| /* |
| * Licensed to the Apache Software Foundation (ASF) under one or more |
| * contributor license agreements. See the NOTICE file distributed with |
| * this work for additional information regarding copyright ownership. |
| * The ASF licenses this file to You under the Apache License, Version 2.0 |
| * (the "License"); you may not use this file except in compliance with |
| * the License. You may obtain a copy of the License at |
| * |
| * http://www.apache.org/licenses/LICENSE-2.0 |
| * |
| * Unless required by applicable law or agreed to in writing, software |
| * distributed under the License is distributed on an "AS IS" BASIS, |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| * See the License for the specific language governing permissions and |
| * limitations under the License. |
| */ |
| |
| package org.apache.commons.numbers.complex.streams; |
| |
| import org.apache.commons.numbers.complex.Complex; |
| |
| import org.junit.Assert; |
| import org.junit.Test; |
| |
| /** |
| * Tests for {@link ComplexUtils}. |
| */ |
| public class ComplexUtilsTest { |
| |
| private static final double inf = Double.POSITIVE_INFINITY; |
| private static final double negInf = Double.NEGATIVE_INFINITY; |
| private static final double nan = Double.NaN; |
| private static final double pi = Math.PI; |
| |
| private static final Complex negInfInf = Complex.ofCartesian(negInf, inf); |
| private static final Complex infNegInf = Complex.ofCartesian(inf, negInf); |
| private static final Complex infInf = Complex.ofCartesian(inf, inf); |
| private static final Complex negInfNegInf = Complex.ofCartesian(negInf, negInf); |
| private static final Complex infNaN = Complex.ofCartesian(inf, nan); |
| private static final Complex NAN = Complex.ofCartesian(nan, nan); |
| |
| private static Complex[] c; // complex array with real values even and imag |
| // values odd |
| private static Complex[] cr; // complex array with real values consecutive |
| private static Complex[] ci; // complex array with imag values consecutive |
| private static double[] d; // real array with consecutive vals |
| private static double[] di; // interleaved real array with consecutive vals, |
| // 'interleaved' length |
| private static float[] f; // real array with consecutive vals |
| private static float[] fi; // interleaved real array with consecutive vals, interleaved |
| // length |
| private static double[] sr; // real component of split array, evens |
| private static double[] si; // imag component of split array, odds |
| private static float[] sfr; // real component of split array, float, evens |
| private static float[] sfi; // imag component of split array, float, odds |
| private static String msg; // error message for AssertEquals |
| private static Complex[][] c2d, cr2d, ci2d; // for 2d methods |
| private static Complex[][][] c3d, cr3d, ci3d; // for 3d methods |
| private static Complex[][][][] c4d, cr4d, ci4d; // for 3d methods |
| private static double[][] di2d0, di2d1, sr2d, si2d; |
| private static double[][][] di3d0, di3d1, di3d2, sr3d, si3d; |
| private static double[][][][] di4d0, di4d1, di4d2, di4d3, sr4d, si4d; |
| private static float[][] fi2d0, fi2d1, sfr2d, sfi2d; |
| private static float[][][] fi3d0, fi3d1, fi3d2, sfr3d, sfi3d; |
| private static float[][][][] sfr4d, sfi4d; |
| |
| private static void setArrays() { // initial setup method |
