test/003-omnibus-opcodes/src/FloatMath.java - platform/art - Git at Google

 // Copyright 2006 The Android Open Source Project

 /**
  * Test arithmetic operations.
  */
 public class FloatMath {

     static void convTest() {
         System.out.println("FloatMath.convTest");

         float f;
         double d;
         int i;
         long l;

         /* float --> int */
         f = 1234.5678f;
         i = (int) f;
         Main.assertTrue(i == 1234);

         f = -1234.5678f;
         i = (int) f;
         Main.assertTrue(i == -1234);

         /* float --> long */
         f = 1238.5678f;
         l = (long) f;
         Main.assertTrue(l == 1238);

         f = -1238.5678f;
         l = (long) f;
         Main.assertTrue(l == -1238);

         /* float --> double */
         f = 1238.5678f;
         d = (double) f;
         Main.assertTrue(d > 1238.567 && d < 1238.568);

         /* double --> int */
         d = 1234.5678;
         i = (int) d;
         Main.assertTrue(i == 1234);

         d = -1234.5678;
         i = (int) d;
         Main.assertTrue(i == -1234);

         /* double --> long */
         d = 5678956789.0123;
         l = (long) d;
         Main.assertTrue(l == 5678956789L);

         d = -5678956789.0123;
         l = (long) d;
         Main.assertTrue(l == -5678956789L);

         /* double --> float */
         d = 1238.5678;
         f = (float) d;
         Main.assertTrue(f > 1238.567 && f < 1238.568);

         /* int --> long */
         i = 7654;
         l = (long) i;
         Main.assertTrue(l == 7654L);

         i = -7654;
         l = (long) i;
         Main.assertTrue(l == -7654L);

         /* int --> float */
         i = 1234;
         f = (float) i;
         Main.assertTrue(f > 1233.9f && f < 1234.1f);

         i = -1234;
         f = (float) i;
         Main.assertTrue(f < -1233.9f && f > -1234.1f);

         /* int --> double */
         i = 1238;
         d = (double) i;
         Main.assertTrue(d > 1237.9f && d < 1238.1f);

         i = -1238;
         d = (double) i;
         Main.assertTrue(d < -1237.9f && d > -1238.1f);

         /* long --> int (with truncation) */
         l = 5678956789L;
         i = (int) l;
         Main.assertTrue(i == 1383989493);

         l = -5678956789L;
         i = (int) l;
         Main.assertTrue(i == -1383989493);

         /* long --> float */
         l = 5678956789L;
         f = (float) l;
         Main.assertTrue(f > 5.6789564E9 && f < 5.6789566E9);

         l = -5678956789L;
         f = (float) l;
         Main.assertTrue(f < -5.6789564E9 && f > -5.6789566E9);

         /* long --> double */
         l = 6678956789L;
         d = (double) l;
         Main.assertTrue(d > 6.6789567E9 && d < 6.6789568E9);

         l = -6678956789L;
         d = (double) l;
         Main.assertTrue(d < -6.6789567E9 && d > -6.6789568E9);
     }

     /*
      * We pass in the arguments and return the results so the compiler
      * doesn't do the math for us.
      */
     static float[] floatOperTest(float x, float y) {
         System.out.println("FloatMath.floatOperTest");

         float[] results = new float[9];

         /* this seems to generate "op-float" instructions */
         results[0] = x + y;
         results[1] = x - y;
         results[2] = x * y;
         results[3] = x / y;
         results[4] = x % -y;

         /* this seems to generate "op-float/2addr" instructions */
         results[8] = x + (((((x + y) - y) * y) / y) % y);

         return results;
     }
     static void floatOperCheck(float[] results) {
         Main.assertTrue(results[0] > 69996.99f && results[0] < 69997.01f);
         Main.assertTrue(results[1] > 70002.99f && results[1] < 70003.01f);
         Main.assertTrue(results[2] > -210000.01f && results[2] < -209999.99f);
         Main.assertTrue(results[3] > -23333.34f && results[3] < -23333.32f);
         Main.assertTrue(results[4] > 0.999f && results[4] < 1.001f);
         Main.assertTrue(results[8] > 70000.99f && results[8] < 70001.01f);
     }

     /*
      * We pass in the arguments and return the results so the compiler
      * doesn't do the math for us.
      */
     static double[] doubleOperTest(double x, double y) {
         System.out.println("FloatMath.doubleOperTest");

         double[] results = new double[9];

