コード例 #1
0
TEST(ComplexMatrixIOTest,OneByOneMatirx) {
	ComplexMatrix cm(1,1);
	cm(0,0).real = 1.0;
	cm(0,0).imag = 0.5;
	complexMatrixToBytes(cm,"cm.bin");
	ComplexMatrix cm2;
	bytesToComplexMatrix(cm2, "cm.bin");
	EXPECT_EQ(cm.GetRows(), cm2.GetRows());
	EXPECT_EQ(cm.GetCols(), cm2.GetCols());
	for (int i=0; i<cm.GetRows(); ++i) {
		for (int j=0; j<cm.GetCols(); ++j) {
			EXPECT_DOUBLE_EQ(cm(i,j).real, cm2(i,j).real);
			EXPECT_DOUBLE_EQ(cm(i,j).imag, cm2(i,j).imag);
		}
	}
}
コード例 #2
0
ChanMappingController::ChanMappingController(QObject *parent)
:  QObject(parent), currentMode(DAQ::AI60Demux), is_dual(false)
{
	
	if (!setupDefaults) {
		setupDefaults = true;
		// run once -- setup defaults array
		for (int i = 0; i < (int)DAQ::N_Modes; ++i) {
			ChanMap & cm (defaultMapping[i]);
			const unsigned numIntans = DAQ::ModeNumIntans[i], numChansPerIntan = DAQ::ModeNumChansPerIntan[i];
			cm.reserve(numIntans*numChansPerIntan);
			for (int j = 0; j < (int)numIntans; ++j)
				for (int k = 0; k < (int)numChansPerIntan; ++k)
					cm.push_back(defaultMappingForIntan(j, k, numChansPerIntan));
			ChanMap & cm2 (defaultMapping2[i]);
			const unsigned numIntans2 = DAQ::ModeNumIntans[i]*2;
			cm2.reserve(numIntans2*numChansPerIntan);
			for (int j = 0; j < (int)numIntans2; ++j)
				for (int k = 0; k < (int)numChansPerIntan; ++k)
					cm2.push_back(defaultMappingForIntan(j, k, numChansPerIntan));
		}
	}
	
    dialogParent = new QDialog(0);    
    dialog = new Ui::ChanMapping;
    dialog->setupUi(dialogParent);
	Connect(dialog->loadBut, SIGNAL(clicked()), this, SLOT(loadButPushed()));
	Connect(dialog->saveBut, SIGNAL(clicked()), this, SLOT(saveButPushed()));
    resetFromSettings();
}
コード例 #3
0
TEST(ComplexMatrixIOTest,ThousandByThousandMatirx) {
	ComplexMatrix cm(1000,1000);
	RandomNumberGenerator random;
	for (int i=0; i<cm.GetRows(); ++i) {
		for (int j=0; j<cm.GetCols(); ++j) {
			cm(i,j) = random.randomComplex();
		}
	}
	complexMatrixToBytes(cm,"cm.bin");
	ComplexMatrix cm2;
	bytesToComplexMatrix(cm2, "cm.bin");
	EXPECT_EQ(cm.GetRows(), cm2.GetRows());
	EXPECT_EQ(cm.GetCols(), cm2.GetCols());
	for (int i=0; i<cm.GetRows(); ++i) {
		for (int j=0; j<cm.GetCols(); ++j) {
			EXPECT_DOUBLE_EQ(cm(i,j).real, cm2(i,j).real);
			EXPECT_DOUBLE_EQ(cm(i,j).imag, cm2(i,j).imag);
		}
	}
}
コード例 #4
0
ファイル: ex2main.cpp プロジェクト: patrysia/Cwiczenie_2
int main(void)
{
    cout << "main by kk. Last updated 20.09.2011\n";

