mlir/lib/Support/Timing.cpp - llvm-project - Git at Google

 //===- Timing.cpp - Execution time measurement facilities -----------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Facilities to measure and provide statistics on execution time.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Support/Timing.h"
 #include "mlir/Support/ThreadLocalCache.h"
 #include "llvm/ADT/MapVector.h"
 #include "llvm/ADT/Statistic.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/ADT/StringSet.h"
 #include "llvm/Support/Allocator.h"
 #include "llvm/Support/CommandLine.h"
 #include "llvm/Support/Format.h"
 #include "llvm/Support/FormatVariadic.h"
 #include "llvm/Support/ManagedStatic.h"
 #include "llvm/Support/RWMutex.h"
 #include "llvm/Support/Threading.h"
 #include "llvm/Support/raw_ostream.h"

 #include <atomic>
 #include <chrono>

 using namespace mlir;
 using namespace detail;
 using DisplayMode = DefaultTimingManager::DisplayMode;

 constexpr llvm::StringLiteral kTimingDescription =
     "... Execution time report ...";

 //===----------------------------------------------------------------------===//
 // TimingManager
 //===----------------------------------------------------------------------===//

 namespace mlir {
 namespace detail {
 /// Private implementation details of the `TimingManager`.
 class TimingManagerImpl {
 public:
   // Identifier allocator, map, and mutex for thread safety.
   llvm::BumpPtrAllocator identifierAllocator;
   llvm::StringSet<llvm::BumpPtrAllocator &> identifiers;
   llvm::sys::SmartRWMutex<true> identifierMutex;

   /// A thread local cache of identifiers to reduce lock contention.
   ThreadLocalCache<llvm::StringMap<llvm::StringMapEntry<llvm::NoneType> *>>
       localIdentifierCache;

   TimingManagerImpl() : identifiers(identifierAllocator) {}
 };
 } // namespace detail
 } // namespace mlir

 TimingManager::TimingManager() : impl(std::make_unique<TimingManagerImpl>()) {}

 TimingManager::~TimingManager() {}

 /// Get the root timer of this timing manager.
 Timer TimingManager::getRootTimer() {
   auto rt = rootTimer();
   return rt.hasValue() ? Timer(*this, rt.getValue()) : Timer();
 }

 /// Get the root timer of this timing manager wrapped in a `TimingScope`.
 TimingScope TimingManager::getRootScope() {
   return TimingScope(getRootTimer());
 }

 //===----------------------------------------------------------------------===//
 // Identifier uniquing
 //===----------------------------------------------------------------------===//

 /// Return an identifier for the specified string.
 TimingIdentifier TimingIdentifier::get(StringRef str, TimingManager &tm) {
   // Check for an existing instance in the local cache.
   auto &impl = *tm.impl;
   auto *&localEntry = (*impl.localIdentifierCache)[str];
   if (localEntry)
     return TimingIdentifier(localEntry);

   // Check for an existing identifier in read-only mode.
   {
     llvm::sys::SmartScopedReader<true> contextLock(impl.identifierMutex);
     auto it = impl.identifiers.find(str);
     if (it != impl.identifiers.end()) {
       localEntry = &*it;
       return TimingIdentifier(localEntry);
     }
   }

   // Acquire a writer-lock so that we can safely create the new instance.
   llvm::sys::SmartScopedWriter<true> contextLock(impl.identifierMutex);
   auto it = impl.identifiers.insert(str).first;
   localEntry = &*it;
   return TimingIdentifier(localEntry);
 }

 //===----------------------------------------------------------------------===//
 // Helpers for time record printing
 //===----------------------------------------------------------------------===//

 namespace {

 /// Simple record class to record timing information.
 struct TimeRecord {
   TimeRecord(double wall = 0.0, double user = 0.0) : wall(wall), user(user) {}

   TimeRecord &operator+=(const TimeRecord &other) {
     wall += other.wall;
     user += other.user;
     return *this;
   }

   TimeRecord &operator-=(const TimeRecord &other) {
     wall -= other.wall;
     user -= other.user;
     return *this;
   }

   /// Print the current time record to 'os', with a breakdown showing
   /// contributions to the give 'total' time record.
   void print(raw_ostream &os, const TimeRecord &total) {
     if (total.user != total.wall)
       os << llvm::format("  %8.4f (%5.1f%%)", user, 100.0 * user / total.user);
     os << llvm::format("  %8.4f (%5.1f%%)  ", wall, 100.0 * wall / total.wall);
   }

   double wall, user;
 };

 } // namespace

 /// Utility to print a single line entry in the timer output.
 static void printTimeEntry(raw_ostream &os, unsigned indent, StringRef name,
                            TimeRecord time, TimeRecord total) {
   time.print(os, total);
   os.indent(indent) << name << "\n";
 }

