cnorxz/src/tests/op_unit_test.cc

// -*- C++ -*-

#include <cstdlib>
#include "gtest/gtest.h"
#include <iostream>

#include "multi_array_header.h"

#include <ctime>
#include <cmath>

namespace MAT = MultiArrayTools;

namespace {

    double xround(double arg)
    {
	return roundf(arg * 100000.) / 100000.;
    }
    
    using namespace MAT;

    template <class Factory>
    void swapFactory(std::shared_ptr<RangeFactoryBase>& fptr)
    {
	auto nptr = std::make_shared<Factory>();
	fptr = nptr;
    }
    
    template <class Factory, typename T>
    void swapFactory(std::shared_ptr<RangeFactoryBase>& fptr, std::initializer_list<T> ilist)
    {
	std::vector<T> tmp = ilist;
	auto nptr = std::make_shared<Factory>( tmp );
	fptr = nptr;
    }

    template <class Factory, typename T>
    void swapFactory(std::shared_ptr<RangeFactoryBase>& fptr, std::vector<T>& ilist)
    {
	std::vector<T> tmp = ilist;
	auto nptr = std::make_shared<Factory>( tmp );
	fptr = nptr;
    }

    
    template <class Factory, class... Rs>
    void swapMFactory(std::shared_ptr<RangeFactoryBase>& fptr, const Rs&... rs)
    {
	auto nptr = std::make_shared<Factory>( rs... );
	fptr = nptr;
    }

    template <typename... Ts>
    auto mkt(Ts&&... ts) -> decltype(std::make_tuple(ts...))
    {
	return std::make_tuple(ts...);
    }

    template <typename... Ts>
    auto mkts(Ts&&... ts) -> decltype(std::make_tuple(ts...))
    {
	return std::make_tuple(static_cast<size_t>( ts )...);
    }
    
    class OpTest_1Dim : public ::testing::Test
    {
    protected:

	typedef SingleRangeFactory<char,SpaceType::ANY> SRF;
	typedef SRF::oType SRange;

	OpTest_1Dim()
	{
	    swapFactory<SRF>(rfbptr, {'a', 'l', 'f', 'g'} );
	    srptr = std::dynamic_pointer_cast<SRange>( rfbptr->create() );
	}

	std::shared_ptr<RangeFactoryBase> rfbptr;
	std::shared_ptr<SRange> srptr;
	std::vector<double> v1 = { 2.917, 9.436, 0.373, 7.192 };
	std::vector<double> v2 = { 8.870, 4.790, 8.215, 5.063 };
    };
    
    class OpTest_MDim : public ::testing::Test
    {
    protected:

	typedef SingleRangeFactory<char,SpaceType::ANY> SRF;
	typedef SRF::oType SRange;

	typedef MultiRangeFactory<SRange,SRange> MRF;
	typedef MRF::oType MRange;
	
	OpTest_MDim()
	{
	    swapFactory<SRF>(rfbptr, {'x', 'l', 'f', 'g'} );
	    sr1ptr = std::dynamic_pointer_cast<SRange>( rfbptr->create() );

	    swapFactory<SRF>(rfbptr, {'1', '2', '3'} );
	    sr2ptr = std::dynamic_pointer_cast<SRange>( rfbptr->create() );

	    swapFactory<SRF>(rfbptr, {'a', 'b'} );
	    sr3ptr = std::dynamic_pointer_cast<SRange>( rfbptr->create() );

	    swapFactory<SRF>(rfbptr, {'A', 'B'} );
	    sr4ptr = std::dynamic_pointer_cast<SRange>( rfbptr->create() );

	    swapMFactory<MRF>(rfbptr, sr2ptr, sr3ptr);
	    mr1ptr = std::dynamic_pointer_cast<MRange>( rfbptr->create() );

	    swapMFactory<MRF>(rfbptr, sr2ptr, sr4ptr);
	    mr2ptr = std::dynamic_pointer_cast<MRange>( rfbptr->create() );
	}

	std::shared_ptr<RangeFactoryBase> rfbptr;
	std::shared_ptr<SRange> sr1ptr;
	std::shared_ptr<SRange> sr2ptr;
	std::shared_ptr<SRange> sr3ptr;
	std::shared_ptr<SRange> sr4ptr;
	std::shared_ptr<MRange> mr1ptr;
	std::shared_ptr<MRange> mr2ptr;
	std::vector<double> v1 = { 2.917, 9.436, 0.373 };
	std::vector<double> v2 = { 8.870, 4.790 };
	std::vector<double> v3 = { 0.353, 4.005, 1.070, 2.310, 9.243, 2.911 };
	std::vector<double> v4 = { 1.470, 2.210 };
    };

    class OpTest_Performance : public ::testing::Test
    {
    protected:

	typedef SingleRangeFactory<size_t,SpaceType::ANY> SRF;
	typedef SRF::oType SRange;

	typedef MultiRangeFactory<SRange,SRange> MRF;
	typedef MRF::oType MRange;

