cnorxz/src/tests/op4_unit_test.cc


#include "test_header.h"
#include <ctime>

namespace
{

    template <class MA>
    void setMARandom(MA& ma, int seed)
    {
	std::srand(seed);
	double n = 0;
	double d = 0;
	for(auto& x: ma.vdata()){
	    double nx = 0;
	    double dx = 0;
	    while(nx == x or dx == d or nx == dx or dx == 0){
		nx = static_cast<double>(std::rand() % 1000);
		dx = static_cast<double>(std::rand() % 1000);
	    }
	    n = nx;
	    d = dx;
	    assert(n != d);
	    x = n/d;
	}
    }

    template <class Op>
    DynamicO<double> mkDynOp(const Op& op)
    {
	return DynamicO<double>(op);
    }

    template <class Op1, class Op2>
    DynamicO<double> mkDynMul(const Op1& op1, const Op2& op2)
    {
	auto op = op1 * op2;
	return DynamicO<double>(std::make_shared<DynamicOperation<double,decltype(op)>>(op));
    }
    
    class OpTest_Dyn : public ::testing::Test
    {
    protected:

	MultiArray<double,CR,DR> ma1;
	MultiArray<double,CR,DR> ma2;
	MultiArray<double,DR> ma3;
	MultiArray<double,DR> ma5;

	MultiArray<double,CR,DR> res1;
	MultiArray<double,CR,DR> res2;

	std::map<std::string,std::shared_ptr<IndexW>> imap;

	std::shared_ptr<DR> dr1;
	std::shared_ptr<DR> dr1a;
	std::shared_ptr<DR> dr2;
	std::shared_ptr<DR> dr3;
	std::shared_ptr<DR> dr4;
	std::shared_ptr<DR> dr5;
	std::shared_ptr<DR> dr6;
	std::shared_ptr<CR> cr1;

	std::shared_ptr<CR::IndexType> ci4;
	
	OpTest_Dyn()
	{
	    cr1 = createRangeE<CR>(5);
	    
	    auto cr2 = createRangeE<CR>(7);
	    auto cr3 = createRangeE<CR>(11);
	    auto cr4 = createRangeE<CR>(3);
	    auto cr5 = createRangeE<CR>(13);

	    dr1 = createRangeE<DR>(cr2,cr2,cr3,cr4);
	    dr1a = createRangeE<DR>(cr2,cr2,cr3);
	    dr2 = createRangeE<DR>(cr3,cr3,cr4);
	    dr3 = createRangeE<DR>(cr2,cr5);
	    dr5 = createRangeE<DR>(cr5);
	    dr6 = createRangeE<DR>(cr3,cr4);

	    dr4 = createRangeE<DR>(cr2,cr3,cr4,cr4);

	    ma1 = mkArray<double>(cr1,dr1);
	    ma2 = mkArray<double>(cr1,dr2);
	    ma3 = mkArray<double>(dr3);
	    ma5 = mkArray<double>(dr5);

	    res1 = mkArray<double>(cr1,dr4);
	    res2 = mkArray<double>(cr1,dr6);

	    setMARandom(ma1, 25);
	    setMARandom(ma2, 31);
	    setMARandom(ma3, 47);
	    setMARandom(ma5, 59);

	    imap["i2_1"] = mkIndexW(getIndex(cr2));
	    imap["i2_2"] = mkIndexW(getIndex(cr2));
	    imap["i3_1"] = mkIndexW(getIndex(cr3));
	    imap["i3_2"] = mkIndexW(getIndex(cr3));
	    ci4 = getIndex(cr4);
	    imap["i4_1"] = mkIndexW(ci4);
	    imap["i4_2"] = mkIndexW(getIndex(cr4));
	    imap["i5_1"] = mkIndexW(getIndex(cr5));
	    imap["i5_2"] = mkIndexW(getIndex(cr5));
	}
    };

    TEST_F(OpTest_Dyn, Multiply)
    {
	auto i1 = getIndex(cr1);
	auto di1 = getIndex(dr1);
	auto di1a = getIndex(dr1a);
	auto di2 = getIndex(dr2);
	auto di4 = getIndex(dr4);

	auto mi = mkMIndex(i1,di1a);
	