| c = new Complex[10]; |
| cr = new Complex[10]; |
| ci = new Complex[10]; |
| d = new double[10]; |
| f = new float[10]; |
| di = new double[20]; |
| fi = new float[20]; |
| sr = new double[10]; |
| si = new double[10]; |
| sfr = new float[10]; |
| sfi = new float[10]; |
| c2d = new Complex[10][10]; |
| cr2d = new Complex[10][10]; |
| ci2d = new Complex[10][10]; |
| c3d = new Complex[10][10][10]; |
| cr3d = new Complex[10][10][10]; |
| ci3d = new Complex[10][10][10]; |
| c4d = new Complex[10][10][10][10]; |
| cr4d = new Complex[10][10][10][10]; |
| ci4d = new Complex[10][10][10][10]; |
| sr2d = new double[10][10]; |
| sr3d = new double[10][10][10]; |
| sr4d = new double[10][10][10][10]; |
| si2d = new double[10][10]; |
| si3d = new double[10][10][10]; |
| si4d = new double[10][10][10][10]; |
| sfr2d = new float[10][10]; |
| sfr3d = new float[10][10][10]; |
| sfr4d = new float[10][10][10][10]; |
| sfi2d = new float[10][10]; |
| sfi3d = new float[10][10][10]; |
| sfi4d = new float[10][10][10][10]; |
| di2d0 = new double[20][10]; |
| di2d1 = new double[10][20]; |
| di3d0 = new double[20][10][10]; |
| di3d1 = new double[10][20][10]; |
| di3d2 = new double[10][10][20]; |
| di4d0 = new double[20][10][10][10]; |
| di4d1 = new double[10][20][10][10]; |
| di4d2 = new double[10][10][20][10]; |
| di4d3 = new double[10][10][10][20]; |
| fi2d0 = new float[20][10]; |
| fi2d1 = new float[10][20]; |
| fi3d0 = new float[20][10][10]; |
| fi3d1 = new float[10][20][10]; |
| fi3d2 = new float[10][10][20]; |
| for (int i = 0; i < 20; i += 2) { |
| int halfI = i / 2; |
| |
| // Complex arrays |
| c[halfI] = Complex.ofCartesian(i, i + 1); |
| cr[halfI] = Complex.ofReal(halfI); |
| ci[halfI] = Complex.ofCartesian(0, halfI); |
| |
| // standalone - split equivalent to c |
| sr[halfI] = i; |
| si[halfI] = i + 1; |
| sfr[halfI] = i; |
| sfi[halfI] = i + 1; |
| |
| // depending on method used equivalents to cr or ci |
| d[halfI] = halfI; |
| f[halfI] = halfI; |
| |
| // interleaved - all equivalent to c2d |
| di[i] = i; |
| di[i + 1] = i + 1; |
| fi[i] = i; |
| fi[i + 1] = i + 1; |
| } |
| for (int i = 0; i < 10; i++) { |
| for (int j = 0; j < 20; j += 2) { |
| int halfJ = j / 2; |
| int real = 10 * i + j; |
| int imaginary = 10 * i + j + 1; |
| |
| // Complex arrays |
| c2d[i][halfJ] = Complex.ofCartesian(real, imaginary); |
| cr2d[i][halfJ] = Complex.ofReal(real); |
| ci2d[i][halfJ] = Complex.ofCartesian(0, imaginary); |
| |
| // standalone - split equivalent to c2d, standalone equivalent to cr2d or ci2d |
| sr2d[i][halfJ] = real; |
| si2d[i][halfJ] = imaginary; |
| sfr2d[i][halfJ] = real; |
| sfi2d[i][halfJ] = imaginary; |
| |
| // interleaved - all equivalent to c2d |
| di2d0[j][i] = 10 * halfJ + 2 * i; |
| di2d0[j + 1][i] = di2d0[j][i] + 1; |
| di2d1[i][j] = real; |
| di2d1[i][j + 1] = imaginary; |
| fi2d0[j][i] = 10 * halfJ + 2 * i; |
| fi2d0[j + 1][i] = fi2d0[j][i] + 1; |
| fi2d1[i][j] = real; |
| fi2d1[i][j + 1] = imaginary; |
| } |
| } |
| for (int i = 0; i < 10; i++) { |
| for (int j = 0; j < 10; j++) { |
| for (int k = 0; k < 20; k += 2) { |
| int halfK = k / 2; |
| int real = 100 * i + 10 * j + k; |
| int imaginary = 100 * i + 10 * j + k + 1; |
| |
| // Complex arrays |
| c3d[i][j][halfK] = Complex.ofCartesian(real, imaginary); |
| cr3d[i][j][halfK] = Complex.ofReal(real); |
| ci3d[i][j][halfK] = Complex.ofCartesian(0, imaginary); |
| |