	OpTest_Performance()
	{
	
	    std::vector<size_t> initvec1(vs1);
	    cv1.resize(vs1);
	    for(size_t i = 0; i != vs1; ++i){
		initvec1[i] = i;
		cv1[i] = sqrt( static_cast<double>(i)*0.53 );
	    }

	    std::vector<size_t> initvec2(vs2);
	    cv2.resize(vs2*vs1);
	    for(size_t i = 0; i != vs2; ++i){
		initvec2[i] = i;
		for(size_t j = 0; j != vs1; ++j){
		    cv2[i*vs1 + j] = static_cast<double>(i) * sin(static_cast<double>(j)*0.4);
		}
	    }

	    swapFactory<SRF>(rfbptr, initvec1);
	    sr1ptr = std::dynamic_pointer_cast<SRange>(rfbptr->create());

	    swapFactory<SRF>(rfbptr, initvec2);
	    sr2ptr = std::dynamic_pointer_cast<SRange>(rfbptr->create());

	    swapMFactory<MRF>(rfbptr, sr2ptr, sr1ptr);
	    mrptr = std::dynamic_pointer_cast<MRange>(rfbptr->create());
	}

	//const size_t vs1 = 10000;
	//const size_t vs2 = 1000;
	const size_t vs1 = 4000;
	const size_t vs2 = 2500;

	std::shared_ptr<RangeFactoryBase> rfbptr;
	std::shared_ptr<SRange> sr1ptr;
	std::shared_ptr<SRange> sr2ptr;
	std::shared_ptr<MRange> mrptr;

	std::vector<double> cv1;
	std::vector<double> cv2;
    };

    class OpTest_Spin : public ::testing::Test
    {
    protected:

	typedef SpinRF SRF;
	typedef SpinRange SR;
	typedef MultiRangeFactory<SR,SR,SR,SR,SR,SR,SR,SR> SR8F;
	typedef SR8F::oType SR8;

	static const size_t s = 65536;
	
	OpTest_Spin()
	{
	    data.resize(s);
	    for(size_t i = 0; i != s; ++i){
		double arg = static_cast<double>( i - s ) - 0.1; 
		data[i] = sin(arg)/arg;
	    }
	    SRF f;
	    sr = std::dynamic_pointer_cast<SR>(f.create());
	}

	std::vector<double> data;
	std::shared_ptr<SR> sr;
    };

    TEST_F(OpTest_Spin, Contract)
    {
	MultiArray<double,SR,SR,SR,SR,SR,SR,SR,SR> ma(sr, sr, sr, sr, sr, sr, sr, sr, data);
	MultiArray<double,SR,SR> res1( sr, sr );
	
	auto alpha = MAT::getIndex<SR>();
	auto beta = MAT::getIndex<SR>();
	auto gamma = MAT::getIndex<SR>();
	auto delta = MAT::getIndex<SR>();
	auto deltap = MAT::getIndex<SR>();
	
	auto mix = MAT::mkMIndex( alpha, beta, gamma );

	std::clock_t begin = std::clock();
	res1(delta, deltap) = ma(delta, alpha, alpha, beta, beta, gamma, gamma, deltap).c(mix);
	std::clock_t end = std::clock();
	std::cout << "MultiArray time: " << static_cast<double>( end - begin ) / CLOCKS_PER_SEC
		  << std::endl;
	
	std::vector<double> vres(4*4);

	std::clock_t begin2 = std::clock();
	for(size_t d = 0; d != 4; ++d){
	    for(size_t p = 0; p != 4; ++p){
		const size_t tidx = d*4 + p;
		vres[tidx] = 0.;
		for(size_t a = 0; a != 4; ++a){
		    for(size_t b = 0; b != 4; ++b){
			for(size_t c = 0; c != 4; ++c){
			    const size_t sidx = d*4*4*4*4*4*4*4 + a*5*4*4*4*4 + b*5*4*4*4 + c*5*4 + p;
			    vres[tidx] += data[sidx];
			}
		    }
		}
	    }
	}
	std::clock_t end2 = std::clock();

	EXPECT_EQ( xround(res1.at(mkts(0,0))), xround(vres[0]) );
	EXPECT_EQ( xround(res1.at(mkts(0,1))), xround(vres[1]) );
	EXPECT_EQ( xround(res1.at(mkts(0,2))), xround(vres[2]) );
	EXPECT_EQ( xround(res1.at(mkts(0,3))), xround(vres[3]) );
	
