| /* |
| * Copyright (C) 2014 The Android Open Source Project |
| * |
| * Licensed 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 android.renderscript.cts; |
| |
| import android.util.Log; |
| |
| public class CoreMathVerifier { |
| static { |
| System.loadLibrary("coremathtestcpp_jni"); |
| } |
| |
| /* The level of precision we expect out of the half_* functions. floats (f32) have 23 bits of |
| * mantissa and halfs (f16) have 10 bits. 8192 = 2 ^ (23 - 10). |
| */ |
| private static final int HALF_PRECISION = 8192; |
| // The level of precision we expect out of the fast_* functions. |
| private static final int FAST_PRECISION = 8192; |
| // The level of precision we expect out of the native_* functions. |
| private static final int NATIVE_PRECISION = 8192; |
| |
| // Static classes used to return multiple values from a few JNI functions. |
| static public class FrexpResult { |
| public float significand; |
| public int exponent; |
| } |
| |
| static public class LgammaResult { |
| public float lgamma; |
| public int gammaSign; |
| } |
| |
| static public class RemquoResult { |
| public float remainder; |
| public int quotient; |
| } |
| |
| /* We're calling into native: |
| * - not all functions are available in Java, notably gamma and erf, |
| * - Java lacks float version of these functions, so we can compare implementations with |
| * similar constraints, and |
| * - handling unsigned integers, especially longs, is painful and error prone in Java. |
| */ |
| static native float acos(float x); |
| static native float acosh(float x); |
| static native float asin(float x); |
| static native float asinh(float x); |
| static native float atan(float x); |
| static native float atan2(float x, float y); |
| static native float atanh(float x); |
| static native float cbrt(float x); |
| static native float ceil(float x); |
| static native float cos(float x); |
| static native float cosh(float x); |
| static native float erf(float x); |
| static native float erfc(float x); |
| static native float exp(float x); |
| static native float exp10(float x); |
| static native float exp2(float x); |
| static native float expm1(float x); |
| static native float floor(float x); |
| static native FrexpResult frexp(float x); |
| static native float hypot(float x, float y); |
| static native int ilogb(float x); |
| static native float ldexp(float x, int exp); |
| static native float lgamma(float x); |
| static native LgammaResult lgamma2(float x); |
| static native float log(float x); |
| static native float logb(float x); |
| static native float log10(float x); |
| static native float log1p(float x); |
| static native float log2(float x); |
| static native byte maxI8(byte x, byte y); |
| static native byte maxU8(byte x, byte y); |
| static native short maxI16(short x, short y); |
| static native short maxU16(short x, short y); |
| static native int maxI32(int x, int y); |
| static native int maxU32(int x, int y); |
| static native long maxI64(long x, long y); |
| static native long maxU64(long x, long y); |
| static native byte minI8(byte x, byte y); |
| static native byte minU8(byte x, byte y); |
| static native short minI16(short x, short y); |
| static native short minU16(short x, short y); |
| static native int minI32(int x, int y); |
| static native int minU32(int x, int y); |
| static native long minI64(long x, long y); |
| static native long minU64(long x, long y); |
| static native float pow(float x, float y); |
| static native RemquoResult remquo(float numerator, float denominator); |
| static native float rint(float x); |
| static native float round(float x); |
| static native float sin(float x); |
| static native float sinh(float x); |
| static native float sqrt(float x); |
| static native float tan(float x); |
| static native float tanh(float x); |
| static native float tgamma(float x); |
| static native float trunc(float x); |
| |
| static native byte convertCharToChar(byte x); |
| static native byte convertCharToUchar(byte x); |
| static native short convertCharToShort(byte x); |
| static native short convertCharToUshort(byte x); |
| static native int convertCharToInt(byte x); |
| static native int convertCharToUint(byte x); |
| static native long convertCharToLong(byte x); |
| static native long convertCharToUlong(byte x); |
| static native float convertCharToFloat(byte x); |
| static native double convertCharToDouble(byte x); |
| |
| static native byte convertUcharToChar(byte x); |
| static native byte convertUcharToUchar(byte x); |
| static native short convertUcharToShort(byte x); |
| static native short convertUcharToUshort(byte x); |
| static native int convertUcharToInt(byte x); |
| static native int convertUcharToUint(byte x); |
| static native long convertUcharToLong(byte x); |
| static native long convertUcharToUlong(byte x); |
| static native float convertUcharToFloat(byte x); |
| static native double convertUcharToDouble(byte x); |
| |
| static native byte convertShortToChar(short x); |
| static native byte convertShortToUchar(short x); |
| static native short convertShortToShort(short x); |
| static native short convertShortToUshort(short x); |
| static native int convertShortToInt(short x); |
| static native int convertShortToUint(short x); |
| static native long convertShortToLong(short x); |
| static native long convertShortToUlong(short x); |
| static native float convertShortToFloat(short x); |
| static native double convertShortToDouble(short x); |
| |
| static native byte convertUshortToChar(short x); |
| static native byte convertUshortToUchar(short x); |
| static native short convertUshortToShort(short x); |
| static native short convertUshortToUshort(short x); |
| static native int convertUshortToInt(short x); |
| static native int convertUshortToUint(short x); |
| static native long convertUshortToLong(short x); |
| static native long convertUshortToUlong(short x); |
| static native float convertUshortToFloat(short x); |
| static native double convertUshortToDouble(short x); |
| |
| static native byte convertIntToChar(int x); |
| static native byte convertIntToUchar(int x); |
| static native short convertIntToShort(int x); |
| static native short convertIntToUshort(int x); |
| static native int convertIntToInt(int x); |
| static native int convertIntToUint(int x); |
| static native long convertIntToLong(int x); |
| static native long convertIntToUlong(int x); |
| static native float convertIntToFloat(int x); |
| static native double convertIntToDouble(int x); |
| |
| static native byte convertUintToChar(int x); |
| static native byte convertUintToUchar(int x); |
| static native short convertUintToShort(int x); |
| static native short convertUintToUshort(int x); |
| static native int convertUintToInt(int x); |
| static native int convertUintToUint(int x); |
| static native long convertUintToLong(int x); |
| static native long convertUintToUlong(int x); |
| static native float convertUintToFloat(int x); |
| static native double convertUintToDouble(int x); |
| |
| static native byte convertLongToChar(long x); |
| static native byte convertLongToUchar(long x); |
| static native short convertLongToShort(long x); |
| static native short convertLongToUshort(long x); |
| static native int convertLongToInt(long x); |
| static native int convertLongToUint(long x); |
| static native long convertLongToLong(long x); |
| static native long convertLongToUlong(long x); |
| static native float convertLongToFloat(long x); |
| static native double convertLongToDouble(long x); |
| |
| static native byte convertUlongToChar(long x); |
| static native byte convertUlongToUchar(long x); |
| static native short convertUlongToShort(long x); |
| static native short convertUlongToUshort(long x); |
| static native int convertUlongToInt(long x); |
| static native int convertUlongToUint(long x); |
| static native long convertUlongToLong(long x); |
| static native long convertUlongToUlong(long x); |
| static native float convertUlongToFloat(long x); |
| static native double convertUlongToDouble(long x); |
| |
| static native byte convertFloatToChar(float x); |
| static native byte convertFloatToUchar(float x); |
| static native short convertFloatToShort(float x); |
| static native short convertFloatToUshort(float x); |
| static native int convertFloatToInt(float x); |
| static native int convertFloatToUint(float x); |
| static native long convertFloatToLong(float x); |
| static native long convertFloatToUlong(float x); |
| static native float convertFloatToFloat(float x); |
| static native double convertFloatToDouble(float x); |
| |
| static native byte convertDoubleToChar(double x); |
| static native byte convertDoubleToUchar(double x); |
| static native short convertDoubleToShort(double x); |
| static native short convertDoubleToUshort(double x); |
| static native int convertDoubleToInt(double x); |
| static native int convertDoubleToUint(double x); |
| static native long convertDoubleToLong(double x); |
| static native long convertDoubleToUlong(double x); |
| static native float convertDoubleToFloat(double x); |
| static native double convertDoubleToDouble(double x); |
| |
| static private Target.Floaty pi(Target t) { |
| return t.newFloaty(Math.PI); |
| } |
| |
| static private Target.Floaty pi32(Target t) { |
| return t.new32((float) Math.PI); |
| } |
| |
| static private Target.Floaty any(Target t) { |
| return t.newFloaty(Double.NEGATIVE_INFINITY, Double.NaN, Double.POSITIVE_INFINITY); |
| } |
| |
| static private Target.Floaty any32(Target t) { |
| return t.new32(Float.NEGATIVE_INFINITY, Float.NaN, Float.POSITIVE_INFINITY); |
| } |
| |
| static private Target.Floaty acos(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.acos(in.mid()), |
| Math.acos(in.min()), |
| Math.acos(in.max())); |
| } |
| |
| // TODO Remove this function and similar variants that take a float parameter instead of double. |
| static private Target.Floaty acos(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| acos(in.mid32()), |
| acos(in.min32()), |
| acos(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty acosh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| acosh((float) in.mid()), |
| acosh((float) in.min()), |
| acosh((float) in.max())); |
| } |
| |
| static private Target.Floaty acosh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| acosh(in.mid32()), |
| acosh(in.min32()), |
| acosh(in.max32())); |
| } |
| |
| static private Target.Floaty acospi(double d, Target t) { |
| return t.divide(acos(d, t), pi(t)); |
| } |
| |
| static private Target.Floaty acospi(float f, Target t) { |
| return t.divide(acos(f, t), pi32(t)); |
| } |
| |
| static private Target.Floaty asin(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.asin(in.mid()), |
| Math.asin(in.min()), |
| Math.asin(in.max())); |
| } |
| |
| static private Target.Floaty asin(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| asin(in.mid32()), |
| asin(in.min32()), |
| asin(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty asinh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| asinh((float) in.mid()), |
| asinh((float) in.min()), |
| asinh((float) in.max())); |
| } |
| |
| static private Target.Floaty asinh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| asinh(in.mid32()), |
| asinh(in.min32()), |
| asinh(in.max32())); |
| } |
| |
| static private Target.Floaty asinpi(double d, Target t) { |
| return t.divide(asin(d, t), pi(t)); |
| } |
| |
| static private Target.Floaty asinpi(float f, Target t) { |
| return t.divide(asin(f, t), pi32(t)); |
| } |
| |
| static private Target.Floaty atan(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.atan(in.mid()), |
| Math.atan(in.min()), |
| Math.atan(in.max())); |
| } |
| |
| static private Target.Floaty atan(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| atan(in.mid32()), |
| atan(in.min32()), |
| atan(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty atanh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| atanh((float) in.mid()), |
| atanh((float) in.min()), |
| atanh((float) in.max())); |
| } |
| |
| static private Target.Floaty atanh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| atanh(in.mid32()), |
| atanh(in.min32()), |
| atanh(in.max32())); |
| } |
| |
| static private Target.Floaty atanpi(double d, Target t) { |
| return t.divide(atan(d, t), pi(t)); |
| } |
| |
| static private Target.Floaty atanpi(float f, Target t) { |
| return t.divide(atan(f, t), pi32(t)); |
| } |
| |
| static private Target.Floaty atan2(double y, double x, Target t) { |
