test/java/lang/Math/PowTests.java - platform/external/jetbrains/jdk8u_jdk - Git at Google

 /*
  * Copyright (c) 2004, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 /*
  * @test
  * @bug 4984407 5033578
  * @summary Tests for {Math, StrictMath}.pow
  * @author Joseph D. Darcy
  */

 public class PowTests {
     private PowTests(){}

     static final double infinityD = Double.POSITIVE_INFINITY;

     static int testPowCase(double input1, double input2, double expected) {
         int failures = 0;
         failures += Tests.test("StrictMath.pow(double, double)", input1, input2,
                                StrictMath.pow(input1, input2), expected);
         failures += Tests.test("Math.pow(double, double)", input1, input2,
                                Math.pow(input1, input2), expected);
         return failures;
     }


     static int testStrictPowCase(double input1, double input2, double expected) {
         int failures = 0;
         failures += Tests.test("StrictMath.pow(double, double)", input1, input2,
                                StrictMath.pow(input1, input2), expected);
         return failures;
     }

     static int testNonstrictPowCase(double input1, double input2, double expected) {
         int failures = 0;
         failures += Tests.test("Math.pow(double, double)", input1, input2,
                                Math.pow(input1, input2), expected);
         return failures;
     }

     /*
      * Test for bad negation implementation.
      */
     static int testPow() {
         int failures = 0;

         double [][] testCases = {
             {-0.0,               3.0,   -0.0},
             {-0.0,               4.0,    0.0},
             {-infinityD,        -3.0,   -0.0},
             {-infinityD,        -4.0,    0.0},
         };

         for (double[] testCase : testCases) {
             failures+=testPowCase(testCase[0], testCase[1], testCase[2]);
         }

         return failures;
     }

     /*
      * Test cross-product of different kinds of arguments.
      */
     static int testCrossProduct() {
         int failures = 0;

         double testData[] = {
                                 Double.NEGATIVE_INFINITY,
 /* > -oo */                     -Double.MAX_VALUE,
 /**/                            (double)Long.MIN_VALUE,
 /**/                            (double) -((1L<<53)+2L),
 /**/                            (double) -((1L<<53)),
 /**/                            (double) -((1L<<53)-1L),
 /**/                            -((double)Integer.MAX_VALUE + 4.0),
 /**/                            (double)Integer.MIN_VALUE - 1.0,
 /**/                            (double)Integer.MIN_VALUE,
 /**/                            (double)Integer.MIN_VALUE + 1.0,
 /**/                            -Math.PI,
 /**/                            -3.0,
 /**/                            -Math.E,
 /**/                            -2.0,
 /**/                            -1.0000000000000004,
 /* < -1.0 */                    -1.0000000000000002, // nextAfter(-1.0, -oo)
                                 -1.0,
 /* > -1.0 */                    -0.9999999999999999, // nextAfter(-1.0, +oo)
 /* > -1.0 */                    -0.9999999999999998,
 /**/                            -0.5,
 /**/                            -1.0/3.0,
 /* < 0.0 */                     -Double.MIN_VALUE,
                                 -0.0,
                                 +0.0,
 /* > 0.0 */                     +Double.MIN_VALUE,
 /**/                            +1.0/3.0,
 /**/                            +0.5,
 /**/                            +0.9999999999999998,
 /* < +1.0 */                    +0.9999999999999999, // nextAfter(-1.0, +oo)
                                 +1.0,
 /* > 1.0 */                     +1.0000000000000002, // nextAfter(+1.0, +oo)
 /**/                            +1.0000000000000004,
 /**/                            +2.0,
 /**/                            +Math.E,
 /**/                            +3.0,
 /**/                            +Math.PI,
 /**/                            -(double)Integer.MIN_VALUE - 1.0,
 /**/                            -(double)Integer.MIN_VALUE,
 /**/                            -(double)Integer.MIN_VALUE + 1.0,
 /**/                            (double)Integer.MAX_VALUE + 4.0,
 /**/                            (double) ((1L<<53)-1L),
 /**/                            (double) ((1L<<53)),
 /**/                            (double) ((1L<<53)+2L),
 /**/                            -(double)Long.MIN_VALUE,
 /* < oo */                      Double.MAX_VALUE,
                                 Double.POSITIVE_INFINITY,
                                 Double.NaN
     };

         double NaN = Double.NaN;
         for(double x: testData) {
             for(double y: testData) {
                 boolean testPass = false;
                 double expected=NaN;
                 double actual;