 /// Utility to print the timer heading information.
 static void printTimeHeader(raw_ostream &os, TimeRecord total) {
   // Figure out how many spaces to description name.
   unsigned padding = (80 - kTimingDescription.size()) / 2;
   os << "===" << std::string(73, '-') << "===\n";
   os.indent(padding) << kTimingDescription << '\n';
   os << "===" << std::string(73, '-') << "===\n";

   // Print the total time followed by the section headers.
   os << llvm::format("  Total Execution Time: %.4f seconds\n\n", total.wall);
   if (total.user != total.wall)
     os << "  ----User Time----";
   os << "  ----Wall Time----  ----Name----\n";
 }

 //===----------------------------------------------------------------------===//
 // Timer Implementation for DefaultTimingManager
 //===----------------------------------------------------------------------===//

 namespace {

 /// A timer used to sample execution time.
 ///
 /// Separately tracks wall time and user time to account for parallel threads of
 /// execution. Timers are intended to be started and stopped multiple times.
 /// Each start and stop will add to the timer's wall and user time.
 class TimerImpl {
 public:
   using ChildrenMap = llvm::MapVector<const void *, std::unique_ptr<TimerImpl>>;
   using AsyncChildrenMap = llvm::DenseMap<uint64_t, ChildrenMap>;

   TimerImpl(std::string &&name) : threadId(llvm::get_threadid()), name(name) {}

   /// Start the timer.
   void start() { startTime = std::chrono::steady_clock::now(); }

   /// Stop the timer.
   void stop() {
     auto newTime = std::chrono::steady_clock::now() - startTime;
     wallTime += newTime;
     userTime += newTime;
   }

   /// Create a child timer nested within this one. Multiple calls to this
   /// function with the same unique identifier `id` will return the same child
   /// timer.
   ///
   /// This function can be called from other threads, as long as this timer
   /// outlives any uses of the child timer on the other thread.
   TimerImpl *nest(const void *id, function_ref<std::string()> nameBuilder) {
     auto tid = llvm::get_threadid();
     if (tid == threadId)
       return nestTail(children[id], std::move(nameBuilder));
     std::unique_lock<std::mutex> lock(asyncMutex);
     return nestTail(asyncChildren[tid][id], std::move(nameBuilder));
   }

   /// Tail-called from `nest()`.
   TimerImpl *nestTail(std::unique_ptr<TimerImpl> &child,
                       function_ref<std::string()> nameBuilder) {
     if (!child)
       child = std::make_unique<TimerImpl>(nameBuilder());
     return child.get();
   }

   /// Finalize this timer and all its children.
   ///
   /// If this timer has async children, which happens if `nest()` was called
   /// from another thread, this function merges the async childr timers into the
   /// main list of child timers.
   ///
   /// Caution: Call this function only after all nested timers running on other
   /// threads no longer need their timers!
   void finalize() {
     addAsyncUserTime();
     mergeAsyncChildren();
   }

   /// Add the user time of all async children to this timer's user time. This is
   /// necessary since the user time already contains all regular child timers,
   /// but not the asynchronous ones (by the nesting nature of the timers).
   std::chrono::nanoseconds addAsyncUserTime() {
     auto added = std::chrono::nanoseconds(0);
     for (auto &child : children)
       added += child.second->addAsyncUserTime();
     for (auto &thread : asyncChildren) {
       for (auto &child : thread.second) {
         child.second->addAsyncUserTime();
         added += child.second->userTime;
       }
     }
     userTime += added;
     return added;
   }

   /// Ensure that this timer and recursively all its children have their async
   /// children folded into the main map of children.
   void mergeAsyncChildren() {
     for (auto &child : children)
       child.second->mergeAsyncChildren();
     mergeChildren(std::move(asyncChildren));
     assert(asyncChildren.empty());
   }

   /// Merge multiple child timers into this timer.
   ///
   /// Children in `other` are added as children to this timer, or, if this timer
   /// already contains a child with the corresponding unique identifier, are
   /// merged into the existing child.
   void mergeChildren(ChildrenMap &&other) {
     if (children.empty()) {
       children = std::move(other);
       for (auto &child : children)
         child.second->mergeAsyncChildren();
     } else {
       for (auto &child : other)
         mergeChild(child.first, std::move(child.second));
       other.clear();
     }
   }

   /// See above.
   void mergeChildren(AsyncChildrenMap &&other) {
     for (auto &thread : other) {
       mergeChildren(std::move(thread.second));
       assert(thread.second.empty());
     }
     other.clear();
   }

   /// Merge a child timer into this timer for a given unique identifier.
   ///
   /// Moves all child and async child timers of `other` into this timer's child
   /// for the given unique identifier.
   void mergeChild(const void *id, std::unique_ptr<TimerImpl> &&other) {
     auto &into = children[id];
     if (!into) {
       into = std::move(other);
       into->mergeAsyncChildren();
     } else {
       into->wallTime = std::max(into->wallTime, other->wallTime);
       into->userTime += other->userTime;
       into->mergeChildren(std::move(other->children));
       into->mergeChildren(std::move(other->asyncChildren));
       other.reset();
     }
   }