| Target.Floaty numerator = t.newFloaty(y); |
| Target.Floaty denominator = t.newFloaty(x); |
| return t.newFloaty( |
| Math.atan2(numerator.mid(), denominator.mid()), |
| Math.atan2(numerator.min(), denominator.min()), |
| Math.atan2(numerator.min(), denominator.max()), |
| Math.atan2(numerator.max(), denominator.min()), |
| Math.atan2(numerator.max(), denominator.max())); |
| } |
| |
| static private Target.Floaty atan2(float y, float x, Target t) { |
| Target.Floaty numerator = t.new32(y); |
| Target.Floaty denominator = t.new32(x); |
| return t.new32( |
| atan2(numerator.mid32(), denominator.mid32()), |
| atan2(numerator.min32(), denominator.min32()), |
| atan2(numerator.min32(), denominator.max32()), |
| atan2(numerator.max32(), denominator.min32()), |
| atan2(numerator.max32(), denominator.max32())); |
| } |
| |
| static private Target.Floaty atan2pi(double y, double x, Target t) { |
| return t.divide(atan2(y, x, t), pi(t)); |
| } |
| |
| static private Target.Floaty atan2pi(float y, float x, Target t) { |
| return t.divide(atan2(y, x, t), pi32(t)); |
| } |
| |
| static private Target.Floaty cbrt(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.cbrt(in.mid()), |
| Math.cbrt(in.min()), |
| Math.cbrt(in.max())); |
| } |
| |
| static private Target.Floaty cbrt(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| cbrt(in.mid32()), |
| cbrt(in.min32()), |
| cbrt(in.max32())); |
| } |
| |
| static private Target.Floaty clamp(double value, double minValue, double maxValue, Target t) { |
| return t.newFloaty(Math.min(maxValue, Math.max(minValue, value))); |
| } |
| |
| static private Target.Floaty copysign(double magnitude, double sign, Target t) { |
| return t.newFloaty(Math.copySign(magnitude, sign)); |
| } |
| |
| static private Target.Floaty cos(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.cos(in.mid()), |
| Math.cos(in.min()), |
| Math.cos(in.max())); |
| } |
| |
| static private Target.Floaty cos(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| cos(in.mid32()), |
| cos(in.min32()), |
| cos(in.max32())); |
| } |
| |
| static private Target.Floaty cosh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.cosh(in.mid()), |
| Math.cosh(in.min()), |
| Math.cosh(in.max())); |
| } |
| |
| static private Target.Floaty cosh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| cosh(in.mid32()), |
| cosh(in.min32()), |
| cosh(in.max32())); |
| } |
| |
| static private Target.Floaty cospi(double d, Target t) { |
| Target.Floaty in = t.multiply(t.newFloaty(d), pi(t)); |
| return t.newFloaty( |
| Math.cos(in.mid()), |
| Math.cos(in.min()), |
| Math.cos(in.max())); |
| } |
| |
| static private Target.Floaty cospi(float f, Target t) { |
| Target.Floaty in = t.multiply(t.new32(f), pi32(t)); |
| return t.new32( |
| cos(in.mid32()), |
| cos(in.min32()), |
| cos(in.max32())); |
| } |
| |
| // Computes the cross product of two double-precision 3D vectors. |
| static private void cross(double[] v1, double[] v2, Target.Floaty[] out, Target t) { |
| Target.Floaty a12 = t.multiply(t.newFloaty(v1[1]), t.newFloaty(v2[2])); |
| Target.Floaty a21 = t.multiply(t.newFloaty(v1[2]), t.newFloaty(v2[1])); |
| out[0] = t.subtract(a12, a21); |
| Target.Floaty a02 = t.multiply(t.newFloaty(v1[0]), t.newFloaty(v2[2])); |
| Target.Floaty a20 = t.multiply(t.newFloaty(v1[2]), t.newFloaty(v2[0])); |
| out[1] = t.subtract(a20, a02); |
| Target.Floaty a01 = t.multiply(t.newFloaty(v1[0]), t.newFloaty(v2[1])); |
| Target.Floaty a10 = t.multiply(t.newFloaty(v1[1]), t.newFloaty(v2[0])); |
| out[2] = t.subtract(a01, a10); |
| if (out.length == 4) { |
| out[3] = t.newFloaty(0.f); |
| } |
| } |
| |
| // Computes the cross product of two 3D vectors. |
| static private void cross(float[] v1, float[] v2, Target.Floaty[] out, Target t) { |
| Target.Floaty a12 = t.multiply(t.new32(v1[1]), t.new32(v2[2])); |
| Target.Floaty a21 = t.multiply(t.new32(v1[2]), t.new32(v2[1])); |
| out[0] = t.subtract(a12, a21); |
| Target.Floaty a02 = t.multiply(t.new32(v1[0]), t.new32(v2[2])); |
| Target.Floaty a20 = t.multiply(t.new32(v1[2]), t.new32(v2[0])); |
| out[1] = t.subtract(a20, a02); |
| Target.Floaty a01 = t.multiply(t.new32(v1[0]), t.new32(v2[1])); |
| Target.Floaty a10 = t.multiply(t.new32(v1[1]), t.new32(v2[0])); |
| out[2] = t.subtract(a01, a10); |
| if (out.length == 4) { |
| out[3] = t.new32(0.f); |
| } |
| } |
| |
| static private Target.Floaty divide(double left, double right, Target t) { |
| Target.Floaty lFloaty = t.newFloaty(left); |
| Target.Floaty rFloaty = t.newFloaty(right); |
| return t.divide(lFloaty, rFloaty); |
| } |
| |
| // Convert a double-precision radian value to degrees. |
| static private Target.Floaty degrees(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| Target.Floaty k = t.newFloaty(180. / Math.PI); |
| return t.multiply(in, k); |
| } |
| |
| // Returns the distance between two points (in double-precision) in n-dimensional space. |
| static private Target.Floaty distance(double[] point1, double[] point2, Target t) { |
| Target.Floaty sum = t.newFloaty(0.f); |
| for (int i = 0; i < point1.length; i++) { |
| Target.Floaty diff = t.subtract(t.newFloaty(point1[i]), t.newFloaty(point2[i])); |
| sum = t.add(sum, t.multiply(diff, diff)); |
| } |
| Target.Floaty d = t.sqrt(sum); |
| return d; |
| } |
| |
| // Returns the distance between two points in n-dimensional space. |
| static private Target.Floaty distance(float[] point1, float[] point2, Target t) { |
| Target.Floaty sum = t.new32(0.f); |
| for (int i = 0; i < point1.length; i++) { |
| Target.Floaty diff = t.subtract(t.new32(point1[i]), t.new32(point2[i])); |
| sum = t.add(sum, t.multiply(diff, diff)); |
| } |
| Target.Floaty d = t.sqrt(sum); |
| return d; |
| } |
| |
| // Computes the error function for a double-precision input. |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty erf(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| erf((float) in.mid()), |
| erf((float) in.min()), |
| erf((float) in.max())); |
| } |
| |
| // Computes the complementary error function for a double-precision input. |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty erfc(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| erfc((float) in.mid()), |
| erfc((float) in.min()), |
| erfc((float) in.max())); |
| } |
| |
| static private Target.Floaty exp(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.exp(in.mid()), |
| Math.exp(in.min()), |
| Math.exp(in.max())); |
| } |
| |
| static private Target.Floaty exp(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| exp(in.mid32()), |
| exp(in.min32()), |
| exp(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty exp10(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| exp10((float) in.mid()), |
| exp10((float) in.min()), |
| exp10((float) in.max())); |
| } |
| |
| static private Target.Floaty exp10(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| exp10(in.mid32()), |
| exp10(in.min32()), |
| exp10(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty exp2(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| exp2((float) in.mid()), |
| exp2((float) in.min()), |
| exp2((float) in.max())); |
| } |
| |
| static private Target.Floaty exp2(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| exp2(in.mid32()), |
| exp2(in.min32()), |
| exp2(in.max32())); |
| } |
| |
| static private Target.Floaty expm1(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.expm1(in.mid()), |
| Math.expm1(in.min()), |
| Math.expm1(in.max())); |
| } |
| |
| static private Target.Floaty expm1(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| expm1(in.mid32()), |
| expm1(in.min32()), |
| expm1(in.max32())); |
| } |
| |
| static private Target.Floaty fabs(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.abs(in.mid()), |
| Math.abs(in.min()), |
| Math.abs(in.max())); |
| } |
| |
| static private Target.Floaty fdim(double a, double b, Target t) { |
| Target.Floaty inA = t.newFloaty(a); |
| Target.Floaty inB = t.newFloaty(b); |
| Target.Floaty r = t.subtract(inA, inB); |
| return t.newFloaty( |
| Math.max(0., r.mid()), |
| Math.max(0., r.min()), |
| Math.max(0., r.max())); |
| } |
| |
| static private Target.Floaty floor(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.floor(in.mid()), |
| Math.floor(in.min()), |
| Math.floor(in.max())); |
| } |
| |
| static private Target.Floaty fma(double m1, double m2, double offset, Target t) { |
| Target.Floaty inM1 = t.newFloaty(m1); |
| Target.Floaty inM2 = t.newFloaty(m2); |
| Target.Floaty inOffset = t.newFloaty(offset); |
| |
| return t.add(t.multiply(inM1, inM2), inOffset); |
| } |
| |
| static private Target.Floaty fmax(double a, double b, Target t) { |
| return t.newFloaty(Math.max(a, b)); |
| } |
| |
| static private Target.Floaty fmin(double a, double b, Target t) { |
| return t.newFloaty(Math.min(a, b)); |
| } |
| |
| static private Target.Floaty fmod(double numerator, double denominator, Target t) { |
| Target.Floaty inNumerator = t.newFloaty(numerator); |
| Target.Floaty inDenominator = t.newFloaty(denominator); |
| return t.newFloaty( |
| numerator % denominator, |
| inNumerator.min() % inDenominator.min(), |
| inNumerator.min() % inDenominator.max(), |
| inNumerator.max() % inDenominator.min(), |
| inNumerator.max() % inDenominator.max()); |
| } |
| |
| // Compute the fractional part of a double value and returns a result that is at most |
| // 'fractUpperBound'. |
| static private Target.Floaty fract(double d, Target t, double fractUpperBound) { |
| return t.newFloaty(Math.min( |
| d - Math.floor(d), |
| fractUpperBound)); |
| } |
| |
| static private Target.Floaty hypot(double x, double y, Target t) { |
| Target.Floaty inX = t.newFloaty(x); |
| Target.Floaty inY = t.newFloaty(y); |
| return t.newFloaty( |
| Math.hypot(inX.mid(), inY.mid()), |
| Math.hypot(inX.min(), inY.min()), |
| Math.hypot(inX.min(), inY.max()), |
| Math.hypot(inX.max(), inY.min()), |
| Math.hypot(inX.max(), inY.max())); |
| } |
| |
| static private Target.Floaty hypot(float x, float y, Target t) { |
| Target.Floaty inX = t.new32(x); |
| Target.Floaty inY = t.new32(y); |
| return t.new32( |
| hypot(inX.mid32(), inY.mid32()), |
| hypot(inX.min32(), inY.min32()), |
| hypot(inX.min32(), inY.max32()), |
| hypot(inX.max32(), inY.min32()), |
| hypot(inX.max32(), inY.max32())); |
| } |
| |
| // Returns the length of an n-dimensional vector (in double-precision). |
| static private Target.Floaty length(double[] array, Target t) { |
| Target.Floaty sum = t.newFloaty(0.); |
| for (int i = 0; i < array.length; i++) { |
| Target.Floaty f = t.newFloaty(array[i]); |
| sum = t.add(sum, t.multiply(f, f)); |
| } |
| return t.sqrt(sum); |
| } |
| |
| // Returns the length of the n-dimensional vector. |
| static private Target.Floaty length(float[] array, Target t) { |
| Target.Floaty sum = t.new32(0.f); |
| for (int i = 0; i < array.length; i++) { |
| Target.Floaty f = t.new32(array[i]); |
| sum = t.add(sum, t.multiply(f, f)); |
| } |
| Target.Floaty l = t.sqrt(sum); |
| return l; |
| } |
| |
| static private Target.Floaty log(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.log(in.mid()), |
| Math.log(in.min()), |
| Math.log(in.max())); |
| } |
| |
| static private Target.Floaty log(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| log(in.mid32()), |
| log(in.min32()), |
| log(in.max32())); |
| } |
| |
| static private Target.Floaty log10(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.log10(in.mid()), |
| Math.log10(in.min()), |
| Math.log10(in.max())); |
| } |
| |
| static private Target.Floaty log10(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| log10(in.mid32()), |
| log10(in.min32()), |
| log10(in.max32())); |
| } |
| |
| static private Target.Floaty log1p(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.log1p(in.mid()), |
| Math.log1p(in.min()), |
| Math.log1p(in.max())); |
| } |
| |
| static private Target.Floaty log1p(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| log1p(in.mid32()), |
| log1p(in.min32()), |
| log1p(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty log2(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| log2((float) in.mid()), |
| log2((float) in.min()), |
| log2((float) in.max())); |
| } |
| |
| static private Target.Floaty log2(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| log2(in.mid32()), |
| log2(in.min32()), |
| log2(in.max32())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty logb(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| logb((float) in.mid()), |
| logb((float) in.min()), |
| logb((float) in.max())); |
| } |
| |