         /* this seems to generate "op-double" instructions */
         results[0] = x + y;
         results[1] = x - y;
         results[2] = x * y;
         results[3] = x / y;
         results[4] = x % -y;

         /* this seems to generate "op-double/2addr" instructions */
         results[8] = x + (((((x + y) - y) * y) / y) % y);

         return results;
     }
     static void doubleOperCheck(double[] results) {
         Main.assertTrue(results[0] > 69996.99 && results[0] < 69997.01);
         Main.assertTrue(results[1] > 70002.99 && results[1] < 70003.01);
         Main.assertTrue(results[2] > -210000.01 && results[2] < -209999.99);
         Main.assertTrue(results[3] > -23333.34 && results[3] < -23333.32);
         Main.assertTrue(results[4] > 0.999 && results[4] < 1.001);
         Main.assertTrue(results[8] > 70000.99 && results[8] < 70001.01);
     }

     /*
      * Try to cause some unary operations.
      */
     static float unopTest(float f) {
         f = -f;
         return f;
     }

     static int[] convI(long l, float f, double d, float zero) {
         int[] results = new int[6];
         results[0] = (int) l;
         results[1] = (int) f;
         results[2] = (int) d;
         results[3] = (int) (1.0f / zero);       // +inf
         results[4] = (int) (-1.0f / zero);      // -inf
         results[5] = (int) ((1.0f / zero) / (1.0f / zero)); // NaN
         return results;
     }
     static void checkConvI(int[] results) {
         System.out.println("FloatMath.checkConvI");
         Main.assertTrue(results[0] == 0x44332211);
         Main.assertTrue(results[1] == 123);
         Main.assertTrue(results[2] == -3);
         Main.assertTrue(results[3] == 0x7fffffff);
         Main.assertTrue(results[4] == 0x80000000);
         Main.assertTrue(results[5] == 0);
     }

     static long[] convL(int i, float f, double d, double zero) {
         long[] results = new long[6];
         results[0] = (long) i;
         results[1] = (long) f;
         results[2] = (long) d;
         results[3] = (long) (1.0 / zero);       // +inf
         results[4] = (long) (-1.0 / zero);      // -inf
         results[5] = (long) ((1.0 / zero) / (1.0 / zero));  // NaN
         return results;
     }
     static void checkConvL(long[] results) {
         System.out.println("FloatMath.checkConvL");
         Main.assertTrue(results[0] == 0xFFFFFFFF88776655L);
         Main.assertTrue(results[1] == 123);
         Main.assertTrue(results[2] == -3);
         Main.assertTrue(results[3] == 0x7fffffffffffffffL);
         Main.assertTrue(results[4] == 0x8000000000000000L);
         Main.assertTrue(results[5] == 0);
     }

     static float[] convF(int i, long l, double d) {
         float[] results = new float[3];
         results[0] = (float) i;
         results[1] = (float) l;
         results[2] = (float) d;
         return results;
     }
     static void checkConvF(float[] results) {
         System.out.println("FloatMath.checkConvF");
         // TODO: Main.assertTrue values
         for (int i = 0; i < results.length; i++)
             System.out.println(" " + i + ": " + results[i]);
         System.out.println("-2.0054409E9, -8.6133031E18, -3.1415927");
     }

     static double[] convD(int i, long l, float f) {
         double[] results = new double[3];
         results[0] = (double) i;
         results[1] = (double) l;
         results[2] = (double) f;
         return results;
     }
     static void checkConvD(double[] results) {
         System.out.println("FloatMath.checkConvD");
         // TODO: Main.assertTrue values
         for (int i = 0; i < results.length; i++)
             System.out.println(" " + i + ": " + results[i]);
         System.out.println("-2.005440939E9, -8.6133032459203287E18, 123.4560012817382");
     }

     static void checkConsts() {
         System.out.println("FloatMath.checkConsts");

         float f = 10.0f;        // const/special
         Main.assertTrue(f > 9.9 && f < 10.1);

         double d = 10.0;        // const-wide/special
         Main.assertTrue(d > 9.9 && d < 10.1);
     }

     /*
      * Determine if two floating point numbers are approximately equal.
      *
      * (Assumes that floating point is generally working, so we can't use
      * this for the first set of tests.)
      */
     static boolean approxEqual(float a, float b, float maxDelta) {
         if (a > b)
             return (a - b) < maxDelta;
         else
             return (b - a) < maxDelta;
     }
     static boolean approxEqual(double a, double b, double maxDelta) {
         if (a > b)
             return (a - b) < maxDelta;
         else
             return (b - a) < maxDelta;
     }