   /// Dump a human-readable tree representation of the timer and its children.
   /// This is useful for debugging the timing mechanisms and structure of the
   /// timers.
   void dump(raw_ostream &os, unsigned indent = 0, unsigned markThreadId = 0) {
     auto time = getTimeRecord();
     os << std::string(indent * 2, ' ') << name << " [" << threadId << "]"
        << llvm::format("  %7.4f / %7.4f", time.user, time.wall);
     if (threadId != markThreadId && markThreadId != 0)
       os << " (*)";
     os << "\n";
     for (auto &child : children)
       child.second->dump(os, indent + 1, threadId);
     for (auto &thread : asyncChildren)
       for (auto &child : thread.second)
         child.second->dump(os, indent + 1, threadId);
   }

   /// Returns the time for this timer in seconds.
   TimeRecord getTimeRecord() {
     return TimeRecord(
         std::chrono::duration_cast<std::chrono::duration<double>>(wallTime)
             .count(),
         std::chrono::duration_cast<std::chrono::duration<double>>(userTime)
             .count());
   }

   /// Print the timing result in list mode.
   void printAsList(raw_ostream &os, TimeRecord total) {
     // Flatten the leaf timers in the tree and merge them by name.
     llvm::StringMap<TimeRecord> mergedTimers;
     std::function<void(TimerImpl *)> addTimer = [&](TimerImpl *timer) {
       mergedTimers[timer->name] += timer->getTimeRecord();
       for (auto &children : timer->children)
         addTimer(children.second.get());
     };
     addTimer(this);

     // Sort the timing information by wall time.
     std::vector<std::pair<StringRef, TimeRecord>> timerNameAndTime;
     for (auto &it : mergedTimers)
       timerNameAndTime.emplace_back(it.first(), it.second);
     llvm::array_pod_sort(timerNameAndTime.begin(), timerNameAndTime.end(),
                          [](const std::pair<StringRef, TimeRecord> *lhs,
                             const std::pair<StringRef, TimeRecord> *rhs) {
                            return llvm::array_pod_sort_comparator<double>(
                                &rhs->second.wall, &lhs->second.wall);
                          });

     // Print the timing information sequentially.
     for (auto &timeData : timerNameAndTime)
       printTimeEntry(os, 0, timeData.first, timeData.second, total);
   }

   /// Print the timing result in tree mode.
   void printAsTree(raw_ostream &os, TimeRecord total, unsigned indent = 0) {
     unsigned childIndent = indent;
     if (!hidden) {
       printTimeEntry(os, indent, name, getTimeRecord(), total);
       childIndent += 2;
     }
     for (auto &child : children) {
       child.second->printAsTree(os, total, childIndent);
     }
   }

   /// Print the current timing information.
   void print(raw_ostream &os, DisplayMode displayMode) {
     // Print the banner.
     auto total = getTimeRecord();
     printTimeHeader(os, total);

     // Defer to a specialized printer for each display mode.
     switch (displayMode) {
     case DisplayMode::List:
       printAsList(os, total);
       break;
     case DisplayMode::Tree:
       printAsTree(os, total);
       break;
     }

     // Print the top-level time not accounted for by child timers, and the
     // total.
     auto rest = total;
     for (auto &child : children)
       rest -= child.second->getTimeRecord();
     printTimeEntry(os, 0, "Rest", rest, total);
     printTimeEntry(os, 0, "Total", total, total);
     os.flush();
   }

   /// The last time instant at which the timer was started.
   std::chrono::time_point<std::chrono::steady_clock> startTime;

   /// Accumulated wall time. If multiple threads of execution are merged into
   /// this timer, the wall time will hold the maximum wall time of each thread
   /// of execution.
   std::chrono::nanoseconds wallTime = std::chrono::nanoseconds(0);

   /// Accumulated user time. If multiple threads of execution are merged into
   /// this timer, each thread's user time is added here.
   std::chrono::nanoseconds userTime = std::chrono::nanoseconds(0);

   /// The thread on which this timer is running.
   uint64_t threadId;

   /// A descriptive name for this timer.
   std::string name;

   /// Whether to omit this timer from reports and directly show its children.
   bool hidden = false;

   /// Child timers on the same thread the timer itself. We keep at most one
   /// timer per unique identifier.
   ChildrenMap children;

   /// Child timers on other threads. We keep at most one timer per unique
   /// identifier.
   AsyncChildrenMap asyncChildren;

   /// Mutex for the async children.
   std::mutex asyncMutex;
 };