| static private Target.Floaty mad(double m1, double m2, double offset, Target t) { |
| Target.Floaty ab = t.multiply(t.newFloaty(m1), t.newFloaty(m2)); |
| return t.add(ab, t.newFloaty(offset)); |
| } |
| |
| static private Target.Floaty max(double a, double b, Target t) { |
| return t.newFloaty(Math.max(a, b)); |
| } |
| |
| static private Target.Floaty min(double a, double b, Target t) { |
| return t.newFloaty(Math.min(a, b)); |
| } |
| |
| static private Target.Floaty mix(double start, double stop, double fraction, Target t) { |
| Target.Floaty inStart = t.newFloaty(start); |
| Target.Floaty inStop = t.newFloaty(stop); |
| Target.Floaty inFraction = t.newFloaty(fraction); |
| |
| Target.Floaty diff = t.subtract(inStop, inStart); |
| return t.add(inStart, t.multiply(diff, inFraction)); |
| } |
| |
| // Normalizes the double-precision n-dimensional vector, i.e. makes it length 1. |
| static private void normalize(double[] in, Target.Floaty[] out, Target t) { |
| Target.Floaty l = length(in, t); |
| boolean isZero = l.get() == 0.; |
| for (int i = 0; i < in.length; i++) { |
| out[i] = t.newFloaty(in[i]); |
| if (!isZero) { |
| out[i] = t.divide(out[i], l); |
| } |
| } |
| } |
| |
| // Normalizes the n-dimensional vector, i.e. makes it length 1. |
| static private void normalize(float[] in, Target.Floaty[] out, Target t) { |
| Target.Floaty l = length(in, t); |
| boolean isZero = l.get32() == 0.f; |
| for (int i = 0; i < in.length; i++) { |
| out[i] = t.new32(in[i]); |
| if (!isZero) { |
| out[i] = t.divide(out[i], l); |
| } |
| } |
| } |
| |
| static private Target.Floaty pow(double x, double y, Target t) { |
| Target.Floaty base = t.newFloaty(x); |
| Target.Floaty exponent = t.newFloaty(y); |
| return t.newFloaty( |
| Math.pow(base.mid(), exponent.mid()), |
| Math.pow(base.min(), exponent.min()), |
| Math.pow(base.min(), exponent.max()), |
| Math.pow(base.max(), exponent.min()), |
| Math.pow(base.max(), exponent.max())); |
| } |
| |
| static private Target.Floaty powr(float x, float y, Target t) { |
| Target.Floaty base = t.new32(x); |
| Target.Floaty exponent = t.new32(y); |
| return t.new32( |
| pow(base.mid32(), exponent.mid32()), |
| pow(base.min32(), exponent.min32()), |
| pow(base.min32(), exponent.max32()), |
| pow(base.max32(), exponent.min32()), |
| pow(base.max32(), exponent.max32())); |
| } |
| |
| static private Target.Floaty radians(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| Target.Floaty k = t.newFloaty(Math.PI / 180); |
| return t.multiply(in, k); |
| } |
| |
| static private Target.Floaty recip(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.divide(t.newFloaty(1.), in); |
| } |
| |
| static private Target.Floaty recip(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.divide(t.new32(1.f), in); |
| } |
| |
| static private Target.Floaty rint(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.rint(in.mid()), |
| Math.rint(in.min()), |
| Math.rint(in.max())); |
| } |
| |
| static private Target.Floaty rootn(float inV, int inN, Target t) { |
| /* Rootn of a negative number should be possible only if the number |
| * is odd. In cases where the int is very large, our approach will |
| * lose whether the int is odd, and we'll get a NaN for weird cases |
| * like rootn(-3.95, 818181881), which should return 1. We handle the |
| * case by handling the sign ourselves. We use copysign to handle the |
| * negative zero case. |
| */ |
| float value; |
| if ((inN & 0x1) == 0x1) { |
| value = Math.copySign(pow(Math.abs(inV), 1.f / inN), |
| inV); |
| } else { |
| value = pow(inV, 1.f / inN); |
| } |
| if (inN == 0) { |
| return t.new32(value, Float.NaN); |
| } else { |
| return t.new32(value); |
| } |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| // |
| // Also, use native round() instead of Math.round() as the latter has different rounding |
| // behavior in case of ties. |
| static private Target.Floaty round(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| round((float) in.mid()), |
| round((float) in.min()), |
| round((float) in.max())); |
| } |
| |
| static private Target.Floaty rsqrt(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.divide(t.newFloaty(1.), t.sqrt(in)); |
| } |
| |
| static private Target.Floaty rsqrt(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.divide(t.new32(1.f), t.sqrt(in)); |
| } |
| |
| static private Target.Floaty sin(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.sin(in.mid()), |
| Math.sin(in.min()), |
| Math.sin(in.max())); |
| } |
| |
| static private Target.Floaty sin(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| sin(in.mid32()), |
| sin(in.min32()), |
| sin(in.max32())); |
| } |
| |
| static private Target.Floaty sinh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.sinh(in.mid()), |
| Math.sinh(in.min()), |
| Math.sinh(in.max())); |
| } |
| |
| static private Target.Floaty sinh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| sinh(in.mid32()), |
| sinh(in.min32()), |
| sinh(in.max32())); |
| } |
| |
| static private Target.Floaty sinpi(double d, Target t) { |
| Target.Floaty in = t.multiply(t.newFloaty(d), pi(t)); |
| return t.newFloaty( |
| Math.sin(in.mid()), |
| Math.sin(in.min()), |
| Math.sin(in.max())); |
| } |
| |
| static private Target.Floaty sinpi(float f, Target t) { |
| Target.Floaty in = t.multiply(t.new32(f), pi32(t)); |
| return t.new32( |
| sin(in.mid32()), |
| sin(in.min32()), |
| sin(in.max32())); |
| } |
| |
| static private Target.Floaty sqrt(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.sqrt(in); |
| } |
| |
| static private Target.Floaty sqrt(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.sqrt(in); |
| } |
| |
| static private Target.Floaty step(double v, double edge, Target t) { |
| return t.newFloaty(v < edge ? 0.f : 1.f); |
| } |
| |
| static private Target.Floaty tan(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| double min = Math.tan(in.min()); |
| double max = Math.tan(in.max()); |
| /* If difference between in.max() and in.min() is larger than PI or if the tan of the min is |
| * greater than that of the max, we spanned a discontinuity. |
| */ |
| if (in.max() - in.min() > Math.PI || min > max) { |
| return any(t); |
| } else { |
| return t.newFloaty(Math.tan(d), min, max); |
| } |
| } |
| |
| static private Target.Floaty tan(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| float min = tan(in.min32()); |
| float max = tan(in.max32()); |
| /* If difference between in.max() and in.min() is larger than PI or if the tan of the min is |
| * greater than that of the max, we spanned a discontinuity. |
| */ |
| if (in.max() - in.min() > Math.PI || min > max) { |
| return any32(t); |
| } else { |
| return t.new32(tan(f), min, max); |
| } |
| } |
| |
| static private Target.Floaty tanh(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| Math.tanh(in.mid()), |
| Math.tanh(in.min()), |
| Math.tanh(in.max())); |
| } |
| |
| static private Target.Floaty tanh(float f, Target t) { |
| Target.Floaty in = t.new32(f); |
| return t.new32( |
| tanh(in.mid32()), |
| tanh(in.min32()), |
| tanh(in.max32())); |
| } |
| |
| static private Target.Floaty tanpi(double d, Target t) { |
| Target.Floaty in = t.multiply(t.newFloaty(d), pi(t)); |
| double min = Math.tan(in.min()); |
| double max = Math.tan(in.max()); |
| |
| /* If difference between in.max() and in.min() is larger than PI or if the tan of the min is |
| * greater than that of the max, we spanned a discontinuity. |
| */ |
| if (in.max() - in.min() > Math.PI || min > max) { |
| return any(t); |
| } else { |
| return t.newFloaty(Math.tan(in.mid()), min, max); |
| } |
| } |
| |
| static private Target.Floaty tanpi(float f, Target t) { |
| Target.Floaty in = t.multiply(t.new32(f), pi32(t)); |
| float min = tan(in.min32()); |
| float max = tan(in.max32()); |
| /* If difference between in.max() and in.min() is larger than PI or if the tan of the min is |
| * greater than that of the max, we spanned a discontinuity. |
| */ |
| if (in.max() - in.min() > Math.PI || min > max) { |
| return any32(t); |
| } else { |
| return t.new32(tan(in.mid32()), min, max); |
| } |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty tgamma(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| tgamma((float) in.mid()), |
| tgamma((float) in.min()), |
| tgamma((float) in.max())); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static private Target.Floaty trunc(double d, Target t) { |
| Target.Floaty in = t.newFloaty(d); |
| return t.newFloaty( |
| trunc((float) in.mid()), |
| trunc((float) in.min()), |
| trunc((float) in.max())); |
| } |
| |
| static public void computeAbs(TestAbs.ArgumentsCharUchar args) { |
| args.out = (byte)Math.abs(args.inV); |
| } |
| |
| static public void computeAbs(TestAbs.ArgumentsShortUshort args) { |
| args.out = (short)Math.abs(args.inV); |
| } |
| |
| static public void computeAbs(TestAbs.ArgumentsIntUint args) { |
| args.out = Math.abs(args.inV); |
| } |
| |
| static public void computeAcos(TestAcos.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = acos(args.inVDouble, t); |
| } |
| |
| static public void computeAcos(TestAcos.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = acos(args.inV, t); |
| } |
| |
| static public void computeAcosh(TestAcosh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = acosh(args.inVDouble, t); |
| } |
| |
| static public void computeAcosh(TestAcosh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = acosh(args.inV, t); |
| } |
| |
| static public void computeAcospi(TestAcospi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = acospi(args.inVDouble, t); |
| } |
| |
| static public void computeAcospi(TestAcospi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = acospi(args.inV, t); |
| } |
| |
| static public void computeAsin(TestAsin.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = asin(args.inVDouble, t); |
| } |
| |
| static public void computeAsin(TestAsin.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = asin(args.inV, t); |
| } |
| |
| static public void computeAsinh(TestAsinh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = asinh(args.inVDouble, t); |
| } |
| |
| static public void computeAsinh(TestAsinh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = asinh(args.inV, t); |
| } |
| |
| static public void computeAsinpi(TestAsinpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = asinpi(args.inVDouble, t); |
| } |
| |
| static public void computeAsinpi(TestAsinpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = asinpi(args.inV, t); |
| } |
| |
| static public void computeAtan(TestAtan.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atan(args.inVDouble, t); |
| } |
| |
| static public void computeAtan(TestAtan.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = atan(args.inV, t); |
| } |
| |
| static public void computeAtanh(TestAtanh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atanh(args.inVDouble, t); |
| } |
| |
| static public void computeAtanh(TestAtanh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = atanh(args.inV, t); |
| } |
| |
| static public void computeAtanpi(TestAtanpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atanpi(args.inVDouble, t); |
| } |
| |
| static public void computeAtanpi(TestAtanpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = atanpi(args.inV, t); |
| } |
| |
| static public void computeAtan2(TestAtan2.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(6, 6); |
| args.out = atan2(args.inNumeratorDouble, args.inDenominatorDouble, t); |
| } |
| |
| static public void computeAtan2(TestAtan2.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(6, 128); |
| args.out = atan2(args.inNumerator, args.inDenominator, t); |
| } |
| |
| static public void computeAtan2pi(TestAtan2pi.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(6, 6); |
| args.out = atan2pi(args.inNumeratorDouble, args.inDenominatorDouble, t); |
| } |
| |
| static public void computeAtan2pi(TestAtan2pi.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(6, 128); |
| args.out = atan2pi(args.inNumerator, args.inDenominator, t); |
| } |
| |
| static public void computeCbrt(TestCbrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = cbrt(args.inVDouble, t); |
| } |
| |
| static public void computeCbrt(TestCbrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(2, 128); |
| args.out = cbrt(args.inV, t); |
| } |
| |
| static public void computeCeil(TestCeil.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.newFloaty(args.inVDouble); |
| args.out = t.newFloaty( |
| Math.ceil(in.mid()), |
| Math.ceil(in.min()), |