| // standalone - split equivalent to c3d, standalone equivalent to cr3d or ci3d |
| sr3d[i][j][halfK] = real; |
| si3d[i][j][halfK] = imaginary; |
| sfr3d[i][j][halfK] = real; |
| sfi3d[i][j][halfK] = imaginary; |
| |
| // interleaved - all equivalent to c3d |
| di3d0[k][i][j] = 100 * halfK + 10 * i + 2 * j; |
| di3d0[k + 1][i][j] = di3d0[k][i][j] + 1; |
| di3d1[j][k][i] = 100 * j + 10 * halfK + 2 * i; |
| di3d1[j][k + 1][i] = di3d1[j][k][i] + 1; |
| di3d2[i][j][k] = real; |
| di3d2[i][j][k + 1] = imaginary; |
| fi3d0[k][i][j] = 100 * halfK + 10 * i + 2 * j; |
| fi3d0[k + 1][i][j] = fi3d0[k][i][j] + 1; |
| fi3d1[j][k][i] = 100 * j + 10 * halfK + 2 * i; |
| fi3d1[j][k + 1][i] = fi3d1[j][k][i] + 1; |
| fi3d2[i][j][k] = real; |
| fi3d2[i][j][k + 1] = imaginary; |
| } |
| } |
| } |
| for (int i = 0; i < 10; i++) { |
| for (int j = 0; j < 10; j++) { |
| for (int k = 0; k < 10; k++) { |
| for (int l = 0; l < 20; l += 2) { |
| int halfL = l / 2; |
| int real = 1000 * i + 100 * j + 10 * k + l; |
| int imaginary = 1000 * i + 100 * j + 10 * k + l + 1; |
| |
| // Complex arrays |
| c4d[i][j][k][halfL] = Complex.ofCartesian(real, imaginary); |
| cr4d[i][j][k][halfL] = Complex.ofReal(real); |
| ci4d[i][j][k][halfL] = Complex.ofCartesian(0, imaginary); |
| |
| // standalone - split equivalent to c4d, standalone equivalent to cr4d or ci4d |
| sr4d[i][j][k][halfL] = real; |
| si4d[i][j][k][halfL] = imaginary; |
| sfr4d[i][j][k][halfL] = real; |
| sfi4d[i][j][k][halfL] = imaginary; |
| |
| // interleaved - all equivalent to c4d |
| di4d0[l][i][j][k] = 1000 * halfL + 100 * i + 10 * j + 2 * k; |
| di4d0[l + 1][i][j][k] = di4d0[l][i][j][k] + 1; |
| di4d1[k][l][i][j] = 1000 * k + 100 * halfL + 10 * i + 2 * j; |
| di4d1[k][l + 1][i][j] = di4d1[k][l][i][j] + 1; |
| di4d2[j][k][l][i] = 1000 * j + 100 * k + 10 * halfL + 2 * i; |
| di4d2[j][k][l + 1][i] = di4d2[j][k][l][i] + 1; |
| di4d3[i][j][k][l] = real; |
| di4d3[i][j][k][l + 1] = imaginary; |
| } |
| } |
| } |
| } |
| msg = ""; |
| } |
| |
| @Test |
| public void testPolar2Complex() { |
| TestUtils.assertEquals(Complex.ONE, ComplexUtils.polar2Complex(1, 0), 10e-12); |
| TestUtils.assertEquals(Complex.ZERO, ComplexUtils.polar2Complex(0, 1), 10e-12); |
| TestUtils.assertEquals(Complex.ZERO, ComplexUtils.polar2Complex(0, -1), 10e-12); |
| TestUtils.assertEquals(Complex.I, ComplexUtils.polar2Complex(1, pi / 2), 10e-12); |
| TestUtils.assertEquals(Complex.I.negate(), ComplexUtils.polar2Complex(1, -pi / 2), 10e-12); |
| double r = 0; |
| for (int i = 0; i < 5; i++) { |
| r += i; |
| double theta = 0; |
| for (int j = 0; j < 20; j++) { |
| theta += pi / 6; |
| TestUtils.assertEquals(altPolar(r, theta), ComplexUtils.polar2Complex(r, theta), 10e-12); |
| } |
| theta = -2 * pi; |
| for (int j = 0; j < 20; j++) { |
| theta -= pi / 6; |
| TestUtils.assertEquals(altPolar(r, theta), ComplexUtils.polar2Complex(r, theta), 10e-12); |
| } |
| } |
| // 1D |
| double[] r1D = new double[11]; |
| double[] theta1D = new double[11]; |
| for (int i = 0; i < 11; i++) { |
| r1D[i] = i; |
| } |
| theta1D[5] = 0; |
| for (int i = 1; i < 5; i++) { |
| theta1D[5+i] = theta1D[5 + i - 1] + pi/6; |
| theta1D[5-i] = theta1D[5 + i + 1] - pi/6; |
| } |
| Complex[] observed1D = ComplexUtils.polar2Complex(r1D, theta1D); |
| Assert.assertEquals(r1D.length, observed1D.length); |
| for (int i = 0; i < r1D.length; i++) { |