 } // namespace

 //===----------------------------------------------------------------------===//
 // DefaultTimingManager
 //===----------------------------------------------------------------------===//

 namespace mlir {
 namespace detail {

 /// Implementation details of the `DefaultTimingManager`.
 class DefaultTimingManagerImpl {
 public:
   /// Whether we should do our work or not.
   bool enabled = false;

   /// The configured display mode.
   DisplayMode displayMode = DisplayMode::Tree;

   /// The stream where we should print our output. This will always be non-null.
   raw_ostream *output = &llvm::errs();

   /// The root timer.
   std::unique_ptr<TimerImpl> rootTimer;
 };

 } // namespace detail
 } // namespace mlir

 DefaultTimingManager::DefaultTimingManager()
     : impl(std::make_unique<DefaultTimingManagerImpl>()) {
   clear(); // initializes the root timer
 }

 DefaultTimingManager::~DefaultTimingManager() { print(); }

 /// Enable or disable execution time sampling.
 void DefaultTimingManager::setEnabled(bool enabled) { impl->enabled = enabled; }

 /// Return whether execution time sampling is enabled.
 bool DefaultTimingManager::isEnabled() const { return impl->enabled; }

 /// Change the display mode.
 void DefaultTimingManager::setDisplayMode(DisplayMode displayMode) {
   impl->displayMode = displayMode;
 }

 /// Return the current display mode;
 DefaultTimingManager::DisplayMode DefaultTimingManager::getDisplayMode() const {
   return impl->displayMode;
 }

 /// Change the stream where the output will be printed to.
 void DefaultTimingManager::setOutput(raw_ostream &os) { impl->output = &os; }

 /// Return the current output stream where the output will be printed to.
 raw_ostream &DefaultTimingManager::getOutput() const {
   assert(impl->output);
   return *impl->output;
 }

 /// Print and clear the timing results.
 void DefaultTimingManager::print() {
   if (impl->enabled) {
     impl->rootTimer->finalize();
     impl->rootTimer->print(*impl->output, impl->displayMode);
   }
   clear();
 }

 /// Clear the timing results.
 void DefaultTimingManager::clear() {
   impl->rootTimer = std::make_unique<TimerImpl>("root");
   impl->rootTimer->hidden = true;
 }

 /// Debug print the timer data structures to an output stream.
 void DefaultTimingManager::dumpTimers(raw_ostream &os) {
   impl->rootTimer->dump(os);
 }

 /// Debug print the timers as a list.
 void DefaultTimingManager::dumpAsList(raw_ostream &os) {
   impl->rootTimer->finalize();
   impl->rootTimer->print(os, DisplayMode::List);
 }

 /// Debug print the timers as a tree.
 void DefaultTimingManager::dumpAsTree(raw_ostream &os) {
   impl->rootTimer->finalize();
   impl->rootTimer->print(os, DisplayMode::Tree);
 }

 Optional<void *> DefaultTimingManager::rootTimer() {
   if (impl->enabled)
     return impl->rootTimer.get();
   return llvm::None;
 }

 void DefaultTimingManager::startTimer(void *handle) {
   static_cast<TimerImpl *>(handle)->start();
 }

 void DefaultTimingManager::stopTimer(void *handle) {
   static_cast<TimerImpl *>(handle)->stop();
 }

 void *DefaultTimingManager::nestTimer(void *handle, const void *id,
                                       function_ref<std::string()> nameBuilder) {
   return static_cast<TimerImpl *>(handle)->nest(id, std::move(nameBuilder));
 }

 void DefaultTimingManager::hideTimer(void *handle) {
   static_cast<TimerImpl *>(handle)->hidden = true;
 }

 //===----------------------------------------------------------------------===//
 // DefaultTimingManager Command Line Options
 //===----------------------------------------------------------------------===//

 namespace {
 struct DefaultTimingManagerOptions {
   llvm::cl::opt<bool> timing{"mlir-timing",
                              llvm::cl::desc("Display execution times"),
                              llvm::cl::init(false)};
   llvm::cl::opt<DisplayMode> displayMode{
       "mlir-timing-display", llvm::cl::desc("Display method for timing data"),
       llvm::cl::init(DisplayMode::Tree),
       llvm::cl::values(
           clEnumValN(DisplayMode::List, "list",
                      "display the results in a list sorted by total time"),
           clEnumValN(DisplayMode::Tree, "tree",
                      "display the results ina with a nested tree view"))};
 };
 } // end anonymous namespace

 static llvm::ManagedStatic<DefaultTimingManagerOptions> options;

 void mlir::registerDefaultTimingManagerCLOptions() {
   // Make sure that the options struct has been constructed.
   *options;
 }