| Math.ceil(in.max())); |
| } |
| |
| static public void computeCeil(TestCeil.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 1); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| ceil(in.mid32()), |
| ceil(in.min32()), |
| ceil(in.max32())); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsCharCharCharChar args) { |
| args.out = minI8(args.inMaxValue, maxI8(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsUcharUcharUcharUchar args) { |
| args.out = minU8(args.inMaxValue, maxU8(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsShortShortShortShort args) { |
| args.out = minI16(args.inMaxValue, maxI16(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsUshortUshortUshortUshort args) { |
| args.out = minU16(args.inMaxValue, maxU16(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsIntIntIntInt args) { |
| args.out = minI32(args.inMaxValue, maxI32(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsUintUintUintUint args) { |
| args.out = minU32(args.inMaxValue, maxU32(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsHalfHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = clamp(args.inValueDouble, args.inMinValueDouble, args.inMaxValueDouble, t); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsFloatFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(Math.min(args.inMaxValue, |
| Math.max(args.inValue, args.inMinValue))); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsLongLongLongLong args) { |
| args.out = minI64(args.inMaxValue, maxI64(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClamp(TestClamp.ArgumentsUlongUlongUlongUlong args) { |
| args.out = minU64(args.inMaxValue, maxU64(args.inValue, args.inMinValue)); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsCharChar args) { |
| int x = args.inValue; |
| args.out = (byte) (Integer.numberOfLeadingZeros(x & 0xff) - 24); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsUcharUchar args) { |
| int x = args.inValue; |
| args.out = (byte) (Integer.numberOfLeadingZeros(x & 0xff) - 24); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsShortShort args) { |
| args.out = (short) (Integer.numberOfLeadingZeros(args.inValue & 0xffff) - 16); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsUshortUshort args) { |
| args.out = (short) (Integer.numberOfLeadingZeros(args.inValue & 0xffff) - 16); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsIntInt args) { |
| args.out = (int) Integer.numberOfLeadingZeros(args.inValue); |
| } |
| |
| static public void computeClz(TestClz.ArgumentsUintUint args) { |
| args.out = (int) Integer.numberOfLeadingZeros(args.inValue); |
| } |
| |
| |
| static public void computeConvert(TestConvert.ArgumentsCharChar args) { |
| args.out = convertCharToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharUchar args) { |
| args.out = convertCharToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharShort args) { |
| args.out = convertCharToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharUshort args) { |
| args.out = convertCharToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharInt args) { |
| args.out = convertCharToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharUint args) { |
| args.out = convertCharToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharLong args) { |
| args.out = convertCharToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharUlong args) { |
| args.out = convertCharToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(convertCharToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(convertCharToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsCharDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertCharToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsUcharChar args) { |
| args.out = convertUcharToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharUchar args) { |
| args.out = convertUcharToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharShort args) { |
| args.out = convertUcharToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharUshort args) { |
| args.out = convertUcharToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharInt args) { |
| args.out = convertUcharToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharUint args) { |
| args.out = convertUcharToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharLong args) { |
| args.out = convertUcharToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharUlong args) { |
| args.out = convertUcharToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(convertUcharToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(convertUcharToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUcharDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertUcharToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsShortChar args) { |
| args.out = convertShortToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortUchar args) { |
| args.out = convertShortToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortShort args) { |
| args.out = convertShortToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortUshort args) { |
| args.out = convertShortToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortInt args) { |
| args.out = convertShortToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortUint args) { |
| args.out = convertShortToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortLong args) { |
| args.out = convertShortToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortUlong args) { |
| args.out = convertShortToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertShortToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(convertShortToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsShortDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertShortToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsUshortChar args) { |
| args.out = convertUshortToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortUchar args) { |
| args.out = convertUshortToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortShort args) { |
| args.out = convertUshortToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortUshort args) { |
| args.out = convertUshortToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortInt args) { |
| args.out = convertUshortToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortUint args) { |
| args.out = convertUshortToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortLong args) { |
| args.out = convertUshortToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortUlong args) { |
| args.out = convertUshortToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertUshortToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(convertUshortToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUshortDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertUshortToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsIntChar args) { |
| args.out = convertIntToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntUchar args) { |
| args.out = convertIntToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntShort args) { |
| args.out = convertIntToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntUshort args) { |
| args.out = convertIntToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntInt args) { |
| args.out = convertIntToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntUint args) { |
| args.out = convertIntToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntLong args) { |
| args.out = convertIntToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntUlong args) { |
| args.out = convertIntToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertIntToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new32(convertIntToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsIntDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertIntToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsUintChar args) { |
| args.out = convertUintToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintUchar args) { |
| args.out = convertUintToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintShort args) { |
| args.out = convertUintToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintUshort args) { |
| args.out = convertUintToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintInt args) { |
| args.out = convertUintToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintUint args) { |
| args.out = convertUintToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintLong args) { |
| args.out = convertUintToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintUlong args) { |
| args.out = convertUintToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertUintToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new32(convertUintToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUintDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertUintToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsLongChar args) { |
| args.out = convertLongToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongUchar args) { |
| args.out = convertLongToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongShort args) { |
| args.out = convertLongToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongUshort args) { |
| args.out = convertLongToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongInt args) { |
| args.out = convertLongToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongUint args) { |
| args.out = convertLongToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongLong args) { |
| args.out = convertLongToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongUlong args) { |
| args.out = convertLongToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertLongToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new32(convertLongToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsLongDouble args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new64(convertLongToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsUlongChar args) { |
| args.out = convertUlongToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongUchar args) { |
| args.out = convertUlongToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongShort args) { |
| args.out = convertUlongToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongUshort args) { |
| args.out = convertUlongToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongInt args) { |
| args.out = convertUlongToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongUint args) { |
| args.out = convertUlongToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongLong args) { |
| args.out = convertUlongToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongUlong args) { |
| args.out = convertUlongToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(convertUlongToDouble(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new32(convertUlongToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsUlongDouble args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new64(convertUlongToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsHalfChar args) { |
| args.out = convertDoubleToChar(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfUchar args) { |
| args.out = convertDoubleToUchar(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfShort args) { |
| args.out = convertDoubleToShort(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfUshort args) { |
| args.out = convertDoubleToUshort(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfInt args) { |
| args.out = convertDoubleToInt(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfUint args) { |
| args.out = convertDoubleToUint(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfLong args) { |
| args.out = convertDoubleToLong(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfUlong args) { |
| args.out = convertDoubleToUlong(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(args.inVDouble); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(convertDoubleToFloat(args.inVDouble)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsHalfDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(args.inVDouble); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsFloatChar args) { |
| args.out = convertFloatToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatUchar args) { |
| args.out = convertFloatToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatShort args) { |
| args.out = convertFloatToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatUshort args) { |
| args.out = convertFloatToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatInt args) { |
