issues stood out in the profile. To use this feature enable LLVM_SUPPORT_XCODE_SIGNPOSTS in CMake and run the compiler under Instruments with -time-passes like so: instruments -t 'Time Profiler' bin/llc -time-passes -o - input.ll' Then open the resulting trace in Instruments. There was a talk at WWDC 2018 that explained the feature which can be found at https://developer.apple.com/videos/play/wwdc2018/405/ if you'd like to know more about it. Reviewers: bogner Reviewed By: bogner Subscribers: jdoerfert, mgorny, kristina, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D52954 llvm-svn: 354365
2019-02-20 02:18:31 +08:00
Signposts->endTimerInterval(this);
}
void Timer::clear() {
Running = Triggered = false;
Time = StartTime = TimeRecord();
}
static void printVal(double Val, double Total, raw_ostream &OS) {
2010-03-30 04:40:19 +08:00
if (Total < 1e-7) // Avoid dividing by zero.
OS << " ----- ";
else
OS << format(" %7.4f (%5.1f%%)", Val, Val*100/Total);
}
void TimeRecord::print(const TimeRecord &Total, raw_ostream &OS) const {
if (Total.getUserTime())
printVal(getUserTime(), Total.getUserTime(), OS);
if (Total.getSystemTime())
printVal(getSystemTime(), Total.getSystemTime(), OS);
if (Total.getProcessTime())
printVal(getProcessTime(), Total.getProcessTime(), OS);
printVal(getWallTime(), Total.getWallTime(), OS);
OS << " ";
if (Total.getMemUsed())
OS << format("%9" PRId64 " ", (int64_t)getMemUsed());
}
//===----------------------------------------------------------------------===//
// NamedRegionTimer Implementation
//===----------------------------------------------------------------------===//
namespace {
typedef StringMap<Timer> Name2TimerMap;
class Name2PairMap {
StringMap<std::pair<TimerGroup*, Name2TimerMap> > Map;
public:
~Name2PairMap() {
for (StringMap<std::pair<TimerGroup*, Name2TimerMap> >::iterator
I = Map.begin(), E = Map.end(); I != E; ++I)
delete I->second.first;
}
Timer &get(StringRef Name, StringRef Description, StringRef GroupName,
StringRef GroupDescription) {
sys::SmartScopedLock<true> L(*TimerLock);
std::pair<TimerGroup*, Name2TimerMap> &GroupEntry = Map[GroupName];
if (!GroupEntry.first)
GroupEntry.first = new TimerGroup(GroupName, GroupDescription);
Timer &T = GroupEntry.second[Name];
if (!T.isInitialized())
T.init(Name, Description, *GroupEntry.first);
return T;
}
};
}
static ManagedStatic<Name2PairMap> NamedGroupedTimers;
NamedRegionTimer::NamedRegionTimer(StringRef Name, StringRef Description,
StringRef GroupName,
StringRef GroupDescription, bool Enabled)
: TimeRegion(!Enabled ? nullptr
: &NamedGroupedTimers->get(Name, Description, GroupName,
GroupDescription)) {}
//===----------------------------------------------------------------------===//
// TimerGroup Implementation
//===----------------------------------------------------------------------===//
/// This is the global list of TimerGroups, maintained by the TimerGroup
/// ctor/dtor and is protected by the TimerLock lock.
static TimerGroup *TimerGroupList = nullptr;
TimerGroup::TimerGroup(StringRef Name, StringRef Description)
: Name(Name.begin(), Name.end()),
Description(Description.begin(), Description.end()) {
// Add the group to TimerGroupList.
sys::SmartScopedLock<true> L(*TimerLock);
if (TimerGroupList)
TimerGroupList->Prev = &Next;
Next = TimerGroupList;
Prev = &TimerGroupList;
TimerGroupList = this;
}
TimerGroup::TimerGroup(StringRef Name, StringRef Description,
const StringMap<TimeRecord> &Records)
: TimerGroup(Name, Description) {
TimersToPrint.reserve(Records.size());
for (const auto &P : Records)
TimersToPrint.emplace_back(P.getValue(), std::string(P.getKey()),
std::string(P.getKey()));
assert(TimersToPrint.size() == Records.size() && "Size mismatch");
}
TimerGroup::~TimerGroup() {
// If the timer group is destroyed before the timers it owns, accumulate and
// print the timing data.
while (FirstTimer)
removeTimer(*FirstTimer);
// Remove the group from the TimerGroupList.
sys::SmartScopedLock<true> L(*TimerLock);
*Prev = Next;
if (Next)
Next->Prev = Prev;
}
void TimerGroup::removeTimer(Timer &T) {
sys::SmartScopedLock<true> L(*TimerLock);
// If the timer was started, move its data to TimersToPrint.
if (T.hasTriggered())
TimersToPrint.emplace_back(T.Time, T.Name, T.Description);
T.TG = nullptr;
// Unlink the timer from our list.