	(*di1)({imap["i2_1"],imap["i2_2"],imap["i3_1"],imap["i4_1"]});
	(*di1a)({imap["i2_1"],imap["i2_2"],imap["i3_1"]});
	(*di2)({imap["i3_1"],imap["i3_1"],imap["i4_2"]});
	(*di4)({imap["i2_1"],imap["i3_1"],imap["i4_1"],imap["i4_2"]});

	auto resx1 = res1;
	auto resx2 = res1;
	auto resx3 = res1;
	auto resx4 = res1;
	auto xx = std::make_shared<decltype(resx4)>(resx4);
	res1(i1,di4) = ma1(i1,di1) * ma2(i1,di2);
	resx1(i1,di4) = mkDynOp(ma1(i1,di1)) * mkDynOp(ma2(i1,di2));
        resx2(i1,di4) = mkDynOp(ma1(i1,di1) * ma2(i1,di2));
	resx3(i1,di4) = mkDynOp(mkDynOp(ma1(i1,di1)) * mkDynOp(ma2(i1,di2)));
	
	auto op1 = mkDynOutOp(ma1(i1,di1) * ma2(i1,di2), ci4);
        auto op1x = ma1(i1,di1) * ma2(i1,di2);
	auto opr = resx4(i1,di4);
        
	auto loop = mkILoop(std::make_tuple(opr,op1,op1.data()->mOp), std::make_tuple(ci4),
			    std::make_tuple(xx), std::make_tuple(opr.assign( op1.data()->mOp, ci4 )),
			    //std::make_tuple(), std::make_tuple(),
			    std::array<size_t,1>({1}), std::array<size_t,1>({0}));
        
        /*
	auto loop = mkILoop(std::make_tuple(opr,op1x), std::make_tuple(ci4),
			    std::make_tuple(xx), std::make_tuple(opr.assign( op1x, ci4 )),
			    //std::make_tuple(), std::make_tuple(),
			    std::array<size_t,1>({1}), std::array<size_t,1>({0}));
        */
	//mi->ifor(1, loop)();
        mi->ifor(1, loop)();
	
	auto i2_1 = imap.at("i2_1");
	auto i2_2 = imap.at("i2_2");
	auto i3_1 = imap.at("i3_1");
	auto i4_1 = imap.at("i4_1");
	auto i4_2 = imap.at("i4_2");
	
	for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){
	    for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){
		size_t ii2_2 = 0;
		for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){
		    for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){
			for(size_t ii4_2 = 0; ii4_2 != i4_2->max(); ++ii4_2){
			    const size_t jr = (((ii1*i2_1->max() + ii2_1)*i3_1->max() + ii3_1)*i4_1->max() + ii4_1)*i4_2->max() + ii4_2;
			    const size_t j1 = (((ii1*i2_1->max() + ii2_1)*i2_2->max() + ii2_2)*i3_1->max() + ii3_1)*i4_1->max() + ii4_1;
			    const size_t j2 = ((ii1*i3_1->max() + ii3_1)*i3_1->max() + ii3_1)*i4_2->max() + ii4_2;
			    auto resv = xround(res1.vdata()[jr]);
			    auto resx1v = xround(resx1.vdata()[jr]);
			    auto resx2v = xround(resx2.vdata()[jr]);
			    auto resx3v = xround(resx3.vdata()[jr]);
	 		    auto x12 = xround(ma1.vdata()[j1]*ma2.vdata()[j2]);
			    EXPECT_EQ( resv, x12 );
			    EXPECT_EQ( resx1v, x12 );
			    EXPECT_EQ( resx2v, x12 );
			    EXPECT_EQ( resx3v, x12 );
			}
		    }
		}
	    }
	    //std::cout << std::endl;
	}
    }

    TEST_F(OpTest_Dyn, Contract)
    {
	auto i1 = getIndex(cr1);
	auto di1 = getIndex(dr1);
	auto di3 = getIndex(dr3);
	auto di5 = getIndex(dr5);
	auto di6 = getIndex(dr6);

