lldb/source/Core/Timer.cpp - llvm-project - Git at Google

 //===-- Timer.cpp -----------------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 #include "lldb/Core/Timer.h"

 #include <map>
 #include <vector>
 #include <algorithm>

 #include "lldb/Core/Stream.h"
 #include "lldb/Host/Mutex.h"

 #include <stdio.h>

 using namespace lldb_private;

 #define TIMER_INDENT_AMOUNT 2
 static bool g_quiet = true;
 uint32_t Timer::g_depth = 0;
 uint32_t Timer::g_display_depth = 0;
 FILE * Timer::g_file = NULL;
 typedef std::vector<Timer *> TimerStack;
 typedef std::map<const char *, uint64_t> CategoryMap;
 static pthread_key_t g_key;

 static Mutex &
 GetCategoryMutex()
 {
     static Mutex g_category_mutex(Mutex::eMutexTypeNormal);
     return g_category_mutex;
 }

 static CategoryMap &
 GetCategoryMap()
 {
     static CategoryMap g_category_map;
     return g_category_map;
 }


 static TimerStack *
 GetTimerStackForCurrentThread ()
 {
     void *timer_stack = ::pthread_getspecific (g_key);
     if (timer_stack == NULL)
     {
         ::pthread_setspecific (g_key, new TimerStack);
         timer_stack = ::pthread_getspecific (g_key);
     }
     return (TimerStack *)timer_stack;
 }

 void
 ThreadSpecificCleanup (void *p)
 {
     delete (TimerStack *)p;
 }

 void
 Timer::SetQuiet (bool value)
 {
     g_quiet = value;
 }

 void
 Timer::Initialize ()
 {
     Timer::g_file = stdout;
     ::pthread_key_create (&g_key, ThreadSpecificCleanup);

 }

 Timer::Timer (const char *category, const char *format, ...) :
     m_category (category),
     m_total_start (),
     m_timer_start (),
     m_total_ticks (0),
     m_timer_ticks (0)
 {
     if (g_depth++ < g_display_depth)
     {
         if (g_quiet == false)
         {
             // Indent
             ::fprintf (g_file, "%*s", g_depth * TIMER_INDENT_AMOUNT, "");
             // Print formatted string
             va_list args;
             va_start (args, format);
             ::vfprintf (g_file, format, args);
             va_end (args);

             // Newline
             ::fprintf (g_file, "\n");
         }
         TimeValue start_time(TimeValue::Now());
         m_total_start = start_time;
         m_timer_start = start_time;
         TimerStack *stack = GetTimerStackForCurrentThread ();
         if (stack)
         {
             if (stack->empty() == false)
                 stack->back()->ChildStarted (start_time);
             stack->push_back(this);
         }
     }
 }


 Timer::~Timer()
 {
     if (m_total_start.IsValid())
     {
         TimeValue stop_time = TimeValue::Now();
         bool notify = false;
         if (m_total_start.IsValid())
         {
             m_total_ticks += (stop_time - m_total_start);
             m_total_start.Clear();
             notify = true;
         }
         if (m_timer_start.IsValid())
         {
             m_timer_ticks += (stop_time - m_timer_start);
             m_timer_start.Clear();
         }

         TimerStack *stack = GetTimerStackForCurrentThread ();
         if (stack)
         {
             assert (stack->back() == this);
             stack->pop_back();
             if (stack->empty() == false)
                 stack->back()->ChildStopped(stop_time);
         }

         const uint64_t total_nsec_uint = GetTotalElapsedNanoSeconds();
         const uint64_t timer_nsec_uint = GetTimerElapsedNanoSeconds();
         const double total_nsec = total_nsec_uint;
         const double timer_nsec = timer_nsec_uint;

         if (g_quiet == false)
         {

             ::fprintf (g_file,
                        "%*s%.9f sec (%.9f sec)\n",
                        (g_depth - 1) *TIMER_INDENT_AMOUNT, "",
                        total_nsec / 1000000000.0,
                        timer_nsec / 1000000000.0);
         }

         // Keep total results for each category so we can dump results.
         Mutex::Locker locker (GetCategoryMutex());
         CategoryMap &category_map = GetCategoryMap();
         category_map[m_category] += timer_nsec_uint;
     }
     if (g_depth > 0)
         --g_depth;
 }

 uint64_t
 Timer::GetTotalElapsedNanoSeconds()
 {
     uint64_t total_ticks = m_total_ticks;