 void mlir::applyDefaultTimingManagerCLOptions(DefaultTimingManager &tm) {
   if (!options.isConstructed())
     return;
   tm.setEnabled(options->timing);
   tm.setDisplayMode(options->displayMode);
 }
	//===- Timing.cpp - Execution time measurement facilities -----------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Facilities to measure and provide statistics on execution time.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Support/Timing.h"
	#include "mlir/Support/ThreadLocalCache.h"
	#include "llvm/ADT/MapVector.h"
	#include "llvm/ADT/Statistic.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/ADT/StringSet.h"
	#include "llvm/Support/Allocator.h"
	#include "llvm/Support/CommandLine.h"
	#include "llvm/Support/Format.h"
	#include "llvm/Support/FormatVariadic.h"
	#include "llvm/Support/ManagedStatic.h"
	#include "llvm/Support/RWMutex.h"
	#include "llvm/Support/Threading.h"
	#include "llvm/Support/raw_ostream.h"

	#include <atomic>
	#include <chrono>

	using namespace mlir;
	using namespace detail;
	using DisplayMode = DefaultTimingManager::DisplayMode;

	constexpr llvm::StringLiteral kTimingDescription =
	"... Execution time report ...";

	//===----------------------------------------------------------------------===//
	// TimingManager
	//===----------------------------------------------------------------------===//

	namespace mlir {
	namespace detail {
	/// Private implementation details of the `TimingManager`.
	class TimingManagerImpl {
	public:
	// Identifier allocator, map, and mutex for thread safety.
	llvm::BumpPtrAllocator identifierAllocator;
	llvm::StringSet<llvm::BumpPtrAllocator &> identifiers;
	llvm::sys::SmartRWMutex<true> identifierMutex;

	/// A thread local cache of identifiers to reduce lock contention.
	ThreadLocalCache<llvm::StringMap<llvm::StringMapEntry<llvm::NoneType> *>>
	localIdentifierCache;

	TimingManagerImpl() : identifiers(identifierAllocator) {}
	};
	} // namespace detail
	} // namespace mlir

	TimingManager::TimingManager() : impl(std::make_unique<TimingManagerImpl>()) {}

	TimingManager::~TimingManager() {}

	/// Get the root timer of this timing manager.
	Timer TimingManager::getRootTimer() {
	auto rt = rootTimer();
	return rt.hasValue() ? Timer(*this, rt.getValue()) : Timer();
	}

	/// Get the root timer of this timing manager wrapped in a `TimingScope`.
	TimingScope TimingManager::getRootScope() {
	return TimingScope(getRootTimer());
	}

	//===----------------------------------------------------------------------===//
	// Identifier uniquing
	//===----------------------------------------------------------------------===//

	/// Return an identifier for the specified string.
	TimingIdentifier TimingIdentifier::get(StringRef str, TimingManager &tm) {
	// Check for an existing instance in the local cache.
	auto &impl = *tm.impl;
	auto &localEntry = (impl.localIdentifierCache)[str];
	if (localEntry)
	return TimingIdentifier(localEntry);

	// Check for an existing identifier in read-only mode.
	{
	llvm::sys::SmartScopedReader<true> contextLock(impl.identifierMutex);
	auto it = impl.identifiers.find(str);
	if (it != impl.identifiers.end()) {
	localEntry = &*it;
	return TimingIdentifier(localEntry);
	}
	}

	// Acquire a writer-lock so that we can safely create the new instance.
	llvm::sys::SmartScopedWriter<true> contextLock(impl.identifierMutex);
	auto it = impl.identifiers.insert(str).first;
	localEntry = &*it;
	return TimingIdentifier(localEntry);
	}

	//===----------------------------------------------------------------------===//
	// Helpers for time record printing
	//===----------------------------------------------------------------------===//

	namespace {

	/// Simple record class to record timing information.
	struct TimeRecord {
	TimeRecord(double wall = 0.0, double user = 0.0) : wall(wall), user(user) {}

	TimeRecord &operator+=(const TimeRecord &other) {
	wall += other.wall;
	user += other.user;
	return *this;
	}

	TimeRecord &operator-=(const TimeRecord &other) {
	wall -= other.wall;
	user -= other.user;
	return *this;
	}

	/// Print the current time record to 'os', with a breakdown showing
	/// contributions to the give 'total' time record.
	void print(raw_ostream &os, const TimeRecord &total) {
	if (total.user != total.wall)
	os << llvm::format(" %8.4f (%5.1f%%)", user, 100.0 * user / total.user);
	os << llvm::format(" %8.4f (%5.1f%%) ", wall, 100.0 * wall / total.wall);
	}

	double wall, user;
	};

	} // namespace

	/// Utility to print a single line entry in the timer output.
	static void printTimeEntry(raw_ostream &os, unsigned indent, StringRef name,
	TimeRecord time, TimeRecord total) {
	time.print(os, total);
	os.indent(indent) << name << "\n";
	}