    ///////////////////////////////////////////////////////

    int it1[] = {84, 23, 84, 21, 120, 93, -131, 238}; 
    int it2[] = {249, 24, 82, 3};
    int it3[] = {439, 828, 39, 230, 95, 1, -242, 34};

    aghMatrix<int>* imptr1 = new aghMatrix<int>(2, 4);
    aghMatrix<int>* imptr2 = new aghMatrix<int>(4, 1);
    aghMatrix<int>* imptr3 = new aghMatrix<int>(4, 1);
    aghMatrix<int>* imptr4 = new aghMatrix<int>(2, 4);
    aghMatrix<int> imtest1, imtest2, imtest3;

    imtest1.setItems(4, 1, 249, 24, 82, 3);
    imtest2.setItems(2, 4, 500+23, 851, 123, 251, 215, 94, -373, 272);
    imtest3.setItems(2, 1, 28419, 22084);


    aghMatrix<int>& imref1 = *imptr1;
    aghMatrix<int>& imref2 = *imptr2;
    aghMatrix<int>& imref3 = *imptr3;
    aghMatrix<int>& imref4 = *imptr4;

    imptr1->setItems(it1);
    imptr2->setItems(it2);
    imref3 = imref2;
    imptr4->setItems(it3);

    // 1st test - operator przypisania
    showTestResult(1, imref3 == imtest1);

    // 2nd test - operator przypisania
    try
    {
        imref3 = imref3;
        showTestResult(2, imref3 == imref2);
    }
    catch(...)
    {
        showTestResult(2, false);
    }

    // 3rd test - jawne wywolanie destruktora
    imref2.~aghMatrix();
    try
    {
        showTestResult(3, imref3 != imref2);
    }
    catch(...)
    {
        showTestResult(3, false);
    }

    // 4th test - destruktor
    try
    {
        delete imptr2;
        showTestResult(4, true);
    }
    catch(...)
    {
        showTestResult(4, false);
    }

    // 5th test - kopiowanie wartosci
    showTestResult(5, imref3 == imtest1);

    // 6th test - operator dodawania
    try
    {
        showTestResult(6, (imref1+imref4) == imtest2);
    }
    catch(...)
    {
        showTestResult(6, false);
    }

    // 7th test - operator mnożenia
    aghMatrix<int> immulres;
    try
    {
        aghMatrix<int> immultmp = imref1*imref3;
        immulres = immultmp;
    }
    catch(...)
    {
        showTestResult(7, false);
    }

    showTestResult(7, immulres == imtest3);

    // 8th test - range test
    try
    {
        immulres(10, 11);
        immulres(10, -11);
    }
    catch(aghException& e)
    {
        showTestResult(8, true);
    }
    catch(...)
    {
        showTestResult(8, false);
    }

    // 9th test - dimesion test
    try
    {
        imref1+imref3;
    }
    catch(aghException& e)
    {
        showTestResult(9, true);
    }
    catch(...)
    {
        showTestResult(9, false);
    }

    // 10th test - dimesion test
    try
    {
        imref1*imref4;
    }
    catch(aghException& e)
    {
        showTestResult(10, true);
    }
    catch(...)
    {
        showTestResult(10, false);
    }
    /////////////////////////////////////////////////////

    char ct[] = {'b', 'k', 'l', 'd', 'h', 'z', 'd', 'j', 'z', 'x', 'c', 'n', 'b', 'k', 'z', 'd', 'w'};
    aghMatrix<char> cm1(3, 2);
    aghMatrix<char> cm2(3, 2);
    aghMatrix<char> cm3(2, 4);
    cm1.setItems(ct);
    cm2.setItems(ct+5);
    cm3.setItems(ct+8);

    aghMatrix<char> cmtest1, cmtest2;
    cmtest1.setItems(3, 2, 'a', 'n', 'u', 'c', 'e', 'b');
    cmtest2.setItems(3, 4, 'j', 't', 's', 'r', 's', 'x', 't', 'w', 's', 'v', 'p', 'k');

    // 11th test - operator dodawania
    try
    {
        showTestResult(11, (cm1+cm2) == cmtest1);
    }
    catch(...)
    {
        showTestResult(11, false);
    }

    // 12th test - operator mnożenia
    try
    {
        showTestResult(12, (cm1*cm3) == cmtest2);
    }
    catch(...)
    {
        showTestResult(12, false);
    }
    /////////////////////////////////////////////////////

    char* cpt[] = {"to", "jest", "tablica", "wyrazow", "o", "rozmiarze", "jedenascie", "ktore", "beda", "elementami", "macierzy"};
    aghMatrix<char*> cpm1(2, 3);
    aghMatrix<char*> cpm2(2, 3);
    aghMatrix<char*> cpm3(3, 1);
    aghMatrix<char*> cpm4;
    aghMatrix<char*> cpm5;
    aghMatrix<char*>* cpmptr1 = new aghMatrix<char*>(1, 1);
    aghMatrix<char*> cpmtest1, cpmtest2;

    cpm1.setItems(cpt);
    cpm2.setItems(cpt+5);
    cpm3.setItems(cpt+3);
    cpmptr1->setItem(0, 0, cpt[5]);
    cpmtest1.setItems(2, 3, "torzmiae", "jestdnaci", "tablickore", "wyrazobed", "oelmntai", "rozmiaecy");
    cpmtest2.setItems(2, 1, "oai", "wyrazomie");