     /*
      * Test some java.lang.Math functions.
      *
      * The method arguments are positive values.
      */
     static void jlmTests(float ff, double dd) {
         System.out.println("FloatMath.jlmTests");

         Main.assertTrue(approxEqual(Math.abs(ff), ff, 0.001f));
         Main.assertTrue(approxEqual(Math.abs(-ff), ff, 0.001f));
         Main.assertTrue(approxEqual(Math.min(ff, -5.0f), -5.0f, 0.001f));
         Main.assertTrue(approxEqual(Math.max(ff, -5.0f), ff, 0.001f));

         Main.assertTrue(approxEqual(Math.abs(dd), dd, 0.001));
         Main.assertTrue(approxEqual(Math.abs(-dd), dd, 0.001));
         Main.assertTrue(approxEqual(Math.min(dd, -5.0), -5.0, 0.001));
         Main.assertTrue(approxEqual(Math.max(dd, -5.0), dd, 0.001));

         double sq = Math.sqrt(dd);
         Main.assertTrue(approxEqual(sq*sq, dd, 0.001));

         Main.assertTrue(approxEqual(0.5403023058681398, Math.cos(1.0), 0.00000001));
         Main.assertTrue(approxEqual(0.8414709848078965, Math.sin(1.0), 0.00000001));
     }

     public static void run() {
         convTest();

         float[] floatResults;
         double[] doubleResults;
         int[] intResults;
         long[] longResults;

         floatResults = floatOperTest(70000.0f, -3.0f);
         floatOperCheck(floatResults);
         doubleResults = doubleOperTest(70000.0, -3.0);
         doubleOperCheck(doubleResults);

         intResults = convI(0x8877665544332211L, 123.456f, -3.1415926535, 0.0f);
         checkConvI(intResults);
         longResults = convL(0x88776655, 123.456f, -3.1415926535, 0.0);
         checkConvL(longResults);
         floatResults = convF(0x88776655, 0x8877665544332211L, -3.1415926535);
         checkConvF(floatResults);
         doubleResults = convD(0x88776655, 0x8877665544332211L, 123.456f);
         checkConvD(doubleResults);

         unopTest(123.456f);

         checkConsts();

         jlmTests(3.14159f, 123456.78987654321);
     }
 }
	// Copyright 2006 The Android Open Source Project

	/**
	* Test arithmetic operations.
	*/
	public class FloatMath {

	static void convTest() {
	System.out.println("FloatMath.convTest");

	float f;
	double d;
	int i;
	long l;

	/* float --> int */
	f = 1234.5678f;
	i = (int) f;
	Main.assertTrue(i == 1234);

	f = -1234.5678f;
	i = (int) f;
	Main.assertTrue(i == -1234);

	/* float --> long */
	f = 1238.5678f;
	l = (long) f;
	Main.assertTrue(l == 1238);

	f = -1238.5678f;
	l = (long) f;
	Main.assertTrue(l == -1238);

	/* float --> double */
	f = 1238.5678f;
	d = (double) f;
	Main.assertTrue(d > 1238.567 && d < 1238.568);

	/* double --> int */
	d = 1234.5678;
	i = (int) d;
	Main.assertTrue(i == 1234);

	d = -1234.5678;
	i = (int) d;
	Main.assertTrue(i == -1234);

	/* double --> long */
	d = 5678956789.0123;
	l = (long) d;
	Main.assertTrue(l == 5678956789L);

	d = -5678956789.0123;
	l = (long) d;
	Main.assertTrue(l == -5678956789L);

	/* double --> float */
	d = 1238.5678;
	f = (float) d;
	Main.assertTrue(f > 1238.567 && f < 1238.568);

	/* int --> long */
	i = 7654;
	l = (long) i;
	Main.assertTrue(l == 7654L);

	i = -7654;
	l = (long) i;
	Main.assertTrue(l == -7654L);

	/* int --> float */
	i = 1234;
	f = (float) i;
	Main.assertTrue(f > 1233.9f && f < 1234.1f);

	i = -1234;
	f = (float) i;
	Main.assertTrue(f < -1233.9f && f > -1234.1f);

	/* int --> double */
	i = 1238;
	d = (double) i;
	Main.assertTrue(d > 1237.9f && d < 1238.1f);

	i = -1238;
	d = (double) i;
	Main.assertTrue(d < -1237.9f && d > -1238.1f);