| Assert.assertEquals(ComplexUtils.polar2Complex(r1D[i], theta1D[i]), observed1D[i]); |
| } |
| |
| // 2D |
| double[][] theta2D = new double[3][4]; |
| double[][] r2D = new double[3][4]; |
| for (int i = 0; i < 3; i++) { |
| for (int j = 0; j < 4; j++) { |
| r2D[i][j] = i + j; |
| theta2D[i][j] = i * j; |
| } |
| } |
| Complex[][] observed2D = ComplexUtils.polar2Complex(r2D, theta2D); |
| Assert.assertEquals(r2D.length, observed2D.length); |
| for (int i = 0; i < r2D.length; i++) { |
| TestUtils.assertSame(msg, ComplexUtils.polar2Complex(r2D[i], theta2D[i]), observed2D[i]); |
| } |
| |
| // 3D |
| double[][][] theta3D = new double[3][4][3]; |
| double[][][] r3D = new double[3][4][3]; |
| for (int i = 0; i < 3; i++) { |
| for (int j = 0; j < 4; j++) { |
| for (int k = 0; k < 3; k++) { |
| r3D[i][j][k] = i + j + k; |
| theta3D[i][j][k] = i * j * k; |
| } |
| } |
| } |
| Complex[][][] observed3D = ComplexUtils.polar2Complex(r3D, theta3D); |
| Assert.assertEquals(r3D.length, observed3D.length); |
| for (int i = 0; i < r3D.length; i++) { |
| TestUtils.assertSame(msg, ComplexUtils.polar2Complex(r3D[i], theta3D[i]), observed3D[i]); |
| } |
| } |
| |
| private Complex altPolar(double r, double theta) { |
| return Complex.I.multiply(Complex.ofCartesian(theta, 0)).exp().multiply(Complex.ofCartesian(r, 0)); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testPolar2ComplexIllegalModulus() { |
| ComplexUtils.polar2Complex(-1, 0); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testPolar2ComplexIllegalModulus1D() { |
| ComplexUtils.polar2Complex(new double[]{0, -1, 2}, new double[]{0, 1, 2}); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testPolar2ComplexIllegalModulus2D() { |
| ComplexUtils.polar2Complex(new double[][]{{0, 2, 2}, {0, -1, 2}}, new double[][]{{0, 1, 2}, {0, 1, 2}}); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testPolar2ComplexIllegalModulus3D() { |
| ComplexUtils.polar2Complex(new double[][][]{{{0, 2, 2}}, {{0, -1, 2}}}, new double[][][]{{{0, 1, 2}}, {{0, 1, 2}}}); |
| } |
| |
| @Test |
| public void testPolar2ComplexNaN() { |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(nan, 1)); |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(1, nan)); |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(nan, nan)); |
| } |
| |
| @Test |
| public void testPolar2ComplexInf() { |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(1, inf)); |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(1, negInf)); |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(inf, inf)); |
| TestUtils.assertSame(NAN, ComplexUtils.polar2Complex(inf, negInf)); |
| TestUtils.assertSame(infInf, ComplexUtils.polar2Complex(inf, pi / 4)); |
| TestUtils.assertSame(infNaN, ComplexUtils.polar2Complex(inf, 0)); |
| TestUtils.assertSame(infNegInf, ComplexUtils.polar2Complex(inf, -pi / 4)); |
| TestUtils.assertSame(negInfInf, ComplexUtils.polar2Complex(inf, 3 * pi / 4)); |
| TestUtils.assertSame(negInfNegInf, ComplexUtils.polar2Complex(inf, 5 * pi / 4)); |
| } |
| |
| @Test |
| public void testCExtract() { |
| final double[] real = new double[] { negInf, -123.45, 0, 1, 234.56, pi, inf }; |
| final Complex[] complex = ComplexUtils.real2Complex(real); |
| |
| for (int i = 0; i < real.length; i++) { |
| Assert.assertEquals(real[i], complex[i].getReal(), 0d); |
| } |
| } |
| |
| // EXTRACTION METHODS |
| |
| @Test |
| public void testExtractionMethods() { |