    // 13th test - destruktor
    char* itemptr = cpmptr1->operator()(0,0);
    itemptr[0] = 'a';

    delete cpmptr1;
    showTestResult(13, strcmp(itemptr, cpt[5]) != 0);

    // 14th test - operator przypisania p1
    cpm5 = cpm4 = cpm3;
    showTestResult(14, (cpm3 == cpm4) && (cpm3 == cpm5));

    // 15th test - operator przypisania p2
    cpm5.setItem(0, 0, "nothing");
    showTestResult(15, (cpm3 == cpm4) && (cpm3 != cpm5) && (strcmp(cpm3(0,0), "wyrazow") == 0));

    // 16th test - operator przypisania
    cpm5 = cpm3;
    try
    {
        cpm5 = cpm5;

        showTestResult(16, cpm3 == cpm5);

    }
    catch(...)
    {
        showTestResult(16, false);
    }

    // 17th test - jawne wywolanie destruktora
    cpm5 = cpm3;
    cpm5.~aghMatrix();
    try
    {
        showTestResult(17, (cpm3 != cpm5));
    }
    catch(...)
    {
        showTestResult(17, false);
    }

    // 18th test - operator dodawania
    try
    {
        showTestResult(18, (cpm1+cpm2) == cpmtest1);
    }
    catch(...)
    {
        showTestResult(18, false);
    }
    // 19th test - operator mnożenia
    try
    {
        showTestResult(19, (cpm1*cpm3) == cpmtest2);
    }
    catch(...)
    {
        showTestResult(19, false);
    }
    /////////////////////////////////////////////////////

    aghComplex cmplxt1[] = {aghComplex(1,1), aghComplex(1,2), aghComplex(2,1), aghComplex(2,2), aghComplex(3,3), aghComplex(3,1), aghComplex(1,0), aghComplex(0,1)};
    aghComplex cmplxt2[] = {aghComplex(-1,2), aghComplex(0,3), aghComplex(2,6), aghComplex(3,2), aghComplex(3,4)};
    aghMatrix<aghComplex> cmplxm1(3, 2);
    aghMatrix<aghComplex> cmplxm2(2, 1);
    aghMatrix<aghComplex> cmplxm3(2, 1);
    aghMatrix<aghComplex> cmplxm4(2, 1);
    aghMatrix<aghComplex> cmplxmtest1(3, 1);
    aghMatrix<aghComplex> cmplxmtest2(2, 1);

    cmplxm1.setItems(cmplxt1);
    cmplxm2.setItems(cmplxt1+6);
    cmplxm3.setItems(cmplxt1+3);

    cmplxmtest1.setItems(cmplxt2);
    cmplxmtest2.setItems(cmplxt2+3);
    cmplxm4 = cmplxm2 + cmplxm3;

    // 20th test - operator dodawania
    try
    {
        showTestResult(20, cmplxm4 == cmplxmtest2);
    }
    catch(...)
    {
        showTestResult(20, false);
    }
    // 21th test - operator mnozenia
    try
    {
        showTestResult(21, (cmplxm1*cmplxm2) == cmplxmtest1);
    }
    catch(...)
    {
        showTestResult(21, false);
    }
    /////////////////////////////////////////////////////

    cout << "Finally, this is the end...\n";
    return 0;
}
コード例 #5
0
ファイル: sparse_solvers.cpp プロジェクト: PMBio/peer
template<typename Scalar> void sparse_solvers(int rows, int cols)
{
  double density = (std::max)(8./(rows*cols), 0.01);
  typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
  typedef Matrix<Scalar,Dynamic,1> DenseVector;
  // Scalar eps = 1e-6;

  DenseVector vec1 = DenseVector::Random(rows);

  std::vector<Vector2i> zeroCoords;
  std::vector<Vector2i> nonzeroCoords;