| args.out = convertFloatToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatUint args) { |
| args.out = convertFloatToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatLong args) { |
| args.out = convertFloatToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatUlong args) { |
| args.out = convertFloatToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(convertFloatToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsFloatDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertFloatToDouble(args.inV)); |
| } |
| |
| static public void computeConvert(TestConvert.ArgumentsDoubleChar args) { |
| args.out = convertDoubleToChar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleUchar args) { |
| args.out = convertDoubleToUchar(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleShort args) { |
| args.out = convertDoubleToShort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleUshort args) { |
| args.out = convertDoubleToUshort(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleInt args) { |
| args.out = convertDoubleToInt(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleUint args) { |
| args.out = convertDoubleToUint(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleLong args) { |
| args.out = convertDoubleToLong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleUlong args) { |
| args.out = convertDoubleToUlong(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.newFloaty(args.inV); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = t.new32(convertDoubleToFloat(args.inV)); |
| } |
| static public void computeConvert(TestConvert.ArgumentsDoubleDouble args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new64(convertDoubleToDouble(args.inV)); |
| } |
| |
| static public void computeCopysign(TestCopysign.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = copysign(args.inMagnitudeValueDouble, args.inSignValueDouble, t); |
| } |
| |
| static public void computeCopysign(TestCopysign.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(Math.copySign(args.inMagnitudeValue, args.inSignValue)); |
| } |
| |
| static public void computeCos(TestCos.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = cos(args.inVDouble, t); |
| } |
| |
| static public void computeCos(TestCos.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = cos(args.inV, t); |
| } |
| |
| static public void computeCosh(TestCosh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = cosh(args.inVDouble, t); |
| } |
| |
| static public void computeCosh(TestCosh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = cosh(args.inV, t); |
| } |
| |
| static public void computeCospi(TestCospi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = cospi(args.inVDouble, t); |
| } |
| |
| static public void computeCospi(TestCospi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = cospi(args.inV, t); |
| } |
| |
| static public void computeCross(TestCross.ArgumentsHalfNHalfNHalfN args, Target t) { |
| t.setPrecision(1, 4); |
| cross(args.inLeftVectorDouble, args.inRightVectorDouble, args.out, t); |
| } |
| |
| static public void computeCross(TestCross.ArgumentsFloatNFloatNFloatN args, Target t) { |
| t.setPrecision(1, 4); |
| cross(args.inLeftVector, args.inRightVector, args.out, t); |
| } |
| |
| static public void computeDegrees(TestDegrees.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = degrees(args.inVDouble, t); |
| } |
| |
| static public void computeDegrees(TestDegrees.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 3); |
| Target.Floaty in = t.new32(args.inV); |
| Target.Floaty k = t.new32((float)(180.0 / Math.PI)); |
| args.out = t.multiply(in, k); |
| } |
| |
| static public void computeDistance(TestDistance.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = distance(new double[] {args.inLeftVectorDouble}, |
| new double[] {args.inRightVectorDouble}, t); |
| } |
| static public void computeDistance(TestDistance.ArgumentsHalfNHalfNHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = distance(args.inLeftVectorDouble, args.inRightVectorDouble, t); |
| } |
| |
| static public void computeDistance(TestDistance.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = distance(new float[] {args.inLeftVector}, new float[] {args.inRightVector}, t); |
| } |
| |
| static public void computeDistance(TestDistance.ArgumentsFloatNFloatNFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = distance(args.inLeftVector, args.inRightVector, t); |
| } |
| |
| static public void computeDot(TestDot.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 4); // TODO double-check precision |
| Target.Floaty a = t.newFloaty(args.inLeftVectorDouble); |
| Target.Floaty b = t.newFloaty(args.inRightVectorDouble); |
| args.out = t.multiply(a, b); |
| } |
| |
| static public void computeDot(TestDot.ArgumentsHalfNHalfNHalf args, Target t) { |
| t.setPrecision(1, 4); // TODO double-check precision |
| Target.Floaty sum = t.newFloaty(0.); |
| for (int i = 0; i < args.inLeftVectorDouble.length; i++) { |
| Target.Floaty a = t.newFloaty(args.inLeftVectorDouble[i]); |
| Target.Floaty b = t.newFloaty(args.inRightVectorDouble[i]); |
| sum = t.add(sum, t.multiply(a, b)); |
| } |
| args.out = sum; |
| } |
| |
| static public void computeDot(TestDot.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 4); |
| Target.Floaty a = t.new32(args.inLeftVector); |
| Target.Floaty b = t.new32(args.inRightVector); |
| args.out = t.multiply(a, b); |
| } |
| |
| static public void computeDot(TestDot.ArgumentsFloatNFloatNFloat args, Target t) { |
| t.setPrecision(1, 4); |
| Target.Floaty sum = t.new32(0.f); |
| for (int i = 0; i < args.inLeftVector.length; i++) { |
| Target.Floaty a = t.new32(args.inLeftVector[i]); |
| Target.Floaty b = t.new32(args.inRightVector[i]); |
| sum = t.add(sum, t.multiply(a, b)); |
| } |
| args.out = sum; |
| } |
| |
| static public void computeErf(TestErf.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = erf(args.inVDouble, t); |
| } |
| |
| static public void computeErf(TestErf.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| erf(args.inV), |
| erf(in.min32()), |
| erf(in.max32())); |
| } |
| |
| static public void computeErfc(TestErfc.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = erfc(args.inVDouble, t); |
| } |
| |
| static public void computeErfc(TestErfc.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| erfc(args.inV), |
| erfc(in.min32()), |
| erfc(in.max32())); |
| } |
| |
| static public void computeExp(TestExp.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp(args.inVDouble, t); |
| } |
| |
| static public void computeExp(TestExp.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 16); |
| args.out = exp(args.inV, t); |
| } |
| |
| static public void computeExp10(TestExp10.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp10(args.inVDouble, t); |
| } |
| |
| static public void computeExp10(TestExp10.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 32); |
| args.out = exp10(args.inV, t); |
| } |
| |
| static public void computeExp2(TestExp2.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp2(args.inVDouble, t); |
| } |
| |
| static public void computeExp2(TestExp2.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 16); |
| args.out = exp2(args.inV, t); |
| } |
| |
| static public void computeExpm1(TestExpm1.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = expm1(args.inVDouble, t); |
| } |
| |
| static public void computeExpm1(TestExpm1.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 16); |
| args.out = expm1(args.inV, t); |
| } |
| |
| static public void computeFabs(TestFabs.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = fabs(args.inVDouble, t); |
| } |
| |
| static public void computeFabs(TestFabs.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| Math.abs(args.inV), |
| Math.abs(in.min32()), |
| Math.abs(in.max32())); |
| } |
| |
| static public void computeFastDistance(TestFastDistance.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| args.out = distance(new float[] {args.inLeftVector}, new float[] {args.inRightVector}, t); |
| } |
| |
| static public void computeFastDistance(TestFastDistance.ArgumentsFloatNFloatNFloat args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| args.out = distance(args.inLeftVector, args.inRightVector, t); |
| } |
| |
| static public void computeFastLength(TestFastLength.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| args.out = length(new float[] {args.inV}, t); |
| } |
| |
| static public void computeFastLength(TestFastLength.ArgumentsFloatNFloat args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| args.out = length(args.inV, t); |
| } |
| |
| static public void computeFastNormalize(TestFastNormalize.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| Target.Floaty[] out = new Target.Floaty[1]; |
| normalize(new float[] {args.inV}, out, t); |
| args.out = out[0]; |
| } |
| |
| static public void computeFastNormalize(TestFastNormalize.ArgumentsFloatNFloatN args, Target t) { |
| t.setPrecision(FAST_PRECISION, FAST_PRECISION); |
| normalize(args.inV, args.out, t); |
| } |
| |
| static public void computeFdim(TestFdim.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = fdim(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeFdim(TestFdim.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| Target.Floaty inA = t.new32(args.inA); |
| Target.Floaty inB = t.new32(args.inB); |
| Target.Floaty r = t.subtract(inA, inB); |
| args.out = t.new32( |
| Math.max(0.f, r.mid32()), |
| Math.max(0.f, r.min32()), |
| Math.max(0.f, r.max32())); |
| } |
| |
| static public void computeFloor(TestFloor.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = floor(args.inVDouble, t); |
| } |
| |
| static public void computeFloor(TestFloor.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| floor(args.inV), |
| floor(in.min32()), |
| floor(in.max32())); |
| } |
| |
| static public void computeFma(TestFma.ArgumentsHalfHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = fma(args.inMultiplicand1Double, args.inMultiplicand2Double, |
| args.inOffsetDouble, t); |
| } |
| |
| static public void computeFma(TestFma.ArgumentsFloatFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| Target.Floaty ab = t.multiply(t.new32(args.inMultiplicand1), t.new32(args.inMultiplicand2)); |
| args.out = t.add(ab, t.new32(args.inOffset)); |
| } |
| |
| static public void computeFmax(TestFmax.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = fmax(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeFmax(TestFmax.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty a = t.new32(args.inA); |
| Target.Floaty b = t.new32(args.inB); |
| args.out = t.new32( |
| Math.max(args.inA, args.inB), |
| Math.max(a.min32(), b.min32()), |
| Math.max(a.min32(), b.max32()), |
| Math.max(a.max32(), b.min32()), |
| Math.max(a.max32(), b.max32())); |
| } |
| |
| static public void computeFmin(TestFmin.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = fmin(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeFmin(TestFmin.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty a = t.new32(args.inA); |
| Target.Floaty b = t.new32(args.inB); |
| args.out = t.new32( |
| Math.min(args.inA, args.inB), |
| Math.min(a.min32(), b.min32()), |
| Math.min(a.min32(), b.max32()), |
| Math.min(a.max32(), b.min32()), |
| Math.min(a.max32(), b.max32())); |
| } |
| |
| static public void computeFmod(TestFmod.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = fmod(args.inNumeratorDouble, args.inDenominatorDouble, t); |
| } |
| |
| static public void computeFmod(TestFmod.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| Target.Floaty numerator = t.new32(args.inNumerator); |
| Target.Floaty denominator = t.new32(args.inDenominator); |
| args.out = t.new32( |
| args.inNumerator % args.inDenominator, |
| numerator.min32() % denominator.min32(), |
| numerator.min32() % denominator.max32(), |
| numerator.max32() % denominator.min32(), |
| numerator.max32() % denominator.max32()); |
| } |
| |
| static public void computeFract(TestFract.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = fract(args.inVDouble, t, 0.99951171875 /* max float16 smaller than 1.0 */); |
| args.outFloor = floor(args.inVDouble, t); |
| } |
| |
| static public void computeFract(TestFract.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| float floor = floor(args.inV); |
| args.outFloor = t.new32(floor); |
| // 0x1.fffffep-1f is 0.999999... |
| args.out = t.new32(Math.min(args.inV - floor, 0x1.fffffep-1f)); |