                 // First, switch on y
                 if( Double.isNaN(y)) {
                     expected = NaN;
                 } else if (y == 0.0) {
                     expected = 1.0;
                 } else if (Double.isInfinite(y) ) {
                     if(y > 0) { // x ^ (+oo)
                         if (Math.abs(x) > 1.0) {
                             expected = Double.POSITIVE_INFINITY;
                         } else if (Math.abs(x) == 1.0) {
                             expected = NaN;
                         } else if (Math.abs(x) < 1.0) {
                             expected = +0.0;
                         } else { // x is NaN
                             assert Double.isNaN(x);
                             expected = NaN;
                         }
                     } else { // x ^ (-oo)
                         if (Math.abs(x) > 1.0) {
                             expected = +0.0;
                         } else if (Math.abs(x) == 1.0) {
                             expected = NaN;
                         } else if (Math.abs(x) < 1.0) {
                             expected = Double.POSITIVE_INFINITY;
                         } else { // x is NaN
                             assert Double.isNaN(x);
                             expected = NaN;
                         }
                     } /* end Double.isInfinite(y) */
                 } else if (y == 1.0) {
                     expected = x;
                 } else if (Double.isNaN(x)) { // Now start switching on x
                     assert y != 0.0;
                     expected = NaN;
                 } else if (x == Double.NEGATIVE_INFINITY) {
                     expected = (y < 0.0) ? f2(y) :f1(y);
                 } else if (x == Double.POSITIVE_INFINITY) {
                     expected = (y < 0.0) ? +0.0 : Double.POSITIVE_INFINITY;
                 } else if (equivalent(x, +0.0)) {
                     assert y != 0.0;
                     expected = (y < 0.0) ? Double.POSITIVE_INFINITY: +0.0;
                 } else if (equivalent(x, -0.0)) {
                     assert y != 0.0;
                     expected = (y < 0.0) ? f1(y): f2(y);
                 } else if( x < 0.0) {
                     assert y != 0.0;
                     failures += testStrictPowCase(x, y, f3(x, y));
                     failures += testNonstrictPowCase(x, y, f3ns(x, y));
                     continue;
                 } else {
                     // go to next iteration
                     expected = NaN;
                     continue;
                 }

                 failures += testPowCase(x, y, expected);
             } // y
         } // x
         return failures;
     }

     static boolean equivalent(double a, double b) {
         return Double.compare(a, b) == 0;
     }

     static double f1(double y) {
         return (intClassify(y) == 1)?
             Double.NEGATIVE_INFINITY:
             Double.POSITIVE_INFINITY;
     }


     static double f2(double y) {
         return (intClassify(y) == 1)?-0.0:0.0;
     }

     static double f3(double x, double y) {
         switch( intClassify(y) ) {
         case 0:
             return StrictMath.pow(Math.abs(x), y);
             // break;

         case 1:
             return -StrictMath.pow(Math.abs(x), y);
             // break;

         case -1:
             return Double.NaN;
             // break;

         default:
             throw new AssertionError("Bad classification.");
             // break;
         }
     }

     static double f3ns(double x, double y) {
         switch( intClassify(y) ) {
         case 0:
             return Math.pow(Math.abs(x), y);
             // break;

         case 1:
             return -Math.pow(Math.abs(x), y);
             // break;

         case -1:
             return Double.NaN;
             // break;

         default:
             throw new AssertionError("Bad classification.");
             // break;
         }
     }

     static boolean isFinite(double a) {
         return (0.0*a  == 0);
     }

     /**
      * Return classification of argument: -1 for non-integers, 0 for
      * even integers, 1 for odd integers.
      */
     static int intClassify(double a) {
         if(!isFinite(a) || // NaNs and infinities
            (a != Math.floor(a) )) { // only integers are fixed-points of floor
                 return -1;
         }
         else {
             // Determine if argument is an odd or even integer.