  // test triangular solver
  {
    DenseVector vec2 = vec1, vec3 = vec1;
    SparseMatrix<Scalar> m2(rows, cols);
    DenseMatrix refMat2 = DenseMatrix::Zero(rows, cols);

    // lower - dense
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeLowerTriangular, &zeroCoords, &nonzeroCoords);
    VERIFY_IS_APPROX(refMat2.template triangularView<Lower>().solve(vec2),
                     m2.template triangularView<Lower>().solve(vec3));

    // upper - dense
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeUpperTriangular, &zeroCoords, &nonzeroCoords);
    VERIFY_IS_APPROX(refMat2.template triangularView<Upper>().solve(vec2),
                     m2.template triangularView<Upper>().solve(vec3));
    VERIFY_IS_APPROX(refMat2.conjugate().template triangularView<Upper>().solve(vec2),
                     m2.conjugate().template triangularView<Upper>().solve(vec3));
    {
      SparseMatrix<Scalar> cm2(m2);
      //Index rows, Index cols, Index nnz, Index* outerIndexPtr, Index* innerIndexPtr, Scalar* valuePtr
      MappedSparseMatrix<Scalar> mm2(rows, cols, cm2.nonZeros(), cm2.outerIndexPtr(), cm2.innerIndexPtr(), cm2.valuePtr());
      VERIFY_IS_APPROX(refMat2.conjugate().template triangularView<Upper>().solve(vec2),
                       mm2.conjugate().template triangularView<Upper>().solve(vec3));
    }

    // lower - transpose
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeLowerTriangular, &zeroCoords, &nonzeroCoords);
    VERIFY_IS_APPROX(refMat2.transpose().template triangularView<Upper>().solve(vec2),
                     m2.transpose().template triangularView<Upper>().solve(vec3));

    // upper - transpose
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeUpperTriangular, &zeroCoords, &nonzeroCoords);
    VERIFY_IS_APPROX(refMat2.transpose().template triangularView<Lower>().solve(vec2),
                     m2.transpose().template triangularView<Lower>().solve(vec3));

    SparseMatrix<Scalar> matB(rows, rows);
    DenseMatrix refMatB = DenseMatrix::Zero(rows, rows);

    // lower - sparse
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeLowerTriangular);
    initSparse<Scalar>(density, refMatB, matB);
    refMat2.template triangularView<Lower>().solveInPlace(refMatB);
    m2.template triangularView<Lower>().solveInPlace(matB);
    VERIFY_IS_APPROX(matB.toDense(), refMatB);

    // upper - sparse
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeUpperTriangular);
    initSparse<Scalar>(density, refMatB, matB);
    refMat2.template triangularView<Upper>().solveInPlace(refMatB);
    m2.template triangularView<Upper>().solveInPlace(matB);
    VERIFY_IS_APPROX(matB, refMatB);

    // test deprecated API
    initSparse<Scalar>(density, refMat2, m2, ForceNonZeroDiag|MakeLowerTriangular, &zeroCoords, &nonzeroCoords);
    VERIFY_IS_APPROX(refMat2.template triangularView<Lower>().solve(vec2),
                     m2.template triangularView<Lower>().solve(vec3));
  }
}
コード例 #6
0
void resultCombiner(const char * name_dv1, const char * name_cm1, const int length1, const char * name_dv2, const char * name_cm2, const int length2, int ftr = 1, const char * outputNameStub = "output")
{
    TVectorD dv1(length1), dv2(length2);
    TMatrixT<double> cm1(length1, length1), cm2(length2, length2);
    double binLimits1[length1][2], binLimits2[length2][2], ccCov1[length1], ccCov2[length1];

    readDataVector(name_dv1, dv1, binLimits1, ftr, ccCov1);
    printf("Read data vector 1 (%d)\n",length1);

    readDataVector(name_dv2, dv2, binLimits2, ftr, ccCov2);
    printf("Read data vector 2 (%d)\n",length2);

    readCovMatrix(name_cm1, cm1);
    printf("Read covariance matrix 1\n");

    readCovMatrix(name_cm2, cm2);
    printf("Read covariance matrix 2\n");