| } |
| |
| static public void computeFract(TestFract.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = fract(args.inVDouble, t, 0.99951171875 /* max float16 smaller than 1.0 */); |
| } |
| |
| static public void computeFract(TestFract.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| float floor = floor(args.inV); |
| // 0x1.fffffep-1f is 0.999999... |
| args.out = t.new32(Math.min(args.inV - floor, 0x1.fffffep-1f)); |
| } |
| |
| static public void computeFrexp(TestFrexp.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(0, 0); |
| FrexpResult result = frexp(args.inV); |
| args.out = t.new32(result.significand); |
| args.outExponent = result.exponent; |
| } |
| |
| static public void computeHalfRecip(TestHalfRecip.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(HALF_PRECISION, HALF_PRECISION); |
| args.out = recip(args.inV, t); |
| } |
| |
| static public void computeHalfRsqrt(TestHalfRsqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(HALF_PRECISION, HALF_PRECISION); |
| args.out = rsqrt(args.inV, t); |
| } |
| |
| static public void computeHalfSqrt(TestHalfSqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(HALF_PRECISION, HALF_PRECISION); |
| args.out = sqrt(args.inV, t); |
| } |
| |
| static public void computeHypot(TestHypot.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = hypot(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeHypot(TestHypot.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = hypot(args.inA, args.inB, t); |
| } |
| |
| static public String verifyIlogb(TestIlogb.ArgumentsFloatInt args) { |
| // Special case when the input is 0. We accept two different answers. |
| if (args.inV == 0.f) { |
| if (args.out != -Integer.MAX_VALUE && args.out != Integer.MIN_VALUE) { |
| return "Expected " + Integer.toString(-Integer.MAX_VALUE) + " or " + |
| Integer.toString(Integer.MIN_VALUE); |
| } |
| } else { |
| int result = ilogb(args.inV); |
| if (args.out != result) { |
| return "Expected " + Integer.toString(result); |
| } |
| } |
| return null; |
| } |
| |
| static public void computeLdexp(TestLdexp.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(1, 1); |
| Target.Floaty inMantissa = t.new32(args.inMantissa); |
| args.out = t.new32( |
| ldexp(inMantissa.mid32(), args.inExponent), |
| ldexp(inMantissa.min32(), args.inExponent), |
| ldexp(inMantissa.max32(), args.inExponent)); |
| } |
| |
| static public void computeLength(TestLength.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = length(new double[]{args.inVDouble}, t); |
| } |
| |
| static public void computeLength(TestLength.ArgumentsHalfNHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = length(args.inVDouble, t); |
| } |
| |
| static public void computeLength(TestLength.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = length(new float[]{args.inV}, t); |
| } |
| |
| static public void computeLength(TestLength.ArgumentsFloatNFloat args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = length(args.inV, t); |
| } |
| |
| static public void computeLgamma(TestLgamma.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| lgamma(in.mid32()), |
| lgamma(in.min32()), |
| lgamma(in.max32())); |
| } |
| |
| /* TODO Until -0 handling is corrected in bionic & associated drivers, we temporarily |
| * disable the verification of -0. We do this with a custom verifier. Once bionic |
| * is fixed, we can restore computeLgamma and remove verifyLgamma. |
| static public void computeLgamma(TestLgamma.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| LgammaResult result = lgamma2(in.mid32()); |
| LgammaResult resultMin = lgamma2(in.min32()); |
| LgammaResult resultMax = lgamma2(in.max32()); |
| args.out = t.new32(result.lgamma, resultMin.lgamma, resultMax.lgamma); |
| args.outY = result.gammaSign; |
| } |
| */ |
| static public String verifyLgamma(TestLgamma.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| LgammaResult result = lgamma2(in.mid32()); |
| LgammaResult resultMin = lgamma2(in.min32()); |
| LgammaResult resultMax = lgamma2(in.max32()); |
| Target.Floaty expectedOut = t.new32(result.lgamma, resultMin.lgamma, resultMax.lgamma); |
| boolean isNegativeZero = args.inV == 0.f && 1.f / args.inV < 0.f; |
| /* TODO The current implementation of bionic does not handle the -0.f case correctly. |
| * It should set the sign to -1 but sets it to 1. |
| */ |
| if (!expectedOut.couldBe(args.out) || |
| (args.outSignOfGamma != result.gammaSign && !isNegativeZero)) { |
| StringBuilder message = new StringBuilder(); |
| message.append(String.format("Input in %14.8g {%8x}:\n", args.inV, Float.floatToRawIntBits(args.inV))); |
| message.append("Expected out: "); |
| message.append(expectedOut.toString()); |
| message.append("\n"); |
| message.append(String.format("Actual out: %14.8g {%8x}", args.out, Float.floatToRawIntBits(args.out))); |
| message.append(String.format("Expected outSign: %d\n", result.gammaSign)); |
| message.append(String.format("Actual outSign: %d\n", args.outSignOfGamma)); |
| return message.toString(); |
| } |
| |
| return null; |
| } |
| |
| static public void computeLog(TestLog.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = log(args.inVDouble, t); |
| } |
| |
| // TODO The relaxed ulf for the various log are taken from the old tests. |
| // They are not consistent. |
| static public void computeLog(TestLog.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 16); |
| args.out = log(args.inV, t); |
| } |
| |
| static public void computeLog10(TestLog10.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = log10(args.inVDouble, t); |
| } |
| |
| static public void computeLog10(TestLog10.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 16); |
| args.out = log10(args.inV, t); |
| } |
| |
| static public void computeLog1p(TestLog1p.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = log1p(args.inVDouble, t); |
| } |
| |
| static public void computeLog1p(TestLog1p.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(2, 16); |
| args.out = log1p(args.inV, t); |
| } |
| |
| static public void computeLog2(TestLog2.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = log2(args.inVDouble, t); |
| } |
| |
| static public void computeLog2(TestLog2.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 128); |
| args.out = log2(args.inV, t); |
| } |
| |
| static public void computeLogb(TestLogb.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = logb(args.inVDouble, t); |
| } |
| |
| static public void computeLogb(TestLogb.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| logb(in.mid32()), |
| logb(in.min32()), |
| logb(in.max32())); |
| } |
| |
| static public void computeMad(TestMad.ArgumentsHalfHalfHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = mad(args.inMultiplicand1Double, args.inMultiplicand2Double, args.inOffsetDouble, t); |
| } |
| |
| static public void computeMad(TestMad.ArgumentsFloatFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 4); |
| Target.Floaty ab = t.multiply(t.new32(args.inMultiplicand1), t.new32(args.inMultiplicand2)); |
| args.out = t.add(ab, t.new32(args.inOffset)); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsCharCharChar args) { |
| args.out = maxI8(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsUcharUcharUchar args) { |
| args.out = maxU8(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsShortShortShort args) { |
| args.out = maxI16(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsUshortUshortUshort args) { |
| args.out = maxU16(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsIntIntInt args) { |
| args.out = maxI32(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsUintUintUint args) { |
| args.out = maxU32(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsLongLongLong args) { |
| args.out = maxI64(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsUlongUlongUlong args) { |
| args.out = maxU64(args.inA, args.inB); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = max(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeMax(TestMax.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty a = t.new32(args.inA); |
| Target.Floaty b = t.new32(args.inB); |
| args.out = t.new32( |
| Math.max(a.mid32(), b.mid32()), |
| Math.max(a.min32(), b.min32()), |
| Math.max(a.min32(), b.max32()), |
| Math.max(a.max32(), b.min32()), |
| Math.max(a.max32(), b.max32())); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsCharCharChar args) { |
| args.out = minI8(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsUcharUcharUchar args) { |
| args.out = minU8(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsShortShortShort args) { |
| args.out = minI16(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsUshortUshortUshort args) { |
| args.out = minU16(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsIntIntInt args) { |
| args.out = minI32(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsUintUintUint args) { |
| args.out = minU32(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsLongLongLong args) { |
| args.out = minI64(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsUlongUlongUlong args) { |
| args.out = minU64(args.inA, args.inB); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = min(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeMin(TestMin.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(Math.min(args.inA, args.inB)); |
| } |
| |
| static public void computeMix(TestMix.ArgumentsHalfHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = mix(args.inStartDouble, args.inStopDouble, args.inFractionDouble, t); |
| } |
| |
| static public void computeMix(TestMix.ArgumentsFloatFloatFloatFloat args, Target t) { |
| t.setPrecision(1, 4); |
| Target.Floaty start = t.new32(args.inStart); |
| Target.Floaty stop = t.new32(args.inStop); |
| Target.Floaty diff = t.subtract(stop, start); |
| args.out = t.add(start, t.multiply(diff, t.new32(args.inFraction))); |
| } |
| |
| static public void computeModf(TestModf.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| float ret = (float)(int)args.inV; |
| args.outIntegralPart = t.new32(ret); |
| args.out = t.new32(args.inV - ret); |
| } |
| |
| static public void computeNan(TestNan.ArgumentsUintFloat args, Target t) { |
| t.setPrecision(0, 0); |
| // TODO(jeanluc) We're not using the input argument |
| args.out = t.new32(Float.NaN); |
| } |
| |
| static public void computeNanHalf(TestNanHalf.ArgumentsHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(Double.NaN); |
| } |
| |
| static public void computeNativeAcos(TestNativeAcos.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = acos(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAcos(TestNativeAcos.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = acos(args.inV, t); |
| } |
| |
| static public void computeNativeAcosh(TestNativeAcosh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = acosh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAcosh(TestNativeAcosh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = acosh(args.inV, t); |
| } |
| |
| static public void computeNativeAcospi(TestNativeAcospi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = acospi(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAcospi(TestNativeAcospi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = acospi(args.inV, t); |
| } |
| |
| static public void computeNativeAsin(TestNativeAsin.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = asin(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAsin(TestNativeAsin.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = asin(args.inV, t); |
| } |
| |
| static public void computeNativeAsinh(TestNativeAsinh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = asinh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAsinh(TestNativeAsinh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = asinh(args.inV, t); |
| } |
| |
| static public void computeNativeAsinpi(TestNativeAsinpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = asinpi(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAsinpi(TestNativeAsinpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = asinpi(args.inV, t); |
| } |
| |
| static public void computeNativeAtan(TestNativeAtan.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atan(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAtan(TestNativeAtan.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = atan(args.inV, t); |
| } |
| |
| static public void computeNativeAtanh(TestNativeAtanh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atanh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAtanh(TestNativeAtanh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = atanh(args.inV, t); |