| setArrays(); |
| // Extract complex from real double array, index 3 |
| TestUtils.assertSame(Complex.ofReal(3), ComplexUtils.extractComplexFromRealArray(d, 3)); |
| // Extract complex from real float array, index 3 |
| TestUtils.assertSame(Complex.ofReal(3), ComplexUtils.extractComplexFromRealArray(f, 3)); |
| // Extract complex from real double array, index 3 |
| TestUtils.assertSame(Complex.ofCartesian(0, 3), ComplexUtils.extractComplexFromImaginaryArray(d, 3)); |
| // Extract complex from real float array, index 3 |
| TestUtils.assertSame(Complex.ofCartesian(0, 3), ComplexUtils.extractComplexFromImaginaryArray(f, 3)); |
| // Extract real double from complex array, index 3 |
| TestUtils.assertSame(6, ComplexUtils.extractRealFromComplexArray(c, 3)); |
| // Extract real float from complex array, index 3 |
| TestUtils.assertSame(6, ComplexUtils.extractRealFloatFromComplexArray(c, 3)); |
| // Extract real double from complex array, index 3 |
| TestUtils.assertSame(7, ComplexUtils.extractImaginaryFromComplexArray(c, 3)); |
| // Extract real float from complex array, index 3 |
| TestUtils.assertSame(7, ComplexUtils.extractImaginaryFloatFromComplexArray(c, 3)); |
| // Extract complex from interleaved double array, index 3 |
| TestUtils.assertSame(Complex.ofCartesian(6, 7), ComplexUtils.extractComplexFromInterleavedArray(d, 3)); |
| // Extract interleaved double array from complex array, index 3 |
| TestUtils.assertSame(new double[]{6d, 7d}, ComplexUtils.extractInterleavedFromComplexArray(c, 3)); |
| // Extract interleaved float array from complex array, index 3 |
| TestUtils.assertSame(new float[]{6f, 7f}, ComplexUtils.extractInterleavedFloatFromComplexArray(c, 3)); |
| // Extract complex from interleaved float array, index 3 |
| TestUtils.assertSame(Complex.ofCartesian(6, 7), ComplexUtils.extractComplexFromInterleavedArray(f, 3)); |
| // Extract interleaved double from complex array, index 3 |
| TestUtils.assertEquals(msg, new double[] { 6, 7 }, ComplexUtils.extractInterleavedFromComplexArray(c, 3), |
| Math.ulp(1)); |
| // Extract interleaved float from complex array, index 3 |
| TestUtils.assertEquals(msg, new double[] { 6, 7 }, ComplexUtils.extractInterleavedFromComplexArray(c, 3), |
| Math.ulp(1)); |
| } |
| // REAL <-> COMPLEX |
| |
| @Test |
| public void testRealToComplex() { |
| setArrays(); |
| // Real double to complex, whole array |
| TestUtils.assertEquals(msg, cr, ComplexUtils.real2Complex(d), Math.ulp(1.0)); |
| // Real float to complex, whole array |
| TestUtils.assertEquals(msg, cr, ComplexUtils.real2Complex(f), Math.ulp(1.0)); |
| |
| // 2d |
| TestUtils.assertEquals(msg, cr2d, ComplexUtils.real2Complex(sr2d), 0); |
| TestUtils.assertEquals(msg, cr2d, ComplexUtils.real2Complex(sfr2d), 0); |
| |
| // 3d |
| TestUtils.assertEquals(msg, cr3d, ComplexUtils.real2Complex(sr3d), 0); |
| TestUtils.assertEquals(msg, cr3d, ComplexUtils.real2Complex(sfr3d), 0); |
| |
| // 4d |
| TestUtils.assertEquals(msg, cr4d, ComplexUtils.real2Complex(sr4d), 0); |
| } |
| |
| @Test |
| public void testComplexToReal() { |
| setArrays(); |
| // Real complex to double, whole array |
| TestUtils.assertEquals(msg, sr, ComplexUtils.complex2Real(c), Math.ulp(1.0)); |
| // Real complex to float, whole array |
| TestUtils.assertEquals(msg, sfr, ComplexUtils.complex2RealFloat(c), Math.ulp(1.0f)); |
| |
| // 2d |
| TestUtils.assertEquals(msg, sr2d, ComplexUtils.complex2Real(cr2d), 0); |