	(*di1)({imap["i2_1"],imap["i2_1"],imap["i3_1"],imap["i4_1"]});
	(*di3)({imap["i2_1"],imap["i5_1"]});
	(*di5)({imap["i5_1"]});
	(*di6)({imap["i3_1"],imap["i4_1"]});

	auto resx1 = res2;
	auto resx2 = res2;
	auto resx3 = res2;
        res2(i1,di6) += (ma1(i1,di1) * ma5(di5)).c(di3);
	resx1(i1,di6) += (mkDynOp(ma1(i1,di1)) * mkDynOp(ma5(di5))).c(di3);
        resx2(i1,di6) += mkDynOp((ma1(i1,di1) * ma5(di5)).c(di3));
	resx3(i1,di6) += mkDynOp((mkDynOp(ma1(i1,di1)) * mkDynOp(ma5(di5))).c(di3));
        
	auto i2_1 = imap.at("i2_1");
	auto i3_1 = imap.at("i3_1");
	auto i4_1 = imap.at("i4_1");
	auto i5_1 = imap.at("i5_1");
	
	for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){
            for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){
                for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){
                    double vv = 0;
                    const size_t jr = (ii1*i3_1->max() + ii3_1)*i4_1->max() + ii4_1;
                    for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){
                        const size_t j1 = (((ii1*i2_1->max() + ii2_1)*i2_1->max() + ii2_1)*i3_1->max() + ii3_1)*i4_1->max() + ii4_1;
                        for(size_t ii5_1 = 0; ii5_1 != i5_1->max(); ++ii5_1){
                            const size_t j2 = ii5_1;
                            vv += ma1.vdata()[j1] * ma5.vdata()[j2];
                        }
                    }
                    
                    auto resv = xround(res2.vdata()[jr]);
                    auto resx1v = xround(resx1.vdata()[jr]);
                    auto resx2v = xround(resx2.vdata()[jr]);
                    auto resx3v = xround(resx3.vdata()[jr]);
                    auto x12 = xround(vv);
                    EXPECT_EQ( resv, x12 );
                    EXPECT_EQ( resx1v, x12 );
                    EXPECT_EQ( resx2v, x12 );
                    EXPECT_EQ( resx3v, x12 );
		}
	    }
	    //std::cout << std::endl;
	}

    }

    TEST_F(OpTest_Dyn, Functional)
    {
	auto i1 = getIndex(cr1);
	auto di1 = getIndex(dr1);
	auto di2 = getIndex(dr2);
	auto di4 = getIndex(dr4);

	//(*di1)({imap["i2_1"],imap["i2_2"],imap["i3_1"],imap["i4_1"]});
	//(*di2)({imap["i3_1"],imap["i3_1"],imap["i4_2"]});
	//(*di4)({imap["i2_1"],imap["i3_1"],imap["i4_1"],imap["i4_2"]});
        (*di1)({"ia_1","ia_2","ib_1","ic_1"});
	(*di2)({"ib_1","ib_1","ic_2"});
	(*di4)({"ia_1","ib_1","ic_1","ic_2"});

	auto resx1 = res1;
	auto resx2 = res1;
	auto resx3 = res1;
	res1(i1,di4) = ma1(i1,di1) * exp(ma2(i1,di2));
	resx1(i1,di4) = mkDynOp(ma1(i1,di1)) * exp(mkDynOp(ma2(i1,di2)));
        resx2(i1,di4) = mkDynOp(ma1(i1,di1) * exp(ma2(i1,di2)));
	resx3(i1,di4) = mkDynOp(mkDynOp(ma1(i1,di1)) * mkDynOp(exp(mkDynOp(ma2(i1,di2)))));
        
	auto i2_1 = imap.at("i2_1");
	auto i2_2 = imap.at("i2_2");
	auto i3_1 = imap.at("i3_1");
	auto i4_1 = imap.at("i4_1");
	auto i4_2 = imap.at("i4_2");
	
