bench/bench_reverse.cpp - mirror - Git at Google


 #include <iostream>
 #include <Eigen/Core>
 #include <bench/BenchUtil.h>
 using namespace Eigen;

 #ifndef REPEAT
 #define REPEAT 100000
 #endif

 #ifndef TRIES
 #define TRIES 20
 #endif

 typedef double Scalar;

 template <typename MatrixType>
 __attribute__ ((noinline)) void bench_reverse(const MatrixType& m)
 {
   int rows = m.rows();
   int cols = m.cols();
   int size = m.size();

   int repeats = (REPEAT*1000)/size;
   MatrixType a = MatrixType::Random(rows,cols);
   MatrixType b = MatrixType::Random(rows,cols);

   BenchTimer timerB, timerH, timerV;

   Scalar acc = 0;
   int r = internal::random<int>(0,rows-1);
   int c = internal::random<int>(0,cols-1);
   for (int t=0; t<TRIES; ++t)
   {
     timerB.start();
     for (int k=0; k<repeats; ++k)
     {
       asm("#begin foo");
       b = a.reverse();
       asm("#end foo");
       acc += b.coeff(r,c);
     }
     timerB.stop();
   }

   if (MatrixType::RowsAtCompileTime==Dynamic)
     std::cout << "dyn   ";
   else
     std::cout << "fixed ";
   std::cout << rows << " x " << cols << " \t"
             << (timerB.value() * REPEAT) / repeats << "s "
             << "(" << 1e-6 * size*repeats/timerB.value() << " MFLOPS)\t";

   std::cout << "\n";
   // make sure the compiler does not optimize too much
   if (acc==123)
     std::cout << acc;
 }

 int main(int argc, char* argv[])
 {
   const int dynsizes[] = {4,6,8,16,24,32,49,64,128,256,512,900,0};
   std::cout << "size            no sqrt                           standard";
 //   #ifdef BENCH_GSL
 //   std::cout << "       GSL (standard + double + ATLAS)  ";
 //   #endif
   std::cout << "\n";
   for (uint i=0; dynsizes[i]>0; ++i)
   {
     bench_reverse(Matrix<Scalar,Dynamic,Dynamic>(dynsizes[i],dynsizes[i]));
     bench_reverse(Matrix<Scalar,Dynamic,1>(dynsizes[i]*dynsizes[i]));
   }
 //   bench_reverse(Matrix<Scalar,2,2>());
 //   bench_reverse(Matrix<Scalar,3,3>());
 //   bench_reverse(Matrix<Scalar,4,4>());
 //   bench_reverse(Matrix<Scalar,5,5>());
 //   bench_reverse(Matrix<Scalar,6,6>());
 //   bench_reverse(Matrix<Scalar,7,7>());
 //   bench_reverse(Matrix<Scalar,8,8>());
 //   bench_reverse(Matrix<Scalar,12,12>());
 //   bench_reverse(Matrix<Scalar,16,16>());
   return 0;
 }

	#include <iostream>
	#include <Eigen/Core>
	#include <bench/BenchUtil.h>
	using namespace Eigen;

	#ifndef REPEAT
	#define REPEAT 100000
	#endif

	#ifndef TRIES
	#define TRIES 20
	#endif

	typedef double Scalar;

	template <typename MatrixType>
	__attribute__ ((noinline)) void bench_reverse(const MatrixType& m)
	{
	int rows = m.rows();
	int cols = m.cols();
	int size = m.size();

	int repeats = (REPEAT*1000)/size;
	MatrixType a = MatrixType::Random(rows,cols);
	MatrixType b = MatrixType::Random(rows,cols);

	BenchTimer timerB, timerH, timerV;

	Scalar acc = 0;
	int r = internal::random<int>(0,rows-1);
	int c = internal::random<int>(0,cols-1);
	for (int t=0; t<TRIES; ++t)
	{
	timerB.start();
	for (int k=0; k<repeats; ++k)
	{
	asm("#begin foo");
	b = a.reverse();
	asm("#end foo");
	acc += b.coeff(r,c);
	}
	timerB.stop();
	}

	if (MatrixType::RowsAtCompileTime==Dynamic)
	std::cout << "dyn ";
	else
	std::cout << "fixed ";
	std::cout << rows << " x " << cols << " \t"
	<< (timerB.value() * REPEAT) / repeats << "s "
	<< "(" << 1e-6 * size*repeats/timerB.value() << " MFLOPS)\t";

	std::cout << "\n";
	// make sure the compiler does not optimize too much
	if (acc==123)
	std::cout << acc;
	}

	int main(int argc, char* argv[])
	{
	const int dynsizes[] = {4,6,8,16,24,32,49,64,128,256,512,900,0};
	std::cout << "size no sqrt standard";
	// #ifdef BENCH_GSL
	// std::cout << " GSL (standard + double + ATLAS) ";
	// #endif
	std::cout << "\n";
	for (uint i=0; dynsizes[i]>0; ++i)
	{
	bench_reverse(Matrix<Scalar,Dynamic,Dynamic>(dynsizes[i],dynsizes[i]));
	bench_reverse(Matrix<Scalar,Dynamic,1>(dynsizes[i]*dynsizes[i]));
	}
	// bench_reverse(Matrix<Scalar,2,2>());
	// bench_reverse(Matrix<Scalar,3,3>());
	// bench_reverse(Matrix<Scalar,4,4>());
	// bench_reverse(Matrix<Scalar,5,5>());
	// bench_reverse(Matrix<Scalar,6,6>());
	// bench_reverse(Matrix<Scalar,7,7>());
	// bench_reverse(Matrix<Scalar,8,8>());
	// bench_reverse(Matrix<Scalar,12,12>());
	// bench_reverse(Matrix<Scalar,16,16>());
	return 0;
	}