| TestUtils.assertEquals(msg, sfr2d, ComplexUtils.complex2RealFloat(cr2d), 0); |
| |
| // 3d |
| TestUtils.assertEquals(msg, sr3d, ComplexUtils.complex2Real(cr3d), 0); |
| TestUtils.assertEquals(msg, sfr3d, ComplexUtils.complex2RealFloat(cr3d), 0); |
| |
| // 4d |
| TestUtils.assertEquals(msg, sr4d, ComplexUtils.complex2Real(cr4d), 0); |
| TestUtils.assertEquals(msg, sfr4d, ComplexUtils.complex2RealFloat(cr4d), 0); |
| } |
| |
| // IMAGINARY <-> COMPLEX |
| |
| @Test |
| public void testImaginaryToComplex() { |
| setArrays(); |
| // Imaginary double to complex, whole array |
| TestUtils.assertEquals(msg, ci, ComplexUtils.imaginary2Complex(d), Math.ulp(1.0)); |
| // Imaginary float to complex, whole array |
| TestUtils.assertEquals(msg, ci, ComplexUtils.imaginary2Complex(f), Math.ulp(1.0)); |
| |
| // 2d |
| TestUtils.assertEquals(msg, ci2d, ComplexUtils.imaginary2Complex(si2d), 0); |
| |
| // 3d |
| TestUtils.assertEquals(msg, ci3d, ComplexUtils.imaginary2Complex(si3d), 0); |
| |
| // 4d |
| TestUtils.assertEquals(msg, ci4d, ComplexUtils.imaginary2Complex(si4d), 0); |
| } |
| |
| @Test |
| public void testComplexToImaginary() { |
| setArrays(); |
| // Imaginary complex to double, whole array |
| TestUtils.assertEquals(msg, si, ComplexUtils.complex2Imaginary(c), Math.ulp(1.0)); |
| // Imaginary complex to float, whole array |
| TestUtils.assertEquals(msg, sfi, ComplexUtils.complex2ImaginaryFloat(c), Math.ulp(1.0f)); |
| |
| // 2d |
| TestUtils.assertEquals(msg, si2d, ComplexUtils.complex2Imaginary(ci2d), 0); |
| TestUtils.assertEquals(msg, sfi2d, ComplexUtils.complex2ImaginaryFloat(ci2d), 0); |
| |
| // 3d |
| TestUtils.assertEquals(msg, si3d, ComplexUtils.complex2Imaginary(ci3d), 0); |
| TestUtils.assertEquals(msg, sfi3d, ComplexUtils.complex2ImaginaryFloat(ci3d), 0); |
| |
| // 4d |
| TestUtils.assertEquals(msg, si4d, ComplexUtils.complex2Imaginary(ci4d), 0); |
| TestUtils.assertEquals(msg, sfi4d, ComplexUtils.complex2ImaginaryFloat(ci4d), 0); |
| } |
| |
| // INTERLEAVED <-> COMPLEX |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex2Dmin() { |
| ComplexUtils.complex2Interleaved(c2d, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex2Dmax() { |
| ComplexUtils.complex2Interleaved(c2d, 2); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex3Dmin() { |
| ComplexUtils.complex2Interleaved(c3d, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex3Dmax() { |
| ComplexUtils.complex2Interleaved(c3d, 3); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex4Dmin() { |
| ComplexUtils.complex2Interleaved(c4d, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedIllegalIndex4Dmax() { |
| ComplexUtils.complex2Interleaved(c4d, 4); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedFloatIllegalIndex2Dmin() { |
| ComplexUtils.complex2InterleavedFloat(c2d, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedFloatIllegalIndex2Dmax() { |
| ComplexUtils.complex2InterleavedFloat(c2d, 2); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedFloatIllegalIndex3Dmin() { |
| ComplexUtils.complex2InterleavedFloat(c3d, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testComplex2InterleavedFloatIllegalIndex3Dmax() { |
| ComplexUtils.complex2InterleavedFloat(c3d, 3); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex2Dmin() { |
| ComplexUtils.interleaved2Complex(di2d0, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex2Dmax() { |