| } |
| |
| static public void computeNativeAtanpi(TestNativeAtanpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atanpi(args.inVDouble, t); |
| } |
| |
| static public void computeNativeAtanpi(TestNativeAtanpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = atanpi(args.inV, t); |
| } |
| |
| static public void computeNativeAtan2(TestNativeAtan2.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atan2(args.inNumeratorDouble, args.inDenominatorDouble, t); |
| } |
| |
| static public void computeNativeAtan2(TestNativeAtan2.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = atan2(args.inNumerator, args.inDenominator, t); |
| } |
| |
| static public void computeNativeAtan2pi(TestNativeAtan2pi.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = atan2pi(args.inNumeratorDouble, args.inDenominatorDouble, t); |
| } |
| |
| static public void computeNativeAtan2pi(TestNativeAtan2pi.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = atan2pi(args.inNumerator, args.inDenominator, t); |
| } |
| |
| static public void computeNativeCbrt(TestNativeCbrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = cbrt(args.inVDouble, t); |
| } |
| |
| static public void computeNativeCbrt(TestNativeCbrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = cbrt(args.inV, t); |
| } |
| |
| static public void computeNativeCos(TestNativeCos.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = cos(args.inVDouble, t); |
| } |
| |
| static public void computeNativeCos(TestNativeCos.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = cos(args.inV, t); |
| } |
| |
| static public void computeNativeCosh(TestNativeCosh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = cosh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeCosh(TestNativeCosh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = cosh(args.inV, t); |
| } |
| |
| static public void computeNativeCospi(TestNativeCospi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = cospi(args.inVDouble, t); |
| } |
| |
| static public void computeNativeCospi(TestNativeCospi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = cospi(args.inV, t); |
| } |
| |
| static public void computeNativeDistance(TestNativeDistance.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = distance(new double[] {args.inLeftVectorDouble}, |
| new double[] {args.inRightVectorDouble}, t); |
| } |
| |
| static public void computeNativeDistance(TestNativeDistance.ArgumentsHalfNHalfNHalf args, Target t) { |
| t.setPrecision(1, 1); |
| args.out = distance(args.inLeftVectorDouble, args.inRightVectorDouble, t); |
| } |
| |
| static public void computeNativeDistance(TestNativeDistance.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = distance(new float[]{args.inLeftVector}, new float[]{args.inRightVector}, t); |
| } |
| |
| static public void computeNativeDistance(TestNativeDistance.ArgumentsFloatNFloatNFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = distance(args.inLeftVector, args.inRightVector, t); |
| } |
| |
| static public void computeNativeDivide(TestNativeDivide.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = divide(args.inLeftVectorDouble, args.inRightVectorDouble, t); |
| } |
| |
| static public void computeNativeDivide(TestNativeDivide.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = t.divide(t.new32(args.inLeftVector), t.new32(args.inRightVector)); |
| } |
| |
| static public void computeNativeExp(TestNativeExp.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp(args.inVDouble, t); |
| } |
| |
| static public void computeNativeExp(TestNativeExp.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = exp(args.inV, t); |
| } |
| |
| static public void computeNativeExp10(TestNativeExp10.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp10(args.inVDouble, t); |
| } |
| |
| static public void computeNativeExp10(TestNativeExp10.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = exp10(args.inV, t); |
| } |
| |
| static public void computeNativeExp2(TestNativeExp2.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = exp2(args.inVDouble, t); |
| } |
| |
| static public void computeNativeExp2(TestNativeExp2.ArgumentsFloatFloat args, Target t) { |
| // TODO we would like to use NATIVE_PRECISION, NATIVE_PRECISION |
| t.setPrecision(13000, 13000); |
| args.out = exp2(args.inV, t); |
| } |
| |
| static public String verifyNativeExpm1(TestNativeExpm1.ArgumentsHalfHalf args, Target t) { |
| // Acceptable error for native_expm1 is: |
| // < 2^-11 in [-Inf, 0.6] |
| // 3 ulp outside |
| double extraAllowedError = 0.; |
| int ulpFactor; |
| if (args.inVDouble < 0.6) { |
| ulpFactor = 0; |
| extraAllowedError = 0.00048828125; // 2^-11 |
| } else { |
| ulpFactor = 3; |
| } |
| t.setPrecision(ulpFactor, ulpFactor); |
| |
| Target.Floaty expectedOut = expm1(args.inVDouble, t); |
| if (!expectedOut.couldBe(args.outDouble, extraAllowedError)) { |
| StringBuilder message = new StringBuilder(); |
| message.append("Ulp Factor: " + Integer.toString(ulpFactor) + "\n"); |
| message.append("Extra allowed error: " + Double.toString(extraAllowedError) + "\n"); |
| message.append("Expected output out: " + expectedOut.toString() + "\n"); |
| return message.toString(); |
| } |
| return null; |
| } |
| |
| static public void computeNativeExpm1(TestNativeExpm1.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = expm1(args.inV, t); |
| } |
| |
| static public void computeNativeHypot(TestNativeHypot.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = hypot(args.inADouble, args.inBDouble, t); |
| } |
| |
| static public void computeNativeHypot(TestNativeHypot.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = hypot(args.inA, args.inB, t); |
| } |
| |
| static public void computeNativeLength(TestNativeLength.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = length(new double[]{args.inVDouble}, t); |
| } |
| |
| static public void computeNativeLength(TestNativeLength.ArgumentsHalfNHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| args.out = length(args.inVDouble, t); |
| } |
| |
| static public void computeNativeLength(TestNativeLength.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = length(new float[] {args.inV}, t); |
| } |
| |
| static public void computeNativeLength(TestNativeLength.ArgumentsFloatNFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = length(args.inV, t); |
| } |
| |
| static public void computeNativeLog(TestNativeLog.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| // http://b/27859722 Accept anything for zero. Negative values don't get tested (see |
| // range() for this function in fw/rs/api/rs_math.spec. |
| if (Math.abs(args.inVDouble) < 1.e-20) { |
| args.out = any(t); |
| } else { |
| args.out = log(args.inVDouble, t); |
| } |
| } |
| |
| static public void computeNativeLog(TestNativeLog.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| // For very small values, allow anything. |
| if (Math.abs(args.inV) < 1.e-20) { |
| args.out = any32(t); |
| } else { |
| args.out = log(args.inV, t); |
| } |
| } |
| |
| static public void computeNativeLog10(TestNativeLog10.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| // http://b/27859722 Accept anything for zero. Negative values don't get tested (see |
| // range() for this function in fw/rs/api/rs_math.spec. |
| if (Math.abs(args.inVDouble) < 1.e-20) { |
| args.out = any(t); |
| } else { |
| args.out = log10(args.inVDouble, t); |
| } |
| } |
| |
| static public void computeNativeLog10(TestNativeLog10.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| // For very small values, allow anything. |
| if (Math.abs(args.inV) < 1.e-20) { |
| args.out = any32(t); |
| } else { |
| args.out = log10(args.inV, t); |
| } |
| } |
| |
| static public void computeNativeLog1p(TestNativeLog1p.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = log1p(args.inVDouble, t); |
| } |
| |
| static public void computeNativeLog1p(TestNativeLog1p.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = log1p(args.inV, t); |
| } |
| |
| static public void computeNativeLog2(TestNativeLog2.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| // http://b/27859722 Accept anything for zero. Negative values don't get tested (see |
| // range() for this function in fw/rs/api/rs_math.spec. |
| if (Math.abs(args.inVDouble) < 1.e-20) { |
| args.out = any(t); |
| } else { |
| args.out = log2(args.inVDouble, t); |
| } |
| } |
| |
| static public void computeNativeLog2(TestNativeLog2.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| // For very small values, allow anything. |
| if (Math.abs(args.inV) < 1.e-20) { |
| args.out = any32(t); |
| } else { |
| args.out = log2(args.inV, t); |
| } |
| } |
| |
| static public void computeNativeNormalize(TestNativeNormalize.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| Target.Floaty[] out = new Target.Floaty[1]; |
| normalize(new double[] {args.inVDouble}, out, t); |
| args.out = out[0]; |
| } |
| |
| static public void computeNativeNormalize(TestNativeNormalize.ArgumentsHalfNHalfN args, Target t) { |
| t.setPrecision(1, 16); // TODO double-check precision. Extra precision needed by libclcore. |
| normalize(args.inVDouble, args.out, t); |
| } |
| |
| static public void computeNativeNormalize(TestNativeNormalize.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| Target.Floaty[] out = new Target.Floaty[1]; |
| normalize(new float[] {args.inV}, out, t); |
| args.out = out[0]; |
| } |
| |
| static public void computeNativeNormalize(TestNativeNormalize.ArgumentsFloatNFloatN args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| normalize(args.inV, args.out, t); |
| } |
| |
| static public void computeNativePowr(TestNativePowr.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| // http://b/27859722 Accept anything for zero. Negative values don't get tested (see |
| // range() for this function in fw/rs/api/rs_math.spec. |
| if (Math.abs(args.inBaseDouble) < 1.e-20) { |
| args.out = any(t); |
| } else { |
| args.out = pow(args.inBaseDouble, args.inExponentDouble, t); |
| } |
| } |
| |
| static public void computeNativePowr(TestNativePowr.ArgumentsFloatFloatFloat args, Target t) { |
| // TODO we would like to use NATIVE_PRECISION, NATIVE_PRECISION |
| t.setPrecision(32000, 32000); |
| // For very small values, allow anything. |
| if (Math.abs(args.inBase) < 1.e-20) { |
| args.out = any32(t); |
| } else { |
| args.out = powr(args.inBase, args.inExponent, t); |
| } |
| } |
| |
| static public void computeNativeRecip(TestNativeRecip.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = recip(args.inVDouble, t); |
| } |
| |
| static public void computeNativeRecip(TestNativeRecip.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = recip(args.inV, t); |
| } |
| |
| static public void computeNativeRootn(TestNativeRootn.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| // Allow anything for zero. |
| if (args.inN == 0) { |
| args.out = any32(t); |
| } else { |
| args.out = rootn(args.inV, args.inN, t); |
| } |
| } |
| |
| static public void computeNativeRsqrt(TestNativeRsqrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = rsqrt(args.inVDouble, t); |
| } |
| |
| static public void computeNativeRsqrt(TestNativeRsqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = rsqrt(args.inV, t); |
| } |
| |
| static public void computeNativeSin(TestNativeSin.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = sin(args.inVDouble, t); |
| } |
| |
| static public void computeNativeSin(TestNativeSin.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = sin(args.inV, t); |
| } |
| |
| static public void computeNativeSincos(TestNativeSincos.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.outCos = cos(args.inVDouble, t); |
| args.out = sin(args.inVDouble, t); |
| } |
| |
| static public void computeNativeSincos(TestNativeSincos.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.outCos = cos(args.inV, t); |
| args.out = sin(args.inV, t); |
| } |
| |
| static public void computeNativeSinh(TestNativeSinh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = sinh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeSinh(TestNativeSinh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = sinh(args.inV, t); |
| } |
| |
| static public void computeNativeSinpi(TestNativeSinpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); // extraAllowedError set in fw/rs/rs_math.spec and generated test files |
| args.out = sinpi(args.inVDouble, t); |
| } |
| |