     // If we are currently running, we need to add the current
     // elapsed time of the running timer...
     if (m_total_start.IsValid())
         total_ticks += (TimeValue::Now() - m_total_start);

     return total_ticks;
 }

 uint64_t
 Timer::GetTimerElapsedNanoSeconds()
 {
     uint64_t timer_ticks = m_timer_ticks;

     // If we are currently running, we need to add the current
     // elapsed time of the running timer...
     if (m_timer_start.IsValid())
         timer_ticks += (TimeValue::Now() - m_timer_start);

     return timer_ticks;
 }

 void
 Timer::ChildStarted (const TimeValue& start_time)
 {
     if (m_timer_start.IsValid())
     {
         m_timer_ticks += (start_time - m_timer_start);
         m_timer_start.Clear();
     }
 }

 void
 Timer::ChildStopped (const TimeValue& stop_time)
 {
     if (!m_timer_start.IsValid())
         m_timer_start = stop_time;
 }

 void
 Timer::SetDisplayDepth (uint32_t depth)
 {
     g_display_depth = depth;
 }


 /* binary function predicate:
  * - returns whether a person is less than another person
  */
 static bool
 CategoryMapIteratorSortCriterion (const CategoryMap::const_iterator& lhs, const CategoryMap::const_iterator& rhs)
 {
     return lhs->second > rhs->second;
 }


 void
 Timer::ResetCategoryTimes ()
 {
     Mutex::Locker locker (GetCategoryMutex());
     CategoryMap &category_map = GetCategoryMap();
     category_map.clear();
 }

 void
 Timer::DumpCategoryTimes (Stream *s)
 {
     Mutex::Locker locker (GetCategoryMutex());
     CategoryMap &category_map = GetCategoryMap();
     std::vector<CategoryMap::const_iterator> sorted_iterators;
     CategoryMap::const_iterator pos, end = category_map.end();
     for (pos = category_map.begin(); pos != end; ++pos)
     {
         sorted_iterators.push_back (pos);
     }
     std::sort (sorted_iterators.begin(), sorted_iterators.end(), CategoryMapIteratorSortCriterion);

     const size_t count = sorted_iterators.size();
     for (size_t i=0; i<count; ++i)
     {
         const double timer_nsec = sorted_iterators[i]->second;
         s->Printf("%.9f sec for %s\n", timer_nsec / 1000000000.0, sorted_iterators[i]->first);
     }
 }
	//===-- Timer.cpp ------------------------------------------------ C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	#include "lldb/Core/Timer.h"

	#include <map>
	#include <vector>
	#include <algorithm>

	#include "lldb/Core/Stream.h"
	#include "lldb/Host/Mutex.h"

	#include <stdio.h>

	using namespace lldb_private;

	#define TIMER_INDENT_AMOUNT 2
	static bool g_quiet = true;
	uint32_t Timer::g_depth = 0;
	uint32_t Timer::g_display_depth = 0;
	FILE * Timer::g_file = NULL;
	typedef std::vector<Timer *> TimerStack;
	typedef std::map<const char *, uint64_t> CategoryMap;
	static pthread_key_t g_key;

	static Mutex &
	GetCategoryMutex()
	{
	static Mutex g_category_mutex(Mutex::eMutexTypeNormal);
	return g_category_mutex;
	}

	static CategoryMap &
	GetCategoryMap()
	{
	static CategoryMap g_category_map;
	return g_category_map;
	}


	static TimerStack *
	GetTimerStackForCurrentThread ()
	{
	void *timer_stack = ::pthread_getspecific (g_key);
	if (timer_stack == NULL)
	{
	::pthread_setspecific (g_key, new TimerStack);
	timer_stack = ::pthread_getspecific (g_key);
	}
	return (TimerStack *)timer_stack;
	}

	void
	ThreadSpecificCleanup (void *p)
	{
	delete (TimerStack *)p;
	}

	void
	Timer::SetQuiet (bool value)
	{
	g_quiet = value;
	}

	void
	Timer::Initialize ()
	{
	Timer::g_file = stdout;
	::pthread_key_create (&g_key, ThreadSpecificCleanup);

	}

	Timer::Timer (const char category, const char format, ...) :
	m_category (category),
	m_total_start (),
	m_timer_start (),
	m_total_ticks (0),
	m_timer_ticks (0)
	{
	if (g_depth++ < g_display_depth)
	{
	if (g_quiet == false)
	{
	// Indent
	::fprintf (g_file, "%s", g_depth TIMER_INDENT_AMOUNT, "");
	// Print formatted string
	va_list args;
	va_start (args, format);
	::vfprintf (g_file, format, args);
	va_end (args);

