Java Code Examples for org.apache.commons.math3.util.FastMath#sinh()

/** Compute hyperbolic sine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic sine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void sinh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.sinh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.cosh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic cosine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic cosine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void cosh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.cosh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.sinh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic cosine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic cosine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void cosh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.cosh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.sinh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic cosine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic cosine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void cosh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.cosh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.sinh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic sine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic sine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void sinh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.sinh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.cosh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic sine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic sine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void sinh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.sinh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.cosh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** Compute hyperbolic cosine of a derivative structure.
 * @param operand array holding the operand
 * @param operandOffset offset of the operand in its array
 * @param result array where result must be stored (for
 * hyperbolic cosine the result array <em>cannot</em> be the input
 * array)
 * @param resultOffset offset of the result in its array
 */
public void cosh(final double[] operand, final int operandOffset,
                 final double[] result, final int resultOffset) {

    // create the function value and derivatives
    double[] function = new double[1 + order];
    function[0] = FastMath.cosh(operand[operandOffset]);
    if (order > 0) {
        function[1] = FastMath.sinh(operand[operandOffset]);
        for (int i = 2; i <= order; ++i) {
            function[i] = function[i - 2];
        }
    }

    // apply function composition
    compose(operand, operandOffset, function, result, resultOffset);

}
 

/** {@inheritDoc} */
public double value(double x) {
    return FastMath.sinh(x);
}
 

@Override
public double execute (double in) {
	switch(bFunc) {
		case SIN:    return FASTMATH ? FastMath.sin(in) : Math.sin(in);
		case COS:    return FASTMATH ? FastMath.cos(in) : Math.cos(in);
		case TAN:    return FASTMATH ? FastMath.tan(in) : Math.tan(in);
		case ASIN:   return FASTMATH ? FastMath.asin(in) : Math.asin(in);
		case ACOS:   return FASTMATH ? FastMath.acos(in) : Math.acos(in);
		case ATAN:   return Math.atan(in); //faster in Math
		// FastMath.*h is faster 98% of time than Math.*h in initial micro-benchmarks
		case SINH:   return FASTMATH ? FastMath.sinh(in) : Math.sinh(in);
		case COSH:   return FASTMATH ? FastMath.cosh(in) : Math.cosh(in);
		case TANH:   return FASTMATH ? FastMath.tanh(in) : Math.tanh(in);
		case CEIL:   return FASTMATH ? FastMath.ceil(in) : Math.ceil(in);
		case FLOOR:  return FASTMATH ? FastMath.floor(in) : Math.floor(in);
		case LOG:    return Math.log(in); //faster in Math
		case LOG_NZ: return (in==0) ? 0 : Math.log(in); //faster in Math
		case ABS:    return Math.abs(in); //no need for FastMath
		case SIGN:   return FASTMATH ? FastMath.signum(in) : Math.signum(in);
		case SQRT:   return Math.sqrt(in); //faster in Math
		case EXP:    return FASTMATH ? FastMath.exp(in) : Math.exp(in);
		case ROUND: return Math.round(in); //no need for FastMath
		
		case PLOGP:
			if (in == 0.0)
				return 0.0;
			else if (in < 0)
				return Double.NaN;
			else //faster in Math
				return in * Math.log(in);
		
		case SPROP:
			//sample proportion: P*(1-P)
			return in * (1 - in); 

		case SIGMOID:
			//sigmoid: 1/(1+exp(-x))
			return FASTMATH ? 1 / (1 + FastMath.exp(-in))  : 1 / (1 + Math.exp(-in));
		
		case ISNA: return Double.isNaN(in) ? 1 : 0;
		case ISNAN: return Double.isNaN(in) ? 1 : 0;
		case ISINF: return Double.isInfinite(in) ? 1 : 0;
		
		default:
			throw new DMLRuntimeException("Builtin.execute(): Unknown operation: " + bFunc);
	}
}
 

/** {@inheritDoc} */
public SparseGradient sinh() {
    return new SparseGradient(FastMath.sinh(value), FastMath.cosh(value), derivatives);
}
 