	/// Utility to print the timer heading information.
	static void printTimeHeader(raw_ostream &os, TimeRecord total) {
	// Figure out how many spaces to description name.
	unsigned padding = (80 - kTimingDescription.size()) / 2;
	os << "===" << std::string(73, '-') << "===\n";
	os.indent(padding) << kTimingDescription << '\n';
	os << "===" << std::string(73, '-') << "===\n";

	// Print the total time followed by the section headers.
	os << llvm::format(" Total Execution Time: %.4f seconds\n\n", total.wall);
	if (total.user != total.wall)
	os << " ----User Time----";
	os << " ----Wall Time---- ----Name----\n";
	}

	//===----------------------------------------------------------------------===//
	// Timer Implementation for DefaultTimingManager
	//===----------------------------------------------------------------------===//

	namespace {

	/// A timer used to sample execution time.
	///
	/// Separately tracks wall time and user time to account for parallel threads of
	/// execution. Timers are intended to be started and stopped multiple times.
	/// Each start and stop will add to the timer's wall and user time.
	class TimerImpl {
	public:
	using ChildrenMap = llvm::MapVector<const void *, std::unique_ptr<TimerImpl>>;
	using AsyncChildrenMap = llvm::DenseMap<uint64_t, ChildrenMap>;

	TimerImpl(std::string &&name) : threadId(llvm::get_threadid()), name(name) {}

	/// Start the timer.
	void start() { startTime = std::chrono::steady_clock::now(); }

	/// Stop the timer.
	void stop() {
	auto newTime = std::chrono::steady_clock::now() - startTime;
	wallTime += newTime;
	userTime += newTime;
	}

	/// Create a child timer nested within this one. Multiple calls to this
	/// function with the same unique identifier `id` will return the same child
	/// timer.
	///
	/// This function can be called from other threads, as long as this timer
	/// outlives any uses of the child timer on the other thread.
	TimerImpl nest(const void id, function_ref<std::string()> nameBuilder) {
	auto tid = llvm::get_threadid();
	if (tid == threadId)
	return nestTail(children[id], std::move(nameBuilder));
	std::unique_lock<std::mutex> lock(asyncMutex);
	return nestTail(asyncChildren[tid][id], std::move(nameBuilder));
	}

	/// Tail-called from `nest()`.
	TimerImpl *nestTail(std::unique_ptr<TimerImpl> &child,
	function_ref<std::string()> nameBuilder) {
	if (!child)
	child = std::make_unique<TimerImpl>(nameBuilder());
	return child.get();
	}

	/// Finalize this timer and all its children.
	///
	/// If this timer has async children, which happens if `nest()` was called
	/// from another thread, this function merges the async childr timers into the
	/// main list of child timers.
	///
	/// Caution: Call this function only after all nested timers running on other
	/// threads no longer need their timers!
	void finalize() {
	addAsyncUserTime();
	mergeAsyncChildren();
	}

	/// Add the user time of all async children to this timer's user time. This is
	/// necessary since the user time already contains all regular child timers,
	/// but not the asynchronous ones (by the nesting nature of the timers).
	std::chrono::nanoseconds addAsyncUserTime() {
	auto added = std::chrono::nanoseconds(0);
	for (auto &child : children)
	added += child.second->addAsyncUserTime();
	for (auto &thread : asyncChildren) {
	for (auto &child : thread.second) {
	child.second->addAsyncUserTime();
	added += child.second->userTime;
	}
	}
	userTime += added;
	return added;
	}

	/// Ensure that this timer and recursively all its children have their async
	/// children folded into the main map of children.
	void mergeAsyncChildren() {
	for (auto &child : children)
	child.second->mergeAsyncChildren();
	mergeChildren(std::move(asyncChildren));
	assert(asyncChildren.empty());
	}

	/// Merge multiple child timers into this timer.
	///
	/// Children in `other` are added as children to this timer, or, if this timer
	/// already contains a child with the corresponding unique identifier, are
	/// merged into the existing child.
	void mergeChildren(ChildrenMap &&other) {
	if (children.empty()) {
	children = std::move(other);
	for (auto &child : children)
	child.second->mergeAsyncChildren();
	} else {
	for (auto &child : other)
	mergeChild(child.first, std::move(child.second));
	other.clear();
	}
	}

	/// See above.
	void mergeChildren(AsyncChildrenMap &&other) {
	for (auto &thread : other) {
	mergeChildren(std::move(thread.second));
	assert(thread.second.empty());
	}
	other.clear();
	}

	/// Merge a child timer into this timer for a given unique identifier.
	///
	/// Moves all child and async child timers of `other` into this timer's child
	/// for the given unique identifier.
	void mergeChild(const void *id, std::unique_ptr<TimerImpl> &&other) {
	auto &into = children[id];
	if (!into) {
	into = std::move(other);
	into->mergeAsyncChildren();
	} else {
	into->wallTime = std::max(into->wallTime, other->wallTime);
	into->userTime += other->userTime;
	into->mergeChildren(std::move(other->children));
	into->mergeChildren(std::move(other->asyncChildren));
	other.reset();
	}
	}