	// Newline
	::fprintf (g_file, "\n");
	}
	TimeValue start_time(TimeValue::Now());
	m_total_start = start_time;
	m_timer_start = start_time;
	TimerStack *stack = GetTimerStackForCurrentThread ();
	if (stack)
	{
	if (stack->empty() == false)
	stack->back()->ChildStarted (start_time);
	stack->push_back(this);
	}
	}
	}


	Timer::~Timer()
	{
	if (m_total_start.IsValid())
	{
	TimeValue stop_time = TimeValue::Now();
	bool notify = false;
	if (m_total_start.IsValid())
	{
	m_total_ticks += (stop_time - m_total_start);
	m_total_start.Clear();
	notify = true;
	}
	if (m_timer_start.IsValid())
	{
	m_timer_ticks += (stop_time - m_timer_start);
	m_timer_start.Clear();
	}

	TimerStack *stack = GetTimerStackForCurrentThread ();
	if (stack)
	{
	assert (stack->back() == this);
	stack->pop_back();
	if (stack->empty() == false)
	stack->back()->ChildStopped(stop_time);
	}

	const uint64_t total_nsec_uint = GetTotalElapsedNanoSeconds();
	const uint64_t timer_nsec_uint = GetTimerElapsedNanoSeconds();
	const double total_nsec = total_nsec_uint;
	const double timer_nsec = timer_nsec_uint;

	if (g_quiet == false)
	{

	::fprintf (g_file,
	"%*s%.9f sec (%.9f sec)\n",
	(g_depth - 1) *TIMER_INDENT_AMOUNT, "",
	total_nsec / 1000000000.0,
	timer_nsec / 1000000000.0);
	}

	// Keep total results for each category so we can dump results.
	Mutex::Locker locker (GetCategoryMutex());
	CategoryMap &category_map = GetCategoryMap();
	category_map[m_category] += timer_nsec_uint;
	}
	if (g_depth > 0)
	--g_depth;
	}

	uint64_t
	Timer::GetTotalElapsedNanoSeconds()
	{
	uint64_t total_ticks = m_total_ticks;

	// If we are currently running, we need to add the current
	// elapsed time of the running timer...
	if (m_total_start.IsValid())
	total_ticks += (TimeValue::Now() - m_total_start);

	return total_ticks;
	}

	uint64_t
	Timer::GetTimerElapsedNanoSeconds()
	{
	uint64_t timer_ticks = m_timer_ticks;

	// If we are currently running, we need to add the current
	// elapsed time of the running timer...
	if (m_timer_start.IsValid())
	timer_ticks += (TimeValue::Now() - m_timer_start);

	return timer_ticks;
	}

	void
	Timer::ChildStarted (const TimeValue& start_time)
	{
	if (m_timer_start.IsValid())
	{
	m_timer_ticks += (start_time - m_timer_start);
	m_timer_start.Clear();
	}
	}

	void
	Timer::ChildStopped (const TimeValue& stop_time)
	{
	if (!m_timer_start.IsValid())
	m_timer_start = stop_time;
	}

	void
	Timer::SetDisplayDepth (uint32_t depth)
	{
	g_display_depth = depth;
	}


	/* binary function predicate:
	* - returns whether a person is less than another person
	*/
	static bool
	CategoryMapIteratorSortCriterion (const CategoryMap::const_iterator& lhs, const CategoryMap::const_iterator& rhs)
	{
	return lhs->second > rhs->second;
	}


	void
	Timer::ResetCategoryTimes ()
	{
	Mutex::Locker locker (GetCategoryMutex());
	CategoryMap &category_map = GetCategoryMap();
	category_map.clear();
	}

	void
	Timer::DumpCategoryTimes (Stream *s)
	{
	Mutex::Locker locker (GetCategoryMutex());
	CategoryMap &category_map = GetCategoryMap();
	std::vector<CategoryMap::const_iterator> sorted_iterators;
	CategoryMap::const_iterator pos, end = category_map.end();
	for (pos = category_map.begin(); pos != end; ++pos)
	{
	sorted_iterators.push_back (pos);
	}
	std::sort (sorted_iterators.begin(), sorted_iterators.end(), CategoryMapIteratorSortCriterion);

	const size_t count = sorted_iterators.size();
	for (size_t i=0; i<count; ++i)
	{
	const double timer_nsec = sorted_iterators[i]->second;
	s->Printf("%.9f sec for %s\n", timer_nsec / 1000000000.0, sorted_iterators[i]->first);
	}
	}