/** {@inheritDoc} */
public double value(double x) {
    return FastMath.sinh(x);
}
 

/** {@inheritDoc} */
public double value(double x) {
    return FastMath.sinh(x);
}
 

public static double[] vectSinhWrite(double[] a, int ai, int len) {
	double[] c = allocVector(len, false);
	for( int j = 0; j < len; j++, ai++)
		c[j] = FastMath.sinh(a[ai]);
	return c;
}
 

public static void vectSinhAdd(double[] a, double[] c, int[] aix, int ai, int ci, int alen, int len) {
	for( int j = ai; j < ai+alen; j++ )
		c[ci + aix[j]] += FastMath.sinh(a[j]);
}
 

public static void vectSinhAdd(double[] a, double[] c, int ai, int ci, int len) {
	for( int j = ai; j < ai+len; j++, ci++)
		c[ci] +=  FastMath.sinh(a[j]);
}
 

@Override
public double execute (double in) {
	switch(bFunc) {
		case SIN:    return FASTMATH ? FastMath.sin(in) : Math.sin(in);
		case COS:    return FASTMATH ? FastMath.cos(in) : Math.cos(in);
		case TAN:    return FASTMATH ? FastMath.tan(in) : Math.tan(in);
		case ASIN:   return FASTMATH ? FastMath.asin(in) : Math.asin(in);
		case ACOS:   return FASTMATH ? FastMath.acos(in) : Math.acos(in);
		case ATAN:   return Math.atan(in); //faster in Math
		// FastMath.*h is faster 98% of time than Math.*h in initial micro-benchmarks
		case SINH:   return FASTMATH ? FastMath.sinh(in) : Math.sinh(in);
		case COSH:   return FASTMATH ? FastMath.cosh(in) : Math.cosh(in);
		case TANH:   return FASTMATH ? FastMath.tanh(in) : Math.tanh(in);
		case CEIL:   return FASTMATH ? FastMath.ceil(in) : Math.ceil(in);
		case FLOOR:  return FASTMATH ? FastMath.floor(in) : Math.floor(in);
		case LOG:    return Math.log(in); //faster in Math
		case LOG_NZ: return (in==0) ? 0 : Math.log(in); //faster in Math
		case ABS:    return Math.abs(in); //no need for FastMath
		case SIGN:   return FASTMATH ? FastMath.signum(in) : Math.signum(in);
		case SQRT:   return Math.sqrt(in); //faster in Math
		case EXP:    return FASTMATH ? FastMath.exp(in) : Math.exp(in);
		case ROUND: return Math.round(in); //no need for FastMath
		
		case PLOGP:
			if (in == 0.0)
				return 0.0;
			else if (in < 0)
				return Double.NaN;
			else //faster in Math
				return in * Math.log(in);
		
		case SPROP:
			//sample proportion: P*(1-P)
			return in * (1 - in); 

		case SIGMOID:
			//sigmoid: 1/(1+exp(-x))
			return FASTMATH ? 1 / (1 + FastMath.exp(-in))  : 1 / (1 + Math.exp(-in));
		
		case ISNA: return Double.isNaN(in) ? 1 : 0;
		case ISNAN: return Double.isNaN(in) ? 1 : 0;
		case ISINF: return Double.isInfinite(in) ? 1 : 0;
		
		default:
			throw new DMLRuntimeException("Builtin.execute(): Unknown operation: " + bFunc);
	}
}
 

/** {@inheritDoc} */
public double value(double x) {
    return FastMath.sinh(x);
}
 

/** {@inheritDoc} */
public double value(double x) {
    return FastMath.sinh(x);
}
 

public static double[] vectSinhWrite(double[] a, int ai, int len) {
	double[] c = allocVector(len, false);
	for( int j = 0; j < len; j++, ai++)
		c[j] = FastMath.sinh(a[ai]);
	return c;
}
 

public static void vectSinhAdd(double[] a, double[] c, int[] aix, int ai, int ci, int alen, int len) {
	for( int j = ai; j < ai+alen; j++ )
		c[ci + aix[j]] += FastMath.sinh(a[j]);
}