	EXPECT_EQ( xround(res1.at(mkts(1,0))), xround(vres[4]) );
	EXPECT_EQ( xround(res1.at(mkts(1,1))), xround(vres[5]) );
	EXPECT_EQ( xround(res1.at(mkts(1,2))), xround(vres[6]) );
	EXPECT_EQ( xround(res1.at(mkts(1,3))), xround(vres[7]) );

	EXPECT_EQ( xround(res1.at(mkts(2,0))), xround(vres[8]) );
	EXPECT_EQ( xround(res1.at(mkts(2,1))), xround(vres[9]) );
	EXPECT_EQ( xround(res1.at(mkts(2,2))), xround(vres[10]) );
	EXPECT_EQ( xround(res1.at(mkts(2,3))), xround(vres[11]) );

	EXPECT_EQ( xround(res1.at(mkts(3,0))), xround(vres[12]) );
	EXPECT_EQ( xround(res1.at(mkts(3,1))), xround(vres[13]) );
	EXPECT_EQ( xround(res1.at(mkts(3,2))), xround(vres[14]) );
	EXPECT_EQ( xround(res1.at(mkts(3,3))), xround(vres[15]) );

	std::cout << "std::vector - for loop time: " << static_cast<double>( end2 - begin2 ) / CLOCKS_PER_SEC
		  << std::endl;
	std::cout << "ratio: " << static_cast<double>( end - begin ) / static_cast<double>( end2 - begin2 ) << std::endl;
    }    
    
    TEST_F(OpTest_Performance, PCheck)
    {
	MultiArray<double,MRange> ma2(mrptr, cv2);
	MultiArray<double,SRange> ma1(sr1ptr, cv1);
	MultiArray<double,MRange> res(mrptr);

	auto si1 = MAT::getIndex(sr1ptr);
	auto si2 = MAT::getIndex(sr2ptr);
	auto mi = MAT::getIndex(mrptr);
	(*mi)(si2, si1);

	std::clock_t begin = std::clock();
	
	res(mi) = ma2(mi) * ma1(si1);

	std::clock_t end = std::clock();
	std::cout << "MultiArray time: " << static_cast<double>( end - begin ) / CLOCKS_PER_SEC
		  << std::endl;

	std::vector<double> res2(vs1*vs2);
	std::clock_t begin2 = std::clock();
	
	for(size_t i = 0; i != vs2; ++i){
	    for(size_t j = 0; j != vs1; ++j){
		res2[i*vs1 + j] = cv1[j] * cv2[i*vs1 + j];
	    }
	}

	std::clock_t end2 = std::clock();
	std::cout << "std::vector - for loop time: " << static_cast<double>( end2 - begin2 ) / CLOCKS_PER_SEC
		  << std::endl;

	std::cout << "ratio: " << static_cast<double>( end - begin ) / static_cast<double>( end2 - begin2 ) << std::endl;

	EXPECT_EQ( xround( res.at(mkt(7,9)) ), xround(res2[7*vs1 + 9]) );
	//EXPECT_EQ( xround( res.at(mkt(700,900)) ), xround(res2[700*vs1 + 900]) );
	
    }

    TEST_F(OpTest_1Dim, ExecOp)
    {
	MultiArray<double,SRange> ma1(srptr, v1);
	MultiArray<double,SRange> ma2(srptr, v2);
	MultiArray<double,SRange> res(srptr);

	auto i = MAT::getIndex( srptr );
	
	res(i) = ma1(i) + ma2(i);

	EXPECT_EQ( fabs( res.at('a') - (2.917+8.870) ) < 0.0001, true);
	EXPECT_EQ( fabs( res.at('l') - (9.436+4.790) ) < 0.0001, true );
	EXPECT_EQ( fabs( res.at('f') - (0.373+8.215) ) < 0.0001, true );
	EXPECT_EQ( fabs( res.at('g') - (7.192+5.063) ) < 0.0001, true );
    }

    TEST_F(OpTest_MDim, ExecOp1)
    {
	MultiArray<double,SRange,SRange> res(sr2ptr,sr4ptr);
	const MultiArray<double,SRange> ma1(sr2ptr, v1);
	const MultiArray<double,SRange> ma2(sr4ptr, v2);

	auto i1 = MAT::getIndex( sr2ptr );
	auto i2 = MAT::getIndex( sr4ptr );

	res(i1,i2) = ma1(i1) * ma2(i2);

	EXPECT_EQ( xround( res.at(mkt('1','A')) ), xround(2.917 * 8.870) );
	EXPECT_EQ( xround( res.at(mkt('1','B')) ), xround(2.917 * 4.790) );

	EXPECT_EQ( xround( res.at(mkt('2','A')) ), xround(9.436 * 8.870) );
	EXPECT_EQ( xround( res.at(mkt('2','B')) ), xround(9.436 * 4.790) );
	