| ComplexUtils.interleaved2Complex(di2d0, 2); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex3Dmin() { |
| ComplexUtils.interleaved2Complex(di3d0, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex3Dmax() { |
| ComplexUtils.interleaved2Complex(di3d0, 3); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex4Dmin() { |
| ComplexUtils.interleaved2Complex(di4d0, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexIllegalIndex4Dmax() { |
| ComplexUtils.interleaved2Complex(di4d0, 4); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexFloatIllegalIndex2Dmin() { |
| ComplexUtils.interleaved2Complex(fi2d0, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexFloatIllegalIndex2Dmax() { |
| ComplexUtils.interleaved2Complex(fi2d0, 2); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexFloatIllegalIndex3Dmin() { |
| ComplexUtils.interleaved2Complex(fi3d0, -1); |
| } |
| |
| @Test(expected = IllegalArgumentException.class) |
| public void testInterleaved2ComplexFloatIllegalIndex3Dmax() { |
| ComplexUtils.interleaved2Complex(fi3d0, 3); |
| } |
| |
| @Test |
| public void testInterleavedToComplex() { |
| setArrays(); |
| // Interleaved double to complex, whole array |
| TestUtils.assertEquals(msg, c, ComplexUtils.interleaved2Complex(di), Math.ulp(1.0)); |
| // Interleaved float to complex, whole array |
| TestUtils.assertEquals(msg, c, ComplexUtils.interleaved2Complex(fi), Math.ulp(1.0)); |
| |
| // 2d |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(di2d0, 0)); |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(di2d1, 1)); |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(di2d1)); |
| |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(fi2d0, 0)); |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(fi2d1, 1)); |
| TestUtils.assertSame(msg, c2d, ComplexUtils.interleaved2Complex(fi2d1)); |
| |
| // 3d |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(di3d0, 0)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(di3d1, 1)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(di3d2, 2)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(di3d2)); |
| |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(fi3d0, 0)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(fi3d1, 1)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(fi3d2, 2)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.interleaved2Complex(fi3d2)); |
| |
| // 4d |
| TestUtils.assertSame(msg, c4d, ComplexUtils.interleaved2Complex(di4d0, 0)); |
| TestUtils.assertSame(msg, c4d, ComplexUtils.interleaved2Complex(di4d1, 1)); |
| TestUtils.assertSame(msg, c4d, ComplexUtils.interleaved2Complex(di4d2, 2)); |
| TestUtils.assertSame(msg, c4d, ComplexUtils.interleaved2Complex(di4d3, 3)); |
| } |
| |
| @Test |
| public void testComplexToInterleaved() { |
| setArrays(); |
| TestUtils.assertEquals(msg, di, ComplexUtils.complex2Interleaved(c), Math.ulp(1.0)); |
| // Interleaved complex to float, whole array |
| TestUtils.assertEquals(msg, fi, ComplexUtils.complex2InterleavedFloat(c), Math.ulp(1.0f)); |
| |
| // 2d |
| TestUtils.assertEquals(msg, di2d0, ComplexUtils.complex2Interleaved(c2d, 0), 0); |
| TestUtils.assertEquals(msg, di2d1, ComplexUtils.complex2Interleaved(c2d, 1), 0); |
| TestUtils.assertEquals(msg, di2d1, ComplexUtils.complex2Interleaved(c2d), 0); |
| |