	for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){
	    for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){
		size_t ii2_2 = 0;
		for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){
		    for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){
			for(size_t ii4_2 = 0; ii4_2 != i4_2->max(); ++ii4_2){
			    const size_t jr = (((ii1*i2_1->max() + ii2_1)*i3_1->max() + ii3_1)*i4_1->max() + ii4_1)*i4_2->max() + ii4_2;
			    const size_t j1 = (((ii1*i2_1->max() + ii2_1)*i2_2->max() + ii2_2)*i3_1->max() + ii3_1)*i4_1->max() + ii4_1;
			    const size_t j2 = ((ii1*i3_1->max() + ii3_1)*i3_1->max() + ii3_1)*i4_2->max() + ii4_2;
			    auto resv = xround(res1.vdata()[jr]);
			    auto resx1v = xround(resx1.vdata()[jr]);
			    auto resx2v = xround(resx2.vdata()[jr]);
			    auto resx3v = xround(resx3.vdata()[jr]);
	 		    auto x12 = xround(ma1.vdata()[j1]*exp(ma2.vdata()[j2]));
			    EXPECT_EQ( resv, x12 );
			    EXPECT_EQ( resx1v, x12 );
			    EXPECT_EQ( resx2v, x12 );
			    EXPECT_EQ( resx3v, x12 );
			}
		    }
		}
	    }
	    //std::cout << std::endl;
	}
    }
    
}
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`#include "test_header.h"`
			`#include <ctime>`

			`namespace`
			`{`

			`template <class MA>`
			`void setMARandom(MA& ma, int seed)`
			`{`
			`std::srand(seed);`
			`double n = 0;`
			`double d = 0;`
			`for(auto& x: ma.vdata()){`
			`double nx = 0;`
			`double dx = 0;`
			`while(nx == x or dx == d or nx == dx or dx == 0){`
			`nx = static_cast<double>(std::rand() % 1000);`
			`dx = static_cast<double>(std::rand() % 1000);`
			`}`
			`n = nx;`
			`d = dx;`
			`assert(n != d);`
			`x = n/d;`
			`}`
			`}`

			`template <class Op>`
			`DynamicO<double> mkDynOp(const Op& op)`
			`{`
			`return DynamicO<double>(op);`
			`}`

			`template <class Op1, class Op2>`
			`DynamicO<double> mkDynMul(const Op1& op1, const Op2& op2)`
			`{`
			`auto op = op1 * op2;`
			`return DynamicO<double>(std::make_shared<DynamicOperation<double,decltype(op)>>(op));`
			`}`

			`class OpTest_Dyn : public ::testing::Test`
			`{`
			`protected:`

			`MultiArray<double,CR,DR> ma1;`
			`MultiArray<double,CR,DR> ma2;`
			`MultiArray<double,DR> ma3;`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`MultiArray<double,DR> ma5;`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`MultiArray<double,CR,DR> res1;`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`MultiArray<double,CR,DR> res2;`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`std::map<std::string,std::shared_ptr<IndexW>> imap;`

			`std::shared_ptr<DR> dr1;`
im com 2020-08-27 23:48:04 +02:00			`std::shared_ptr<DR> dr1a;`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`std::shared_ptr<DR> dr2;`
			`std::shared_ptr<DR> dr3;`
			`std::shared_ptr<DR> dr4;`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`std::shared_ptr<DR> dr5;`
			`std::shared_ptr<DR> dr6;`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`std::shared_ptr<CR> cr1;`
im com 2020-08-27 23:48:04 +02:00
			`std::shared_ptr<CR::IndexType> ci4;`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`OpTest_Dyn()`
			`{`
			`cr1 = createRangeE<CR>(5);`

			`auto cr2 = createRangeE<CR>(7);`
			`auto cr3 = createRangeE<CR>(11);`
			`auto cr4 = createRangeE<CR>(3);`
			`auto cr5 = createRangeE<CR>(13);`

			`dr1 = createRangeE<DR>(cr2,cr2,cr3,cr4);`
im com 2020-08-27 23:48:04 +02:00			`dr1a = createRangeE<DR>(cr2,cr2,cr3);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`dr2 = createRangeE<DR>(cr3,cr3,cr4);`
			`dr3 = createRangeE<DR>(cr2,cr5);`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`dr5 = createRangeE<DR>(cr5);`
			`dr6 = createRangeE<DR>(cr3,cr4);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`dr4 = createRangeE<DR>(cr2,cr3,cr4,cr4);`