	/* long --> int (with truncation) */
	l = 5678956789L;
	i = (int) l;
	Main.assertTrue(i == 1383989493);

	l = -5678956789L;
	i = (int) l;
	Main.assertTrue(i == -1383989493);

	/* long --> float */
	l = 5678956789L;
	f = (float) l;
	Main.assertTrue(f > 5.6789564E9 && f < 5.6789566E9);

	l = -5678956789L;
	f = (float) l;
	Main.assertTrue(f < -5.6789564E9 && f > -5.6789566E9);

	/* long --> double */
	l = 6678956789L;
	d = (double) l;
	Main.assertTrue(d > 6.6789567E9 && d < 6.6789568E9);

	l = -6678956789L;
	d = (double) l;
	Main.assertTrue(d < -6.6789567E9 && d > -6.6789568E9);
	}

	/*
	* We pass in the arguments and return the results so the compiler
	* doesn't do the math for us.
	*/
	static float[] floatOperTest(float x, float y) {
	System.out.println("FloatMath.floatOperTest");

	float[] results = new float[9];

	/* this seems to generate "op-float" instructions */
	results[0] = x + y;
	results[1] = x - y;
	results[2] = x * y;
	results[3] = x / y;
	results[4] = x % -y;

	/* this seems to generate "op-float/2addr" instructions */
	results[8] = x + (((((x + y) - y) * y) / y) % y);

	return results;
	}
	static void floatOperCheck(float[] results) {
	Main.assertTrue(results[0] > 69996.99f && results[0] < 69997.01f);
	Main.assertTrue(results[1] > 70002.99f && results[1] < 70003.01f);
	Main.assertTrue(results[2] > -210000.01f && results[2] < -209999.99f);
	Main.assertTrue(results[3] > -23333.34f && results[3] < -23333.32f);
	Main.assertTrue(results[4] > 0.999f && results[4] < 1.001f);
	Main.assertTrue(results[8] > 70000.99f && results[8] < 70001.01f);
	}

	/*
	* We pass in the arguments and return the results so the compiler
	* doesn't do the math for us.
	*/
	static double[] doubleOperTest(double x, double y) {
	System.out.println("FloatMath.doubleOperTest");

	double[] results = new double[9];

	/* this seems to generate "op-double" instructions */
	results[0] = x + y;
	results[1] = x - y;
	results[2] = x * y;
	results[3] = x / y;
	results[4] = x % -y;

	/* this seems to generate "op-double/2addr" instructions */
	results[8] = x + (((((x + y) - y) * y) / y) % y);

	return results;
	}
	static void doubleOperCheck(double[] results) {
	Main.assertTrue(results[0] > 69996.99 && results[0] < 69997.01);
	Main.assertTrue(results[1] > 70002.99 && results[1] < 70003.01);
	Main.assertTrue(results[2] > -210000.01 && results[2] < -209999.99);
	Main.assertTrue(results[3] > -23333.34 && results[3] < -23333.32);
	Main.assertTrue(results[4] > 0.999 && results[4] < 1.001);
	Main.assertTrue(results[8] > 70000.99 && results[8] < 70001.01);
	}

	/*
	* Try to cause some unary operations.
	*/
	static float unopTest(float f) {
	f = -f;
	return f;
	}

	static int[] convI(long l, float f, double d, float zero) {
	int[] results = new int[6];
	results[0] = (int) l;
	results[1] = (int) f;
	results[2] = (int) d;
	results[3] = (int) (1.0f / zero); // +inf
	results[4] = (int) (-1.0f / zero); // -inf
	results[5] = (int) ((1.0f / zero) / (1.0f / zero)); // NaN
	return results;
	}
	static void checkConvI(int[] results) {
	System.out.println("FloatMath.checkConvI");
	Main.assertTrue(results[0] == 0x44332211);
	Main.assertTrue(results[1] == 123);
	Main.assertTrue(results[2] == -3);
	Main.assertTrue(results[3] == 0x7fffffff);
	Main.assertTrue(results[4] == 0x80000000);
	Main.assertTrue(results[5] == 0);
	}

	static long[] convL(int i, float f, double d, double zero) {
	long[] results = new long[6];
	results[0] = (long) i;
	results[1] = (long) f;
	results[2] = (long) d;
	results[3] = (long) (1.0 / zero); // +inf
	results[4] = (long) (-1.0 / zero); // -inf
	results[5] = (long) ((1.0 / zero) / (1.0 / zero)); // NaN
	return results;
	}
	static void checkConvL(long[] results) {
	System.out.println("FloatMath.checkConvL");
	Main.assertTrue(results[0] == 0xFFFFFFFF88776655L);
	Main.assertTrue(results[1] == 123);
	Main.assertTrue(results[2] == -3);
	Main.assertTrue(results[3] == 0x7fffffffffffffffL);
	Main.assertTrue(results[4] == 0x8000000000000000L);
	Main.assertTrue(results[5] == 0);
	}