	EXPECT_EQ( xround( res.at(mkt('3','A')) ), xround(0.373 * 8.870) );
	EXPECT_EQ( xround( res.at(mkt('3','B')) ), xround(0.373 * 4.790) );

    }

    TEST_F(OpTest_MDim, ExecContract)
    {
	MultiArray<double,SRange> res(sr2ptr);
	const MultiArray<double,SRange> ma1(sr2ptr, v1);
	const MultiArray<double,SRange> ma2(sr4ptr, v2);

	auto i1 = MAT::getIndex( sr2ptr );
	auto i2 = MAT::getIndex( sr4ptr );

	res(i1) = (ma1(i1) * ma2(i2)).c(i2);

	EXPECT_EQ( xround( res.at('1') ), xround(2.917 * 8.870 + 2.917 * 4.790) );
	EXPECT_EQ( xround( res.at('2') ), xround(9.436 * 8.870 + 9.436 * 4.790) );
	EXPECT_EQ( xround( res.at('3') ), xround(0.373 * 8.870 + 0.373 * 4.790) );
    }
    
    TEST_F(OpTest_MDim, ExecOp2)
    {
	MultiArray<double,MRange,SRange> res(mr1ptr,sr4ptr);
	MultiArray<double,MRange> ma1(mr1ptr, v3);
	MultiArray<double,SRange> ma2(sr4ptr, v2);
	MultiArray<double,SRange> ma3(sr4ptr, v4);
	
	auto i1 = MAT::getIndex( mr1ptr );
	auto i2 = MAT::getIndex( sr4ptr );
	
	res(i1,i2) = ( ma1(i1) + ma2(i2) ) - ma3(i2);

	EXPECT_EQ( xround( res.at(mkt(mkt('1','a'),'A')) ), xround(0.353 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','a'),'B')) ), xround(0.353 + 4.790 - 2.210)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','b'),'A')) ), xround(4.005 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','b'),'B')) ), xround(4.005 + 4.790 - 2.210) );

	EXPECT_EQ( xround( res.at(mkt(mkt('2','a'),'A')) ), xround(1.070 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','a'),'B')) ), xround(1.070 + 4.790 - 2.210)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','b'),'A')) ), xround(2.310 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','b'),'B')) ), xround(2.310 + 4.790 - 2.210)  );

	EXPECT_EQ( xround( res.at(mkt(mkt('3','a'),'A')) ), xround(9.243 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','a'),'B')) ), xround(9.243 + 4.790 - 2.210)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','b'),'A')) ), xround(2.911 + 8.870 - 1.470)  );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','b'),'B')) ), xround(2.911 + 4.790 - 2.210)  );
    }

    TEST_F(OpTest_MDim, ExecOp3)
    {
	MultiArray<double,MRange,SRange> res(mr1ptr,sr4ptr);
	MultiArray<double,MRange> ma1(mr1ptr, v3);
	MultiArray<double,SRange> ma2(sr2ptr, v1);
	MultiArray<double,SRange> ma3(sr4ptr, v4);

	auto si1 = MAT::getIndex( sr2ptr );
	auto si2 = MAT::getIndex( sr3ptr );
	auto si3 = MAT::getIndex( sr4ptr );
	auto mi = MAT::getIndex( mr1ptr );
	mi->operator()(si1,si2);
	
	res(mi,si3) = ma1(mi) + ma2(si1) + ma3(si3);

	EXPECT_EQ( xround( res.at(mkt(mkt('1','a'),'A')) ), xround(0.353 + 2.917 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','a'),'B')) ), xround(0.353 + 2.917 + 2.210) );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','b'),'A')) ), xround(4.005 + 2.917 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('1','b'),'B')) ), xround(4.005 + 2.917 + 2.210) );

	EXPECT_EQ( xround( res.at(mkt(mkt('2','a'),'A')) ), xround(1.070 + 9.436 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','a'),'B')) ), xround(1.070 + 9.436 + 2.210) );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','b'),'A')) ), xround(2.310 + 9.436 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('2','b'),'B')) ), xround(2.310 + 9.436 + 2.210) );

	EXPECT_EQ( xround( res.at(mkt(mkt('3','a'),'A')) ), xround(9.243 + 0.373 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','a'),'B')) ), xround(9.243 + 0.373 + 2.210) );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','b'),'A')) ), xround(2.911 + 0.373 + 1.470) );
	EXPECT_EQ( xround( res.at(mkt(mkt('3','b'),'B')) ), xround(2.911 + 0.373 + 2.210) );
    }
    
} // anonymous namspace

int main(int argc, char** argv)
{
    ::testing::InitGoogleTest(&argc, argv);
    return RUN_ALL_TESTS();
}