			`ma1 = mkArray<double>(cr1,dr1);`
			`ma2 = mkArray<double>(cr1,dr2);`
			`ma3 = mkArray<double>(dr3);`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`ma5 = mkArray<double>(dr5);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`res1 = mkArray<double>(cr1,dr4);`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`res2 = mkArray<double>(cr1,dr6);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`setMARandom(ma1, 25);`
			`setMARandom(ma2, 31);`
			`setMARandom(ma3, 47);`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`setMARandom(ma5, 59);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`imap["i2_1"] = mkIndexW(getIndex(cr2));`
			`imap["i2_2"] = mkIndexW(getIndex(cr2));`
			`imap["i3_1"] = mkIndexW(getIndex(cr3));`
			`imap["i3_2"] = mkIndexW(getIndex(cr3));`
im com 2020-08-27 23:48:04 +02:00			`ci4 = getIndex(cr4);`
			`imap["i4_1"] = mkIndexW(ci4);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`imap["i4_2"] = mkIndexW(getIndex(cr4));`
			`imap["i5_1"] = mkIndexW(getIndex(cr5));`
			`imap["i5_2"] = mkIndexW(getIndex(cr5));`
			`}`
			`};`

			`TEST_F(OpTest_Dyn, Multiply)`
			`{`
			`auto i1 = getIndex(cr1);`
			`auto di1 = getIndex(dr1);`
im com 2020-08-27 23:48:04 +02:00			`auto di1a = getIndex(dr1a);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`auto di2 = getIndex(dr2);`
			`auto di4 = getIndex(dr4);`

im com 2020-08-27 23:48:04 +02:00			`auto mi = mkMIndex(i1,di1a);`

WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`(*di1)({imap["i2_1"],imap["i2_2"],imap["i3_1"],imap["i4_1"]});`
im com 2020-08-27 23:48:04 +02:00			`(*di1a)({imap["i2_1"],imap["i2_2"],imap["i3_1"]});`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`(*di2)({imap["i3_1"],imap["i3_1"],imap["i4_2"]});`
			`(*di4)({imap["i2_1"],imap["i3_1"],imap["i4_1"],imap["i4_2"]});`

			`auto resx1 = res1;`
OpTest_Dyn, Multiply: add remaining tests: work 2020-08-24 17:39:56 +02:00			`auto resx2 = res1;`
			`auto resx3 = res1;`
im com 2020-08-27 23:48:04 +02:00			`auto resx4 = res1;`
im com 2020-08-28 13:46:12 +02:00			`auto xx = std::make_shared<decltype(resx4)>(resx4);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`res1(i1,di4) = ma1(i1,di1) * ma2(i1,di2);`
			`resx1(i1,di4) = mkDynOp(ma1(i1,di1)) * mkDynOp(ma2(i1,di2));`
OpTest_Dyn, Multiply: add remaining tests: work 2020-08-24 17:39:56 +02:00			`resx2(i1,di4) = mkDynOp(ma1(i1,di1) * ma2(i1,di2));`
			`resx3(i1,di4) = mkDynOp(mkDynOp(ma1(i1,di1)) * mkDynOp(ma2(i1,di2)));`
im com 2020-08-27 23:48:04 +02:00
			`auto op1 = mkDynOutOp(ma1(i1,di1) * ma2(i1,di2), ci4);`
im com 2020-08-28 13:46:12 +02:00			`auto op1x = ma1(i1,di1) * ma2(i1,di2);`
			`auto opr = resx4(i1,di4);`

			`auto loop = mkILoop(std::make_tuple(opr,op1,op1.data()->mOp), std::make_tuple(ci4),`
			`std::make_tuple(xx), std::make_tuple(opr.assign( op1.data()->mOp, ci4 )),`
im com 2020-08-27 23:48:04 +02:00			`//std::make_tuple(), std::make_tuple(),`
			`std::array<size_t,1>({1}), std::array<size_t,1>({0}));`
im com 2020-08-28 13:46:12 +02:00
			`/*`
			`auto loop = mkILoop(std::make_tuple(opr,op1x), std::make_tuple(ci4),`
			`std::make_tuple(xx), std::make_tuple(opr.assign( op1x, ci4 )),`
			`//std::make_tuple(), std::make_tuple(),`
			`std::array<size_t,1>({1}), std::array<size_t,1>({0}));`
			`*/`
im com 2020-08-27 23:48:04 +02:00			`//mi->ifor(1, loop)();`
im com 2020-08-28 13:46:12 +02:00			`mi->ifor(1, loop)();`
im com 2020-08-27 23:48:04 +02:00
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`auto i2_1 = imap.at("i2_1");`
			`auto i2_2 = imap.at("i2_2");`
			`auto i3_1 = imap.at("i3_1");`
			`auto i4_1 = imap.at("i4_1");`
			`auto i4_2 = imap.at("i4_2");`