| static public void computeNativeSinpi(TestNativeSinpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = sinpi(args.inV, t); |
| } |
| |
| static public void computeNativeSqrt(TestNativeSqrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = sqrt(args.inVDouble, t); |
| } |
| |
| static public void computeNativeSqrt(TestNativeSqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = sqrt(args.inV, t); |
| } |
| |
| static public String verifyNativeTan(TestNativeTan.ArgumentsHalfHalf args, Target t) { |
| // Precision for native_tan is as follows: |
| // For integral n: |
| // 8 ulp in [(n-0.45) pi, (n+0.45) pi] |
| // 2048 ulp in [(n+0.45) pi, (n+0.55) pi]" |
| |
| // Compute the fractional part of args.inVDouble / pi |
| double absoluteValueOverPi = Math.abs(args.inVDouble) / Math.PI; |
| double fract = absoluteValueOverPi - Math.floor(absoluteValueOverPi); |
| |
| int ulpFactor; |
| if (0.45 <= fract && fract <= 0.55) { |
| ulpFactor = 2048; |
| } else { |
| ulpFactor = 8; |
| } |
| t.setPrecision(ulpFactor, ulpFactor); |
| |
| Target.Floaty expectedOut = tan(args.inVDouble, t); |
| if (!expectedOut.couldBe(args.outDouble)) { |
| StringBuilder message = new StringBuilder(); |
| message.append("Ulp Factor: " + Integer.toString(ulpFactor) + "\n"); |
| message.append("Expected output out: " + expectedOut.toString() + "\n"); |
| return message.toString(); |
| } |
| |
| return null; |
| } |
| |
| static public void computeNativeTan(TestNativeTan.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = tan(args.inV, t); |
| } |
| |
| static public void computeNativeTanh(TestNativeTanh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = tanh(args.inVDouble, t); |
| } |
| |
| static public void computeNativeTanh(TestNativeTanh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = tanh(args.inV, t); |
| } |
| |
| static public String verifyNativeTanpi(TestNativeTanpi.ArgumentsHalfHalf args, Target t) { |
| // Precision for native_tan is as follows: |
| // For integral n: |
| // 8 ulp in [(n-0.45), (n+0.45)] |
| // 2048 ulp in [(n+0.45), (n+0.55)]" |
| |
| // Compute the fractional part of args.inVDouble |
| double absoluteValue = Math.abs(args.inVDouble); |
| double fract = absoluteValue - Math.floor(absoluteValue); |
| |
| int ulpFactor; |
| if (0.45 <= fract && fract <= 0.55) { |
| ulpFactor = 2048; |
| } else { |
| ulpFactor = 8; |
| } |
| t.setPrecision(ulpFactor, ulpFactor); |
| |
| Target.Floaty expectedOut = tanpi(args.inVDouble, t); |
| if (!expectedOut.couldBe(args.outDouble)) { |
| StringBuilder message = new StringBuilder(); |
| message.append("Ulp Factor: " + Integer.toString(ulpFactor) + "\n"); |
| message.append("Expected output out: " + expectedOut.toString() + "\n"); |
| return message.toString(); |
| } |
| |
| return null; |
| } |
| |
| static public void computeNativeTanpi(TestNativeTanpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(NATIVE_PRECISION, NATIVE_PRECISION); |
| args.out = tanpi(args.inV, t); |
| } |
| |
| static public void computeNextafter(TestNextafter.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(Math.nextAfter(args.inV, args.inTarget)); |
| } |
| |
| static public void computeNormalize(TestNormalize.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| Target.Floaty[] out = new Target.Floaty[1]; |
| normalize(new double[] {args.inVDouble}, out, t); |
| args.out = out[0]; |
| } |
| |
| static public void computeNormalize(TestNormalize.ArgumentsHalfNHalfN args, Target t) { |
| t.setPrecision(1, 1); // TODO double-check precision |
| normalize(args.inVDouble, args.out, t); |
| } |
| |
| static public void computeNormalize(TestNormalize.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(1, 1); |
| Target.Floaty[] out = new Target.Floaty[1]; |
| normalize(new float[] {args.inV}, out, t); |
| args.out = out[0]; |
| } |
| |
| static public void computeNormalize(TestNormalize.ArgumentsFloatNFloatN args, Target t) { |
| t.setPrecision(1, 1); |
| normalize(args.inV, args.out, t); |
| } |
| |
| static public void computePow(TestPow.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = pow(args.inBaseDouble, args.inExponentDouble, t); |
| } |
| |
| static public void computePow(TestPow.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty base = t.new32(args.inBase); |
| Target.Floaty exponent = t.new32(args.inExponent); |
| args.out = t.new32( |
| pow(base.mid32(), exponent.mid32()), |
| pow(base.min32(), exponent.min32()), |
| pow(base.min32(), exponent.max32()), |
| pow(base.max32(), exponent.min32()), |
| pow(base.max32(), exponent.max32())); |
| } |
| |
| static public void computePown(TestPown.ArgumentsHalfIntHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = pow(args.inBaseDouble, (double) args.inExponent, t); |
| } |
| |
| static public void computePown(TestPown.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inBase); |
| // We use double for the calculations because floats does not have enough |
| // mantissa bits. Knowing if an int is odd or even will matter for negative |
| // numbers. Using a float loses the lowest bit. |
| final double y = (double) args.inExponent; |
| args.out = t.new32( |
| (float) Math.pow(in.mid32(), y), |
| (float) Math.pow(in.min32(), y), |
| (float) Math.pow(in.max32(), y)); |
| } |
| |
| static public void computePowr(TestPowr.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = pow(args.inBaseDouble, args.inExponentDouble, t); |
| } |
| |
| static public void computePowr(TestPowr.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| args.out = powr(args.inBase, args.inExponent, t); |
| } |
| |
| static public void computeRadians(TestRadians.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = radians(args.inVDouble, t); |
| } |
| |
| static public void computeRadians(TestRadians.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 3); |
| Target.Floaty in = t.new32(args.inV); |
| Target.Floaty k = t.new32((float)(Math.PI / 180.0)); |
| args.out = t.multiply(in, k); |
| } |
| |
| // NOTE: This function delegates to the floating-point version in libm. Need to switch to the |
| // double-precision version later. |
| static public void computeRemainder(TestRemainder.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| RemquoResult result = remquo((float) args.inNumeratorDouble, |
| (float) args.inDenominatorDouble); |
| args.out = t.newFloaty(result.remainder); |
| } |
| |
| static public void computeRemainder(TestRemainder.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| RemquoResult result = remquo(args.inNumerator, args.inDenominator); |
| args.out = t.new32(result.remainder); |
| } |
| |
| static public String verifyRemquo(TestRemquo.ArgumentsFloatFloatIntFloat args, Target t) { |
| t.setPrecision(0, 0); |
| RemquoResult expected = remquo(args.inNumerator, args.inDenominator); |
| // If the expected remainder is NaN, we don't validate the quotient. It's because of |
| // a division by zero. |
| if (expected.remainder != expected.remainder) { |
| // Check that the value we got is NaN too. |
| if (args.out == args.out) { |
| return "Expected a remainder of NaN but got " + Float.toString(args.out); |
| } |
| } else { |
| // The quotient should have the same lowest three bits. |
| if ((args.outQuotient & 0x07) != (expected.quotient & 0x07)) { |
| return "Quotient returned " + Integer.toString(args.outQuotient) + |
| " does not have the same lower three bits as the expected " + |
| Integer.toString(expected.quotient); |
| } |
| Target.Floaty remainder = t.new32(expected.remainder); |
| if (!remainder.couldBe(args.out)) { |
| return "Remainder returned " + Float.toString(args.out) + |
| " is not similar to the expected " + |
| remainder.toString(); |
| } |
| } |
| return null; |
| } |
| |
| static public void computeRint(TestRint.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = rint(args.inVDouble, t); |
| } |
| |
| static public void computeRint(TestRint.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| rint(in.mid32()), |
| rint(in.min32()), |
| rint(in.max32())); |
| } |
| |
| static public void computeRootn(TestRootn.ArgumentsFloatIntFloat args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = rootn(args.inV, args.inN, t); |
| } |
| |
| static public void computeRound(TestRound.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = round(args.inVDouble, t); |
| } |
| |
| static public void computeRound(TestRound.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| round(in.mid32()), |
| round(in.min32()), |
| round(in.max32())); |
| } |
| |
| static public void computeRsqrt(TestRsqrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = rsqrt(args.inVDouble, t); |
| } |
| |
| static public void computeRsqrt(TestRsqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(2, 2); |
| args.out = rsqrt(args.inV, t); |
| } |
| |
| static public void computeSign(TestSign.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.newFloaty(Math.signum(args.inVDouble)); |
| } |
| |
| static public void computeSign(TestSign.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(Math.signum(args.inV)); |
| } |
| |
| static public void computeSin(TestSin.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = sin(args.inVDouble, t); |
| } |
| |
| static public void computeSin(TestSin.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = sin(args.inV, t); |
| } |
| |
| static public void computeSincos(TestSincos.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(4, 128); |
| args.outCos = cos(args.inVDouble, t ); |
| args.out = sin(args.inVDouble, t); |
| } |
| |
| static public void computeSincos(TestSincos.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.outCos = cos(args.inV,t ); |
| args.out = sin(args.inV, t); |
| } |
| |
| static public void computeSinh(TestSinh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = sinh(args.inVDouble, t); |
| } |
| |
| static public void computeSinh(TestSinh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = sinh(args.inV, t); |
| } |
| |
| static public void computeSinpi(TestSinpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = sinpi(args.inVDouble, t); |
| } |
| |
| static public void computeSinpi(TestSinpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = sinpi(args.inV, t); |
| } |
| |
| static public void computeSqrt(TestSqrt.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = sqrt(args.inVDouble, t); |
| } |
| |
| static public void computeSqrt(TestSqrt.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(3, 3); |
| args.out = sqrt(args.inV, t); |
| } |
| |
| static public void computeStep(TestStep.ArgumentsHalfHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = step(args.inVDouble, args.inEdgeDouble, t); |
| } |
| |
| static public void computeStep(TestStep.ArgumentsFloatFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = t.new32(args.inV < args.inEdge ? 0.f : 1.f); |
| } |
| |
| static public void computeTan(TestTan.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = tan(args.inVDouble, t); |
| } |
| |
| static public void computeTan(TestTan.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = tan(args.inV, t); |
| } |
| |
| static public void computeTanh(TestTanh.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(5, 5); |
| args.out = tanh(args.inVDouble, t); |
| } |
| |
| static public void computeTanh(TestTanh.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(5, 128); |
| args.out = tanh(args.inV, t); |
| } |
| |
| static public void computeTanpi(TestTanpi.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(4, 4); |
| args.out = tanpi(args.inVDouble, t); |
| } |
| |
| static public void computeTanpi(TestTanpi.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(4, 128); |
| args.out = tanpi(args.inV, t); |
| } |
| |
| static public void computeTgamma(TestTgamma.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(16, 16); |
| args.out = tgamma(args.inVDouble, t); |
| } |
| |
| static public void computeTgamma(TestTgamma.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(16, 128); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| tgamma(in.mid32()), |
| tgamma(in.min32()), |
| tgamma(in.max32())); |
| } |
| |
| static public void computeTrunc(TestTrunc.ArgumentsHalfHalf args, Target t) { |
| t.setPrecision(0, 0); |
| args.out = trunc(args.inVDouble, t); |
| } |
| |
| static public void computeTrunc(TestTrunc.ArgumentsFloatFloat args, Target t) { |
| t.setPrecision(0, 0); |
| Target.Floaty in = t.new32(args.inV); |
| args.out = t.new32( |
| trunc(in.mid32()), |
| trunc(in.min32()), |
| trunc(in.max32())); |
| } |
| } |