	/// Dump a human-readable tree representation of the timer and its children.
	/// This is useful for debugging the timing mechanisms and structure of the
	/// timers.
	void dump(raw_ostream &os, unsigned indent = 0, unsigned markThreadId = 0) {
	auto time = getTimeRecord();
	os << std::string(indent * 2, ' ') << name << " [" << threadId << "]"
	<< llvm::format(" %7.4f / %7.4f", time.user, time.wall);
	if (threadId != markThreadId && markThreadId != 0)
	os << " (*)";
	os << "\n";
	for (auto &child : children)
	child.second->dump(os, indent + 1, threadId);
	for (auto &thread : asyncChildren)
	for (auto &child : thread.second)
	child.second->dump(os, indent + 1, threadId);
	}

	/// Returns the time for this timer in seconds.
	TimeRecord getTimeRecord() {
	return TimeRecord(
	std::chrono::duration_cast<std::chrono::duration<double>>(wallTime)
	.count(),
	std::chrono::duration_cast<std::chrono::duration<double>>(userTime)
	.count());
	}

	/// Print the timing result in list mode.
	void printAsList(raw_ostream &os, TimeRecord total) {
	// Flatten the leaf timers in the tree and merge them by name.
	llvm::StringMap<TimeRecord> mergedTimers;
	std::function<void(TimerImpl )> addTimer = [&](TimerImpl timer) {
	mergedTimers[timer->name] += timer->getTimeRecord();
	for (auto &children : timer->children)
	addTimer(children.second.get());
	};
	addTimer(this);

	// Sort the timing information by wall time.
	std::vector<std::pair<StringRef, TimeRecord>> timerNameAndTime;
	for (auto &it : mergedTimers)
	timerNameAndTime.emplace_back(it.first(), it.second);
	llvm::array_pod_sort(timerNameAndTime.begin(), timerNameAndTime.end(),
	[](const std::pair<StringRef, TimeRecord> *lhs,
	const std::pair<StringRef, TimeRecord> *rhs) {
	return llvm::array_pod_sort_comparator<double>(
	&rhs->second.wall, &lhs->second.wall);
	});

	// Print the timing information sequentially.
	for (auto &timeData : timerNameAndTime)
	printTimeEntry(os, 0, timeData.first, timeData.second, total);
	}

	/// Print the timing result in tree mode.
	void printAsTree(raw_ostream &os, TimeRecord total, unsigned indent = 0) {
	unsigned childIndent = indent;
	if (!hidden) {
	printTimeEntry(os, indent, name, getTimeRecord(), total);
	childIndent += 2;
	}
	for (auto &child : children) {
	child.second->printAsTree(os, total, childIndent);
	}
	}

	/// Print the current timing information.
	void print(raw_ostream &os, DisplayMode displayMode) {
	// Print the banner.
	auto total = getTimeRecord();
	printTimeHeader(os, total);

	// Defer to a specialized printer for each display mode.
	switch (displayMode) {
	case DisplayMode::List:
	printAsList(os, total);
	break;
	case DisplayMode::Tree:
	printAsTree(os, total);
	break;
	}

	// Print the top-level time not accounted for by child timers, and the
	// total.
	auto rest = total;
	for (auto &child : children)
	rest -= child.second->getTimeRecord();
	printTimeEntry(os, 0, "Rest", rest, total);
	printTimeEntry(os, 0, "Total", total, total);
	os.flush();
	}

	/// The last time instant at which the timer was started.
	std::chrono::time_point<std::chrono::steady_clock> startTime;

	/// Accumulated wall time. If multiple threads of execution are merged into
	/// this timer, the wall time will hold the maximum wall time of each thread
	/// of execution.
	std::chrono::nanoseconds wallTime = std::chrono::nanoseconds(0);

	/// Accumulated user time. If multiple threads of execution are merged into
	/// this timer, each thread's user time is added here.
	std::chrono::nanoseconds userTime = std::chrono::nanoseconds(0);

	/// The thread on which this timer is running.
	uint64_t threadId;

	/// A descriptive name for this timer.
	std::string name;

	/// Whether to omit this timer from reports and directly show its children.
	bool hidden = false;

	/// Child timers on the same thread the timer itself. We keep at most one
	/// timer per unique identifier.
	ChildrenMap children;

	/// Child timers on other threads. We keep at most one timer per unique
	/// identifier.
	AsyncChildrenMap asyncChildren;

	/// Mutex for the async children.
	std::mutex asyncMutex;
	};