			`for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){`
			`for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){`
			`size_t ii2_2 = 0;`
			`for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){`
			`for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){`
			`for(size_t ii4_2 = 0; ii4_2 != i4_2->max(); ++ii4_2){`
			`const size_t jr = (((ii1i2_1->max() + ii2_1)i3_1->max() + ii3_1)i4_1->max() + ii4_1)i4_2->max() + ii4_2;`
			`const size_t j1 = (((ii1i2_1->max() + ii2_1)i2_2->max() + ii2_2)i3_1->max() + ii3_1)i4_1->max() + ii4_1;`
			`const size_t j2 = ((ii1i3_1->max() + ii3_1)i3_1->max() + ii3_1)*i4_2->max() + ii4_2;`
OpTest_Dyn, Multiply: add remaining tests: work 2020-08-24 17:39:56 +02:00			`auto resv = xround(res1.vdata()[jr]);`
			`auto resx1v = xround(resx1.vdata()[jr]);`
			`auto resx2v = xround(resx2.vdata()[jr]);`
			`auto resx3v = xround(resx3.vdata()[jr]);`
			`auto x12 = xround(ma1.vdata()[j1]*ma2.vdata()[j2]);`
			`EXPECT_EQ( resv, x12 );`
			`EXPECT_EQ( resx1v, x12 );`
			`EXPECT_EQ( resx2v, x12 );`
			`EXPECT_EQ( resx3v, x12 );`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`}`
			`}`
			`}`
			`}`
			`//std::cout << std::endl;`
			`}`
			`}`

			`TEST_F(OpTest_Dyn, Contract)`
			`{`
dynamic contractions work 2020-08-26 17:05:44 +02:00			`auto i1 = getIndex(cr1);`
			`auto di1 = getIndex(dr1);`
			`auto di3 = getIndex(dr3);`
			`auto di5 = getIndex(dr5);`
			`auto di6 = getIndex(dr6);`

			`(*di1)({imap["i2_1"],imap["i2_1"],imap["i3_1"],imap["i4_1"]});`
			`(*di3)({imap["i2_1"],imap["i5_1"]});`
			`(*di5)({imap["i5_1"]});`
			`(*di6)({imap["i3_1"],imap["i4_1"]});`

			`auto resx1 = res2;`
			`auto resx2 = res2;`
			`auto resx3 = res2;`
			`res2(i1,di6) += (ma1(i1,di1) * ma5(di5)).c(di3);`
			`resx1(i1,di6) += (mkDynOp(ma1(i1,di1)) * mkDynOp(ma5(di5))).c(di3);`
			`resx2(i1,di6) += mkDynOp((ma1(i1,di1) * ma5(di5)).c(di3));`
			`resx3(i1,di6) += mkDynOp((mkDynOp(ma1(i1,di1)) * mkDynOp(ma5(di5))).c(di3));`

			`auto i2_1 = imap.at("i2_1");`
			`auto i3_1 = imap.at("i3_1");`
			`auto i4_1 = imap.at("i4_1");`
			`auto i5_1 = imap.at("i5_1");`

			`for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){`
			`for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){`
			`for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){`
			`double vv = 0;`
			`const size_t jr = (ii1i3_1->max() + ii3_1)i4_1->max() + ii4_1;`
			`for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){`
			`const size_t j1 = (((ii1i2_1->max() + ii2_1)i2_1->max() + ii2_1)i3_1->max() + ii3_1)i4_1->max() + ii4_1;`
			`for(size_t ii5_1 = 0; ii5_1 != i5_1->max(); ++ii5_1){`
			`const size_t j2 = ii5_1;`
			`vv += ma1.vdata()[j1] * ma5.vdata()[j2];`
			`}`
			`}`

