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TimeTBB.cpp
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TimeTBB.cpp
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/* ----------------------------------------------------------------------------
* GTSAM Copyright 2010, Georgia Tech Research Corporation,
* Atlanta, Georgia 30332-0415
* All Rights Reserved
* Authors: Frank Dellaert, et al. (see THANKS for the full author list)
* See LICENSE for the license information
* -------------------------------------------------------------------------- */
/**
* @file TimeTBB.cpp
* @brief Measure task scheduling overhead in TBB
* @author Richard Roberts
* @date November 6, 2013
*/
#include <gtsam/global_includes.h>
#include <gtsam/base/Matrix.h>
#include <map>
#include <iostream>
using namespace std;
using namespace gtsam;
#ifdef GTSAM_USE_TBB
#include <tbb/blocked_range.h> // tbb::blocked_range
#include <tbb/tick_count.h> // tbb::tick_count
#include <tbb/parallel_for.h> // tbb::parallel_for
#include <tbb/cache_aligned_allocator.h> // tbb::cache_aligned_allocator
#include <tbb/task_arena.h> // tbb::task_arena
#include <tbb/task_group.h> // tbb::task_group
static const DenseIndex numberOfProblems = 1000000;
static const DenseIndex problemSize = 4;
typedef Eigen::Matrix<double, problemSize, problemSize> FixedMatrix;
/* ************************************************************************* */
struct ResultWithThreads
{
typedef map<int, double>::value_type value_type;
map<int, double> grainSizesWithoutAllocation;
map<int, double> grainSizesWithAllocation;
};
typedef map<int, ResultWithThreads> Results;
/* ************************************************************************* */
struct WorkerWithoutAllocation
{
vector<double>& results;
WorkerWithoutAllocation(vector<double>& results) : results(results) {}
void operator()(const tbb::blocked_range<size_t>& r) const
{
for(size_t i = r.begin(); i != r.end(); ++i)
{
FixedMatrix m1 = FixedMatrix::Random();
FixedMatrix m2 = FixedMatrix::Random();
FixedMatrix prod = m1 * m2;
results[i] = prod.norm();
}
}
};
/* ************************************************************************* */
map<int, double> testWithoutMemoryAllocation(int num_threads)
{
// A function to do some matrix operations without allocating any memory
// Create task_arena and task_group
tbb::task_arena arena(num_threads);
tbb::task_group tg;
// Now call it
vector<double> results(numberOfProblems);
const vector<size_t> grainSizes = {1, 10, 100, 1000};
map<int, double> timingResults;
for(size_t grainSize: grainSizes)
{
tbb::tick_count t0 = tbb::tick_count::now();
// Run parallel code (as a task group) inside of task arena
arena.execute([&]{
tg.run_and_wait([&]{
tbb::parallel_for(tbb::blocked_range<size_t>(0, numberOfProblems), WorkerWithoutAllocation(results));
});
});
tbb::tick_count t1 = tbb::tick_count::now();
cout << "Without memory allocation, grain size = " << grainSize << ", time = " << (t1 - t0).seconds() << endl;
timingResults[(int)grainSize] = (t1 - t0).seconds();
}
return timingResults;
}
/* ************************************************************************* */
struct WorkerWithAllocation
{
vector<double>& results;
WorkerWithAllocation(vector<double>& results) : results(results) {}
void operator()(const tbb::blocked_range<size_t>& r) const
{
tbb::cache_aligned_allocator<double> allocator;
for(size_t i = r.begin(); i != r.end(); ++i)
{
double *m1data = allocator.allocate(problemSize * problemSize);
Eigen::Map<Matrix> m1(m1data, problemSize, problemSize);
double *m2data = allocator.allocate(problemSize * problemSize);
Eigen::Map<Matrix> m2(m2data, problemSize, problemSize);
double *proddata = allocator.allocate(problemSize * problemSize);
Eigen::Map<Matrix> prod(proddata, problemSize, problemSize);
m1 = Eigen::Matrix4d::Random(problemSize, problemSize);
m2 = Eigen::Matrix4d::Random(problemSize, problemSize);
prod = m1 * m2;
results[i] = prod.norm();
allocator.deallocate(m1data, problemSize * problemSize);
allocator.deallocate(m2data, problemSize * problemSize);
allocator.deallocate(proddata, problemSize * problemSize);
}
}
};
/* ************************************************************************* */
map<int, double> testWithMemoryAllocation(int num_threads)
{
// A function to do some matrix operations with allocating memory
// Create task_arena and task_group
tbb::task_arena arena(num_threads);
tbb::task_group tg;
// Now call it
vector<double> results(numberOfProblems);
const vector<size_t> grainSizes = {1, 10, 100, 1000};
map<int, double> timingResults;
for(size_t grainSize: grainSizes)
{
tbb::tick_count t0 = tbb::tick_count::now();
// Run parallel code (as a task group) inside of task arena
arena.execute([&]{
tg.run_and_wait([&]{
tbb::parallel_for(tbb::blocked_range<size_t>(0, numberOfProblems), WorkerWithAllocation(results));
});
});
tbb::tick_count t1 = tbb::tick_count::now();
cout << "With memory allocation, grain size = " << grainSize << ", time = " << (t1 - t0).seconds() << endl;
timingResults[(int)grainSize] = (t1 - t0).seconds();
}
return timingResults;
}
/* ************************************************************************* */
int main(int argc, char* argv[])
{
cout << "numberOfProblems = " << numberOfProblems << endl;
cout << "problemSize = " << problemSize << endl;
const vector<int> numThreads = {1, 4, 8};
Results results;
for(size_t n: numThreads)
{
cout << "With " << n << " threads:" << endl;
results[(int)n].grainSizesWithoutAllocation = testWithoutMemoryAllocation((int)n);
results[(int)n].grainSizesWithAllocation = testWithMemoryAllocation((int)n);
cout << endl;
}
cout << "Summary of results:" << endl;
for(const Results::value_type& threads_result: results)
{
const int threads = threads_result.first;
const ResultWithThreads& result = threads_result.second;
if(threads != 1)
{
for(const ResultWithThreads::value_type& grainsize_time: result.grainSizesWithoutAllocation)
{
const int grainsize = grainsize_time.first;
const double speedup = results[1].grainSizesWithoutAllocation[grainsize] / grainsize_time.second;
cout << threads << " threads, without allocation, grain size = " << grainsize << ", speedup = " << speedup << endl;
}
for(const ResultWithThreads::value_type& grainsize_time: result.grainSizesWithAllocation)
{
const int grainsize = grainsize_time.first;
const double speedup = results[1].grainSizesWithAllocation[grainsize] / grainsize_time.second;
cout << threads << " threads, with allocation, grain size = " << grainsize << ", speedup = " << speedup << endl;
}
}
}
return 0;
}
#else
/* ************************************************************************* */
int main(int argc, char* argv [])
{
cout << "GTSAM is compiled without TBB, please compile with TBB to use this program." << endl;
return 0;
}
#endif