	} // namespace

	//===----------------------------------------------------------------------===//
	// DefaultTimingManager
	//===----------------------------------------------------------------------===//

	namespace mlir {
	namespace detail {

	/// Implementation details of the `DefaultTimingManager`.
	class DefaultTimingManagerImpl {
	public:
	/// Whether we should do our work or not.
	bool enabled = false;

	/// The configured display mode.
	DisplayMode displayMode = DisplayMode::Tree;

	/// The stream where we should print our output. This will always be non-null.
	raw_ostream *output = &llvm::errs();

	/// The root timer.
	std::unique_ptr<TimerImpl> rootTimer;
	};

	} // namespace detail
	} // namespace mlir

	DefaultTimingManager::DefaultTimingManager()
	: impl(std::make_unique<DefaultTimingManagerImpl>()) {
	clear(); // initializes the root timer
	}

	DefaultTimingManager::~DefaultTimingManager() { print(); }

	/// Enable or disable execution time sampling.
	void DefaultTimingManager::setEnabled(bool enabled) { impl->enabled = enabled; }

	/// Return whether execution time sampling is enabled.
	bool DefaultTimingManager::isEnabled() const { return impl->enabled; }

	/// Change the display mode.
	void DefaultTimingManager::setDisplayMode(DisplayMode displayMode) {
	impl->displayMode = displayMode;
	}

	/// Return the current display mode;
	DefaultTimingManager::DisplayMode DefaultTimingManager::getDisplayMode() const {
	return impl->displayMode;
	}

	/// Change the stream where the output will be printed to.
	void DefaultTimingManager::setOutput(raw_ostream &os) { impl->output = &os; }

	/// Return the current output stream where the output will be printed to.
	raw_ostream &DefaultTimingManager::getOutput() const {
	assert(impl->output);
	return *impl->output;
	}

	/// Print and clear the timing results.
	void DefaultTimingManager::print() {
	if (impl->enabled) {
	impl->rootTimer->finalize();
	impl->rootTimer->print(*impl->output, impl->displayMode);
	}
	clear();
	}

	/// Clear the timing results.
	void DefaultTimingManager::clear() {
	impl->rootTimer = std::make_unique<TimerImpl>("root");
	impl->rootTimer->hidden = true;
	}

	/// Debug print the timer data structures to an output stream.
	void DefaultTimingManager::dumpTimers(raw_ostream &os) {
	impl->rootTimer->dump(os);
	}

	/// Debug print the timers as a list.
	void DefaultTimingManager::dumpAsList(raw_ostream &os) {
	impl->rootTimer->finalize();
	impl->rootTimer->print(os, DisplayMode::List);
	}

	/// Debug print the timers as a tree.
	void DefaultTimingManager::dumpAsTree(raw_ostream &os) {
	impl->rootTimer->finalize();
	impl->rootTimer->print(os, DisplayMode::Tree);
	}

	Optional<void *> DefaultTimingManager::rootTimer() {
	if (impl->enabled)
	return impl->rootTimer.get();
	return llvm::None;
	}

	void DefaultTimingManager::startTimer(void *handle) {
	static_cast<TimerImpl *>(handle)->start();
	}

	void DefaultTimingManager::stopTimer(void *handle) {
	static_cast<TimerImpl *>(handle)->stop();
	}

	void DefaultTimingManager::nestTimer(void handle, const void *id,
	function_ref<std::string()> nameBuilder) {
	return static_cast<TimerImpl *>(handle)->nest(id, std::move(nameBuilder));
	}

	void DefaultTimingManager::hideTimer(void *handle) {
	static_cast<TimerImpl *>(handle)->hidden = true;
	}

	//===----------------------------------------------------------------------===//
	// DefaultTimingManager Command Line Options
	//===----------------------------------------------------------------------===//

	namespace {
	struct DefaultTimingManagerOptions {
	llvm::cl::opt<bool> timing{"mlir-timing",
	llvm::cl::desc("Display execution times"),
	llvm::cl::init(false)};
	llvm::cl::opt<DisplayMode> displayMode{
	"mlir-timing-display", llvm::cl::desc("Display method for timing data"),
	llvm::cl::init(DisplayMode::Tree),
	llvm::cl::values(
	clEnumValN(DisplayMode::List, "list",
	"display the results in a list sorted by total time"),
	clEnumValN(DisplayMode::Tree, "tree",
	"display the results ina with a nested tree view"))};
	};
	} // end anonymous namespace

	static llvm::ManagedStatic<DefaultTimingManagerOptions> options;

	void mlir::registerDefaultTimingManagerCLOptions() {
	// Make sure that the options struct has been constructed.
	*options;
	}

	void mlir::applyDefaultTimingManagerCLOptions(DefaultTimingManager &tm) {
	if (!options.isConstructed())
	return;
	tm.setEnabled(options->timing);
	tm.setDisplayMode(options->displayMode);
	}