             a = StrictMath.abs(a); // absolute value doesn't affect odd/even

             if(a+1.0 == a) { // a > maximum odd floating-point integer
                 return 0; // Large integers are all even
             }
             else { // Convert double -> long and look at low-order bit
                 long ell = (long)  a;
                 return ((ell & 0x1L) == (long)1)?1:0;
             }
         }
     }

     public static void main(String [] argv) {
         int failures = 0;

         failures += testPow();
         failures += testCrossProduct();

         if (failures > 0) {
             System.err.println("Testing pow incurred "
                                + failures + " failures.");
             throw new RuntimeException();
         }
     }
 }
	/*
	* Copyright (c) 2004, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	/*
	* @test
	* @bug 4984407 5033578
	* @summary Tests for {Math, StrictMath}.pow
	* @author Joseph D. Darcy
	*/

	public class PowTests {
	private PowTests(){}

	static final double infinityD = Double.POSITIVE_INFINITY;

	static int testPowCase(double input1, double input2, double expected) {
	int failures = 0;
	failures += Tests.test("StrictMath.pow(double, double)", input1, input2,
	StrictMath.pow(input1, input2), expected);
	failures += Tests.test("Math.pow(double, double)", input1, input2,
	Math.pow(input1, input2), expected);
	return failures;
	}


	static int testStrictPowCase(double input1, double input2, double expected) {
	int failures = 0;
	failures += Tests.test("StrictMath.pow(double, double)", input1, input2,
	StrictMath.pow(input1, input2), expected);
	return failures;
	}

	static int testNonstrictPowCase(double input1, double input2, double expected) {
	int failures = 0;
	failures += Tests.test("Math.pow(double, double)", input1, input2,
	Math.pow(input1, input2), expected);
	return failures;
	}

	/*
	* Test for bad negation implementation.
	*/
	static int testPow() {
	int failures = 0;

	double [][] testCases = {
	{-0.0, 3.0, -0.0},
	{-0.0, 4.0, 0.0},
	{-infinityD, -3.0, -0.0},
	{-infinityD, -4.0, 0.0},
	};

	for (double[] testCase : testCases) {
	failures+=testPowCase(testCase[0], testCase[1], testCase[2]);
	}

	return failures;
	}

	/*
	* Test cross-product of different kinds of arguments.
	*/
	static int testCrossProduct() {
	int failures = 0;

	double testData[] = {
	Double.NEGATIVE_INFINITY,
	/* > -oo */ -Double.MAX_VALUE,
	/**/ (double)Long.MIN_VALUE,
	/**/ (double) -((1L<<53)+2L),
	/**/ (double) -((1L<<53)),
	/**/ (double) -((1L<<53)-1L),
	/**/ -((double)Integer.MAX_VALUE + 4.0),
	/**/ (double)Integer.MIN_VALUE - 1.0,
	/**/ (double)Integer.MIN_VALUE,
	/**/ (double)Integer.MIN_VALUE + 1.0,
	/**/ -Math.PI,
	/**/ -3.0,
	/**/ -Math.E,
	/**/ -2.0,
	/**/ -1.0000000000000004,
	/* < -1.0 */ -1.0000000000000002, // nextAfter(-1.0, -oo)
	-1.0,
	/* > -1.0 */ -0.9999999999999999, // nextAfter(-1.0, +oo)
	/* > -1.0 */ -0.9999999999999998,
	/**/ -0.5,
	/**/ -1.0/3.0,
	/* < 0.0 */ -Double.MIN_VALUE,
	-0.0,
	+0.0,
	/* > 0.0 */ +Double.MIN_VALUE,
	/**/ +1.0/3.0,
	/**/ +0.5,
	/**/ +0.9999999999999998,
	/* < +1.0 */ +0.9999999999999999, // nextAfter(-1.0, +oo)
	+1.0,
	/* > 1.0 */ +1.0000000000000002, // nextAfter(+1.0, +oo)
	/**/ +1.0000000000000004,
	/**/ +2.0,
	/**/ +Math.E,
	/**/ +3.0,
	/**/ +Math.PI,
	/**/ -(double)Integer.MIN_VALUE - 1.0,
	/**/ -(double)Integer.MIN_VALUE,
	/**/ -(double)Integer.MIN_VALUE + 1.0,
	/**/ (double)Integer.MAX_VALUE + 4.0,
	/**/ (double) ((1L<<53)-1L),
	/**/ (double) ((1L<<53)),
	/**/ (double) ((1L<<53)+2L),
	/**/ -(double)Long.MIN_VALUE,
	/* < oo */ Double.MAX_VALUE,
	Double.POSITIVE_INFINITY,
	Double.NaN
	};

	double NaN = Double.NaN;
	for(double x: testData) {
	for(double y: testData) {
	boolean testPass = false;
	double expected=NaN;
	double actual;