| TestUtils.assertEquals(msg, fi2d0, ComplexUtils.complex2InterleavedFloat(c2d, 0), 0); |
| TestUtils.assertEquals(msg, fi2d1, ComplexUtils.complex2InterleavedFloat(c2d, 1), 0); |
| TestUtils.assertEquals(msg, fi2d1, ComplexUtils.complex2InterleavedFloat(c2d), 0); |
| |
| // 3d |
| TestUtils.assertEquals(msg, di3d0, ComplexUtils.complex2Interleaved(c3d, 0), 0); |
| TestUtils.assertEquals(msg, di3d1, ComplexUtils.complex2Interleaved(c3d, 1), 0); |
| TestUtils.assertEquals(msg, di3d2, ComplexUtils.complex2Interleaved(c3d, 2), 0); |
| TestUtils.assertEquals(msg, di3d2, ComplexUtils.complex2Interleaved(c3d), 0); |
| |
| TestUtils.assertEquals(msg, fi3d0, ComplexUtils.complex2InterleavedFloat(c3d, 0), 0); |
| TestUtils.assertEquals(msg, fi3d1, ComplexUtils.complex2InterleavedFloat(c3d, 1), 0); |
| TestUtils.assertEquals(msg, fi3d2, ComplexUtils.complex2InterleavedFloat(c3d, 2), 0); |
| TestUtils.assertEquals(msg, fi3d2, ComplexUtils.complex2InterleavedFloat(c3d), 0); |
| |
| // 4d |
| TestUtils.assertEquals(msg, di4d0, ComplexUtils.complex2Interleaved(c4d, 0), 0); |
| TestUtils.assertEquals(msg, di4d1, ComplexUtils.complex2Interleaved(c4d, 1), 0); |
| TestUtils.assertEquals(msg, di4d2, ComplexUtils.complex2Interleaved(c4d, 2), 0); |
| TestUtils.assertEquals(msg, di4d3, ComplexUtils.complex2Interleaved(c4d, 3), 0); |
| TestUtils.assertEquals(msg, di4d3, ComplexUtils.complex2Interleaved(c4d), 0); |
| } |
| |
| // SPLIT TO COMPLEX |
| @Test |
| public void testSplit2Complex() { |
| setArrays(); |
| // Split double to complex, whole array |
| TestUtils.assertEquals(msg, c, ComplexUtils.split2Complex(sr, si), Math.ulp(1.0)); |
| |
| TestUtils.assertSame(msg, c2d, ComplexUtils.split2Complex(sr2d, si2d)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.split2Complex(sr3d, si3d)); |
| TestUtils.assertSame(msg, c4d, ComplexUtils.split2Complex(sr4d, si4d)); |
| TestUtils.assertSame(msg, c2d, ComplexUtils.split2Complex(sfr2d, sfi2d)); |
| TestUtils.assertSame(msg, c3d, ComplexUtils.split2Complex(sfr3d, sfi3d)); |
| } |
| |
| // INITIALIZATION METHODS |
| |
| @Test |
| public void testInitialize() { |
| Complex[] c = new Complex[10]; |
| ComplexUtils.initialize(c); |
| for (Complex cc : c) { |
| TestUtils.assertEquals(Complex.ofCartesian(0, 0), cc, Math.ulp(0)); |
| } |
| } |
| |
| @Test |
| public void testInitialize2d() { |
| Complex[][] c = new Complex[10][10]; |
| ComplexUtils.initialize(c); |
| for (Complex[] c1 : c) { |
| for (Complex c0 : c1) { |
| TestUtils.assertEquals(Complex.ofCartesian(0, 0), c0, Math.ulp(0)); |
| } |
| } |
| } |
| |
| @Test |
| public void testInitialize3d() { |
| Complex[][][] c = new Complex[10][10][10]; |
| ComplexUtils.initialize(c); |
| for (Complex[][] c2 : c) { |
| for (Complex[] c1 : c2) { |
| for (Complex c0 : c1) { |
| TestUtils.assertEquals(Complex.ofCartesian(0, 0), c0, Math.ulp(0)); |
| } |
| } |
| } |
| } |
| |
| @Test |
| public void testAbs() { |
| setArrays(); |
| double[] observed = ComplexUtils.abs(c); |
| Assert.assertEquals(c.length, observed.length); |
| for (int i = 0; i < c.length; i++) { |
| TestUtils.assertEquals(c[i].abs(), observed[i], 0); |
| } |
| } |
| |
| @Test |
| public void testArg() { |
| setArrays(); |
| double[] observed = ComplexUtils.arg(c); |
| Assert.assertEquals(c.length, observed.length); |
| for (int i = 0; i < c.length; i++) { |
| TestUtils.assertEquals(c[i].getArgument(), observed[i], 0); |
| } |
| } |
| } |