			`auto resv = xround(res2.vdata()[jr]);`
			`auto resx1v = xround(resx1.vdata()[jr]);`
			`auto resx2v = xround(resx2.vdata()[jr]);`
			`auto resx3v = xround(resx3.vdata()[jr]);`
			`auto x12 = xround(vv);`
			`EXPECT_EQ( resv, x12 );`
			`EXPECT_EQ( resx1v, x12 );`
			`EXPECT_EQ( resx2v, x12 );`
			`EXPECT_EQ( resx3v, x12 );`
			`}`
			`}`
			`//std::cout << std::endl;`
			`}`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
			`}`

			`TEST_F(OpTest_Dyn, Functional)`
			`{`
dynamic functional operations work 2020-08-26 20:23:58 +02:00			`auto i1 = getIndex(cr1);`
			`auto di1 = getIndex(dr1);`
			`auto di2 = getIndex(dr2);`
			`auto di4 = getIndex(dr4);`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00
dynamic operation: dynamic index call by custom name works 2020-08-27 15:01:29 +02:00			`//(*di1)({imap["i2_1"],imap["i2_2"],imap["i3_1"],imap["i4_1"]});`
			`//(*di2)({imap["i3_1"],imap["i3_1"],imap["i4_2"]});`
			`//(*di4)({imap["i2_1"],imap["i3_1"],imap["i4_1"],imap["i4_2"]});`
			`(*di1)({"ia_1","ia_2","ib_1","ic_1"});`
			`(*di2)({"ib_1","ib_1","ic_2"});`
			`(*di4)({"ia_1","ib_1","ic_1","ic_2"});`
dynamic functional operations work 2020-08-26 20:23:58 +02:00
			`auto resx1 = res1;`
			`auto resx2 = res1;`
			`auto resx3 = res1;`
			`res1(i1,di4) = ma1(i1,di1) * exp(ma2(i1,di2));`
			`resx1(i1,di4) = mkDynOp(ma1(i1,di1)) * exp(mkDynOp(ma2(i1,di2)));`
			`resx2(i1,di4) = mkDynOp(ma1(i1,di1) * exp(ma2(i1,di2)));`
			`resx3(i1,di4) = mkDynOp(mkDynOp(ma1(i1,di1)) * mkDynOp(exp(mkDynOp(ma2(i1,di2)))));`

			`auto i2_1 = imap.at("i2_1");`
			`auto i2_2 = imap.at("i2_2");`
			`auto i3_1 = imap.at("i3_1");`
			`auto i4_1 = imap.at("i4_1");`
			`auto i4_2 = imap.at("i4_2");`

			`for(size_t ii1 = 0; ii1 != i1->max(); ++ii1){`
			`for(size_t ii2_1 = 0; ii2_1 != i2_1->max(); ++ii2_1){`
			`size_t ii2_2 = 0;`
			`for(size_t ii3_1 = 0; ii3_1 != i3_1->max(); ++ii3_1){`
			`for(size_t ii4_1 = 0; ii4_1 != i4_1->max(); ++ii4_1){`
			`for(size_t ii4_2 = 0; ii4_2 != i4_2->max(); ++ii4_2){`
			`const size_t jr = (((ii1i2_1->max() + ii2_1)i3_1->max() + ii3_1)i4_1->max() + ii4_1)i4_2->max() + ii4_2;`
			`const size_t j1 = (((ii1i2_1->max() + ii2_1)i2_2->max() + ii2_2)i3_1->max() + ii3_1)i4_1->max() + ii4_1;`
			`const size_t j2 = ((ii1i3_1->max() + ii3_1)i3_1->max() + ii3_1)*i4_2->max() + ii4_2;`
			`auto resv = xround(res1.vdata()[jr]);`
			`auto resx1v = xround(resx1.vdata()[jr]);`
			`auto resx2v = xround(resx2.vdata()[jr]);`
			`auto resx3v = xround(resx3.vdata()[jr]);`
			`auto x12 = xround(ma1.vdata()[j1]*exp(ma2.vdata()[j2]));`
			`EXPECT_EQ( resv, x12 );`
			`EXPECT_EQ( resx1v, x12 );`
			`EXPECT_EQ( resx2v, x12 );`
			`EXPECT_EQ( resx3v, x12 );`
			`}`
			`}`
			`}`
			`}`
			`//std::cout << std::endl;`
			`}`
WIP: dynamic operation classes 2020-07-13 01:00:35 +02:00			`}`

			`}`