    std::vector<double*> binLimits;
    std::vector<std::vector<int > > preU;
    int i1 = 0, i2 = 0;
    while(i1 < length1 || i2 < length2)
    {
        if(i1 < length1 && i2 < length2)
        {
            if((binLimits1[i1][1] + binLimits1[i1][0])/2 > binLimits2[i2][0] && (binLimits1[i1][1] + binLimits1[i1][0])/2 < binLimits2[i2][1])
            {
                binLimits.push_back(binLimits1[i1]);
                std::vector<int> tmp;
                tmp.push_back(i1);
                tmp.push_back(i2);
                preU.push_back(tmp);
                i1++;
                i2++;
            }
            else if((binLimits1[i1][1] + binLimits1[i1][0])/2 <= binLimits2[i2][0])
            {
                binLimits.push_back(binLimits1[i1]);
                std::vector<int> tmp;
                tmp.push_back(i1);
                tmp.push_back(-1);
                preU.push_back(tmp);
                i1++;
            }
            else
            {
                binLimits.push_back(binLimits2[i2]);
                std::vector<int> tmp;
                tmp.push_back(-1);
                tmp.push_back(i2);
                preU.push_back(tmp);
                i2++;
            }
        }
        else if(i1 < length1 && i2 >= length2)
        {
            binLimits.push_back(binLimits1[i1]);
            std::vector<int> tmp;
            tmp.push_back(i1);
            tmp.push_back(-1);
            preU.push_back(tmp);
            i1++;
        }
        else
        {
            binLimits.push_back(binLimits2[i2]);
            std::vector<int> tmp;
            tmp.push_back(-1);
            tmp.push_back(i2);
            preU.push_back(tmp);
            i2++;
        }
    }

    TVectorD dv(length1 + length2);
    for(int i = 0; i < length1 + length2; i++)
    {
        dv[i] = (i < length1) ? dv1[i] : dv2[i - length1];
    }

    TMatrixT<double> cm(length1 + length2, length1 + length2), U(length1 + length2, preU.size());
    for(int i = 0; i < length1; i++)
    {
        for(int j = 0; j < length1; j++)
        {
            cm[i][j] = cm1[i][j];
        }
    }
    for(int i = length1; i < length1 + length2; i++)
    {
        for(int j = length1; j < length1 + length2; j++)
        {
            cm[i][j] = cm2[i - length1][j - length1];
        }
    }

    for(unsigned int i = 0; i < preU.size(); i++)
    {
        if(preU[i][0] >= 0) U[preU[i][0]][i] = 1;
        if(preU[i][1] >= 0) U[preU[i][1] + length1][i] = 1;
        if(ftr > 1 && preU[i][0] >= 0 && preU[i][1] >= 0)  cm[preU[i][0]][preU[i][1] + length1] = cm[preU[i][1] + length1][preU[i][0]] = ccCov1[preU[i][0]]*ccCov2[preU[i][1]];
    }
    
    //    cm.Print();

    TMatrixT<double> Ut(U);
    Ut.T();

    TMatrixT<double> cmInv(cm);
    cmInv.Invert();
    TMatrixT<double> step1 = Ut * cmInv * U;
    TMatrixT<double> step2 = Ut * cmInv;
    TMatrixT<double> lambda = step1.Invert() * step2;
    TVectorD bV = lambda*dv;
    TMatrixT<double> bcm = (Ut * cmInv * U).Invert();

    printf("Done with combination.\n");

    //write output
    FILE *file;
    char bVoutName[128], CMoutName[128];
    sprintf(bVoutName, "%s_data.txt", outputNameStub);

    file = fopen(bVoutName, "w");
    if(file)
    {
        fprintf(file, "#\n#%9s %9s %9s %15s %15s\n", "Bin", "Y_min", "Y_max", "Value", "Uncertainty");
        for(int i = 0; i < bV.GetNoElements(); i++)
        {
            fprintf(file, " %9i %9.2f %9.2f %15e %15e\n", i + 1, binLimits[i][0], binLimits[i][1], bV[i], sqrt(bcm[i][i]));
        }
        fclose(file);
    }

    sprintf(CMoutName, "%s_covMat.txt", outputNameStub);

    file = fopen(CMoutName, "w");
    if(file)
    {
        fprintf(file, "#\n#%9s %9s %15s\n", "Bin i", "Bin j", "Value");
        for(int i = 0; i < bcm.GetNrows(); i++)
        {
            for(int j = 0; j < bcm.GetNcols(); j++)
            {
                fprintf(file, " %9i %9i %15e\n", i + 1, j + 1, bcm[i][j]);
            }
        }
        fclose(file);
    }
    printf("Output complete.\n");
}