	// First, switch on y
	if( Double.isNaN(y)) {
	expected = NaN;
	} else if (y == 0.0) {
	expected = 1.0;
	} else if (Double.isInfinite(y) ) {
	if(y > 0) { // x ^ (+oo)
	if (Math.abs(x) > 1.0) {
	expected = Double.POSITIVE_INFINITY;
	} else if (Math.abs(x) == 1.0) {
	expected = NaN;
	} else if (Math.abs(x) < 1.0) {
	expected = +0.0;
	} else { // x is NaN
	assert Double.isNaN(x);
	expected = NaN;
	}
	} else { // x ^ (-oo)
	if (Math.abs(x) > 1.0) {
	expected = +0.0;
	} else if (Math.abs(x) == 1.0) {
	expected = NaN;
	} else if (Math.abs(x) < 1.0) {
	expected = Double.POSITIVE_INFINITY;
	} else { // x is NaN
	assert Double.isNaN(x);
	expected = NaN;
	}
	} /* end Double.isInfinite(y) */
	} else if (y == 1.0) {
	expected = x;
	} else if (Double.isNaN(x)) { // Now start switching on x
	assert y != 0.0;
	expected = NaN;
	} else if (x == Double.NEGATIVE_INFINITY) {
	expected = (y < 0.0) ? f2(y) :f1(y);
	} else if (x == Double.POSITIVE_INFINITY) {
	expected = (y < 0.0) ? +0.0 : Double.POSITIVE_INFINITY;
	} else if (equivalent(x, +0.0)) {
	assert y != 0.0;
	expected = (y < 0.0) ? Double.POSITIVE_INFINITY: +0.0;
	} else if (equivalent(x, -0.0)) {
	assert y != 0.0;
	expected = (y < 0.0) ? f1(y): f2(y);
	} else if( x < 0.0) {
	assert y != 0.0;
	failures += testStrictPowCase(x, y, f3(x, y));
	failures += testNonstrictPowCase(x, y, f3ns(x, y));
	continue;
	} else {
	// go to next iteration
	expected = NaN;
	continue;
	}

	failures += testPowCase(x, y, expected);
	} // y
	} // x
	return failures;
	}

	static boolean equivalent(double a, double b) {
	return Double.compare(a, b) == 0;
	}

	static double f1(double y) {
	return (intClassify(y) == 1)?
	Double.NEGATIVE_INFINITY:
	Double.POSITIVE_INFINITY;
	}


	static double f2(double y) {
	return (intClassify(y) == 1)?-0.0:0.0;
	}

	static double f3(double x, double y) {
	switch( intClassify(y) ) {
	case 0:
	return StrictMath.pow(Math.abs(x), y);
	// break;

	case 1:
	return -StrictMath.pow(Math.abs(x), y);
	// break;

	case -1:
	return Double.NaN;
	// break;

	default:
	throw new AssertionError("Bad classification.");
	// break;
	}
	}

	static double f3ns(double x, double y) {
	switch( intClassify(y) ) {
	case 0:
	return Math.pow(Math.abs(x), y);
	// break;

	case 1:
	return -Math.pow(Math.abs(x), y);
	// break;

	case -1:
	return Double.NaN;
	// break;

	default:
	throw new AssertionError("Bad classification.");
	// break;
	}
	}

	static boolean isFinite(double a) {
	return (0.0*a == 0);
	}

	/**
	* Return classification of argument: -1 for non-integers, 0 for
	* even integers, 1 for odd integers.
	*/
	static int intClassify(double a) {
	if(!isFinite(a) \|\| // NaNs and infinities
	(a != Math.floor(a) )) { // only integers are fixed-points of floor
	return -1;
	}
	else {
	// Determine if argument is an odd or even integer.

	a = StrictMath.abs(a); // absolute value doesn't affect odd/even

	if(a+1.0 == a) { // a > maximum odd floating-point integer
	return 0; // Large integers are all even
	}
	else { // Convert double -> long and look at low-order bit
	long ell = (long) a;
	return ((ell & 0x1L) == (long)1)?1:0;
	}
	}
	}

	public static void main(String [] argv) {
	int failures = 0;

	failures += testPow();
	failures += testCrossProduct();

	if (failures > 0) {
	System.err.println("Testing pow incurred "
	+ failures + " failures.");
	throw new RuntimeException();
	}
	}
	}