*T.Prev = T.Next;
if (T.Next)
T.Next->Prev = T.Prev;
// Print the report when all timers in this group are destroyed if some of
// them were started.
if (FirstTimer || TimersToPrint.empty())
return;
std::unique_ptr<raw_ostream> OutStream = CreateInfoOutputFile();
PrintQueuedTimers(*OutStream);
}
void TimerGroup::addTimer(Timer &T) {
sys::SmartScopedLock<true> L(*TimerLock);
// Add the timer to our list.
if (FirstTimer)
FirstTimer->Prev = &T.Next;
T.Next = FirstTimer;
T.Prev = &FirstTimer;
FirstTimer = &T;
}
void TimerGroup::PrintQueuedTimers(raw_ostream &OS) {
// Sort the timers in descending order by amount of time taken.
llvm::sort(TimersToPrint);
TimeRecord Total;
for (const PrintRecord &Record : TimersToPrint)
Total += Record.Time;
// Print out timing header.
OS << "===" << std::string(73, '-') << "===\n";
// Figure out how many spaces to indent TimerGroup name.
unsigned Padding = (80-Description.length())/2;
if (Padding > 80) Padding = 0; // Don't allow "negative" numbers
OS.indent(Padding) << Description << '\n';
OS << "===" << std::string(73, '-') << "===\n";
// If this is not an collection of ungrouped times, print the total time.
// Ungrouped timers don't really make sense to add up. We still print the
// TOTAL line to make the percentages make sense.
if (this != getDefaultTimerGroup())
OS << format(" Total Execution Time: %5.4f seconds (%5.4f wall clock)\n",
Total.getProcessTime(), Total.getWallTime());
OS << '\n';
if (Total.getUserTime())
OS << " ---User Time---";
if (Total.getSystemTime())
OS << " --System Time--";
if (Total.getProcessTime())
OS << " --User+System--";
OS << " ---Wall Time---";
if (Total.getMemUsed())
OS << " ---Mem---";
OS << " --- Name ---\n";
// Loop through all of the timing data, printing it out.
for (const PrintRecord &Record : make_range(TimersToPrint.rbegin(),
TimersToPrint.rend())) {
Record.Time.print(Total, OS);
OS << Record.Description << '\n';
}
Total.print(Total, OS);
OS << "Total\n\n";
OS.flush();
TimersToPrint.clear();
}
void TimerGroup::prepareToPrintList(bool ResetTime) {
// See if any of our timers were started, if so add them to TimersToPrint.
for (Timer *T = FirstTimer; T; T = T->Next) {
if (!T->hasTriggered()) continue;
bool WasRunning = T->isRunning();
if (WasRunning)
T->stopTimer();
TimersToPrint.emplace_back(T->Time, T->Name, T->Description);
if (ResetTime)
T->clear();
if (WasRunning)
T->startTimer();
}
}
void TimerGroup::print(raw_ostream &OS, bool ResetAfterPrint) {
{
// After preparing the timers we can free the lock
sys::SmartScopedLock<true> L(*TimerLock);
prepareToPrintList(ResetAfterPrint);
}
// If any timers were started, print the group.
if (!TimersToPrint.empty())
PrintQueuedTimers(OS);
}
void TimerGroup::clear() {
sys::SmartScopedLock<true> L(*TimerLock);
for (Timer *T = FirstTimer; T; T = T->Next)
T->clear();
}
void TimerGroup::printAll(raw_ostream &OS) {
sys::SmartScopedLock<true> L(*TimerLock);
for (TimerGroup *TG = TimerGroupList; TG; TG = TG->Next)
TG->print(OS);
}
void TimerGroup::clearAll() {
sys::SmartScopedLock<true> L(*TimerLock);
for (TimerGroup *TG = TimerGroupList; TG; TG = TG->Next)
TG->clear();
}
void TimerGroup::printJSONValue(raw_ostream &OS, const PrintRecord &R,
const char *suffix, double Value) {
assert(yaml::needsQuotes(Name) == yaml::QuotingType::None &&
"TimerGroup name should not need quotes");
assert(yaml::needsQuotes(R.Name) == yaml::QuotingType::None &&
"Timer name should not need quotes");
constexpr auto max_digits10 = std::numeric_limits<double>::max_digits10;
OS << "\t\"time." << Name << '.' << R.Name << suffix
<< "\": " << format("%.*e", max_digits10 - 1, Value);
}
const char *TimerGroup::printJSONValues(raw_ostream &OS, const char *delim) {
sys::SmartScopedLock<true> L(*TimerLock);
prepareToPrintList(false);
for (const PrintRecord &R : TimersToPrint) {
OS << delim;
delim = ",\n";
const TimeRecord &T = R.Time;
printJSONValue(OS, R, ".wall", T.getWallTime());
OS << delim;
printJSONValue(OS, R, ".user", T.getUserTime());
OS << delim;
printJSONValue(OS, R, ".sys", T.getSystemTime());
if (T.getMemUsed()) {
OS << delim;
printJSONValue(OS, R, ".mem", T.getMemUsed());
}
}
TimersToPrint.clear();
return delim;
}
const char *TimerGroup::printAllJSONValues(raw_ostream &OS, const char *delim) {
sys::SmartScopedLock<true> L(*TimerLock);
for (TimerGroup *TG = TimerGroupList; TG; TG = TG->Next)
delim = TG->printJSONValues(OS, delim);
return delim;
}
void TimerGroup::ConstructTimerLists() {
(void)*NamedGroupedTimers;
}