	static float[] convF(int i, long l, double d) {
	float[] results = new float[3];
	results[0] = (float) i;
	results[1] = (float) l;
	results[2] = (float) d;
	return results;
	}
	static void checkConvF(float[] results) {
	System.out.println("FloatMath.checkConvF");
	// TODO: Main.assertTrue values
	for (int i = 0; i < results.length; i++)
	System.out.println(" " + i + ": " + results[i]);
	System.out.println("-2.0054409E9, -8.6133031E18, -3.1415927");
	}

	static double[] convD(int i, long l, float f) {
	double[] results = new double[3];
	results[0] = (double) i;
	results[1] = (double) l;
	results[2] = (double) f;
	return results;
	}
	static void checkConvD(double[] results) {
	System.out.println("FloatMath.checkConvD");
	// TODO: Main.assertTrue values
	for (int i = 0; i < results.length; i++)
	System.out.println(" " + i + ": " + results[i]);
	System.out.println("-2.005440939E9, -8.6133032459203287E18, 123.4560012817382");
	}

	static void checkConsts() {
	System.out.println("FloatMath.checkConsts");

	float f = 10.0f; // const/special
	Main.assertTrue(f > 9.9 && f < 10.1);

	double d = 10.0; // const-wide/special
	Main.assertTrue(d > 9.9 && d < 10.1);
	}

	/*
	* Determine if two floating point numbers are approximately equal.
	*
	* (Assumes that floating point is generally working, so we can't use
	* this for the first set of tests.)
	*/
	static boolean approxEqual(float a, float b, float maxDelta) {
	if (a > b)
	return (a - b) < maxDelta;
	else
	return (b - a) < maxDelta;
	}
	static boolean approxEqual(double a, double b, double maxDelta) {
	if (a > b)
	return (a - b) < maxDelta;
	else
	return (b - a) < maxDelta;
	}

	/*
	* Test some java.lang.Math functions.
	*
	* The method arguments are positive values.
	*/
	static void jlmTests(float ff, double dd) {
	System.out.println("FloatMath.jlmTests");

	Main.assertTrue(approxEqual(Math.abs(ff), ff, 0.001f));
	Main.assertTrue(approxEqual(Math.abs(-ff), ff, 0.001f));
	Main.assertTrue(approxEqual(Math.min(ff, -5.0f), -5.0f, 0.001f));
	Main.assertTrue(approxEqual(Math.max(ff, -5.0f), ff, 0.001f));

	Main.assertTrue(approxEqual(Math.abs(dd), dd, 0.001));
	Main.assertTrue(approxEqual(Math.abs(-dd), dd, 0.001));
	Main.assertTrue(approxEqual(Math.min(dd, -5.0), -5.0, 0.001));
	Main.assertTrue(approxEqual(Math.max(dd, -5.0), dd, 0.001));

	double sq = Math.sqrt(dd);
	Main.assertTrue(approxEqual(sq*sq, dd, 0.001));

	Main.assertTrue(approxEqual(0.5403023058681398, Math.cos(1.0), 0.00000001));
	Main.assertTrue(approxEqual(0.8414709848078965, Math.sin(1.0), 0.00000001));
	}

	public static void run() {
	convTest();

	float[] floatResults;
	double[] doubleResults;
	int[] intResults;
	long[] longResults;

	floatResults = floatOperTest(70000.0f, -3.0f);
	floatOperCheck(floatResults);
	doubleResults = doubleOperTest(70000.0, -3.0);
	doubleOperCheck(doubleResults);

	intResults = convI(0x8877665544332211L, 123.456f, -3.1415926535, 0.0f);
	checkConvI(intResults);
	longResults = convL(0x88776655, 123.456f, -3.1415926535, 0.0);
	checkConvL(longResults);
	floatResults = convF(0x88776655, 0x8877665544332211L, -3.1415926535);
	checkConvF(floatResults);
	doubleResults = convD(0x88776655, 0x8877665544332211L, 123.456f);
	checkConvD(doubleResults);

	unopTest(123.456f);

	checkConsts();

	jlmTests(3.14159f, 123456.78987654321);
	}
	}