cavis/libnd4j/include/helpers/cpu/biDiagonalUp.cpp

/*******************************************************************************
 * Copyright (c) 2015-2018 Skymind, Inc.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Apache License, Version 2.0 which is available at
 * https://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.
 *
 * SPDX-License-Identifier: Apache-2.0
 ******************************************************************************/

//
// Created by Yurii Shyrma on 18.12.2017
//


#include <householder.h>
#include <biDiagonalUp.h>
#include <NDArrayFactory.h>


namespace nd4j {
namespace ops {
namespace helpers {


//////////////////////////////////////////////////////////////////////////
BiDiagonalUp::BiDiagonalUp(const NDArray& matrix): _HHmatrix(nd4j::NDArrayFactory::create(matrix.ordering(), {matrix.sizeAt(0), matrix.sizeAt(1)}, matrix.dataType(), matrix.getContext())),
                                                         _HHbidiag(nd4j::NDArrayFactory::create(matrix.ordering(), {matrix.sizeAt(1), matrix.sizeAt(1)}, matrix.dataType(), matrix.getContext())) {

	// input validation
	if(matrix.rankOf() != 2 || matrix.isScalar())
		throw std::runtime_error("ops::helpers::biDiagonalizeUp constructor: input array must be 2D matrix !");

	_HHmatrix.assign(&matrix);
	_HHbidiag.assign(0.);
	
	evalData();

}

	template <typename T>
	void BiDiagonalUp::_evalData() {

		const auto rows = _HHmatrix.sizeAt(0);
		const auto cols = _HHmatrix.sizeAt(1);

		if(rows < cols)
			throw std::runtime_error("ops::helpers::BiDiagonalizeUp::evalData method: this procedure is applicable only for input matrix with rows >= cols !");

		NDArray* bottomRightCorner(nullptr), *column(nullptr), *row(nullptr);
		T coeff, normX;

		T _x, _y;

		for(int i = 0; i < cols-1; ++i ) {

			// evaluate Householder matrix nullifying columns
			column = new NDArray(_HHmatrix({i,rows,  i,i+1}, true));

            _x = _HHmatrix.e<T>(i,i);
            _y = _HHbidiag.e<T>(i,i);

			Householder<T>::evalHHmatrixDataI(*column, _x, _y);

            _HHmatrix.p<T>(i, i, _x);
            _HHbidiag.p<T>(i, i, _y);

			// multiply corresponding matrix block on householder matrix from the left: P * bottomRightCorner
			bottomRightCorner =  new NDArray(_HHmatrix({i,rows,  i+1,cols}, true));	// {i, cols}
			Householder<T>::mulLeft(*bottomRightCorner, _HHmatrix({i+1,rows, i,i+1}, true), _HHmatrix.e<T>(i,i));

			delete bottomRightCorner;
			delete column;

			if(i == cols-2)
				continue; 										// do not apply right multiplying at last iteration

			// evaluate Householder matrix nullifying rows
			row  = new NDArray(_HHmatrix({i,i+1,  i+1,cols}, true));

            _x = _HHmatrix.e<T>(i,i+1);
            _y = _HHbidiag.e<T>(i,i+1);

			Householder<T>::evalHHmatrixDataI(*row, _x, _y);

            _HHmatrix.p<T>(i, i+1, _x);
            _HHbidiag.p<T>(i, i+1, _y);

			// multiply corresponding matrix block on householder matrix from the right: bottomRightCorner * P
			bottomRightCorner = new NDArray(_HHmatrix({i+1,rows,  i+1,cols}, true));  // {i, rows}

			Householder<T>::mulRight(*bottomRightCorner, _HHmatrix({i,i+1, i+2,cols}, true), _HHmatrix.e<T>(i,i+1));

			delete bottomRightCorner;
			delete row;
		}

		row  = new NDArray(_HHmatrix({cols-2,cols-1, cols-1,cols}, true));

		_x = _HHmatrix.e<T>(cols-2,cols-1);
		_y = _HHbidiag.e<T>(cols-2,cols-1);

		Householder<T>::evalHHmatrixDataI(*row, _x, _y);

        _HHmatrix.p<T>(cols-2,cols-1, _x);
        _HHbidiag.p<T>(cols-2,cols-1, _y);

		delete row;

		column = new NDArray(_HHmatrix({cols-1,rows, cols-1,cols}, true));

		_x = _HHmatrix.e<T>(cols-1,cols-1);
		_y = _HHbidiag.e<T>(cols-1,cols-1);

		Householder<T>::evalHHmatrixDataI(*column, _x, _y);

		_HHmatrix.p<T>(cols-1, cols-1, _x);
        _HHbidiag.p<T>(cols-1, cols-1, _y);

		delete column;
	}

//////////////////////////////////////////////////////////////////////////
void BiDiagonalUp::evalData() {
	auto xType = _HHmatrix.dataType();

	BUILD_SINGLE_SELECTOR(xType, _evalData, ();, FLOAT_TYPES);
}


//////////////////////////////////////////////////////////////////////////
template <typename T>
HHsequence BiDiagonalUp::makeHHsequence_(const char type) const {

	if(type == 'u') {

    	const int diagSize = _HHbidiag.sizeAt(0);
    	auto colOfCoeffs = NDArrayFactory::create(_HHmatrix.ordering(),  {diagSize, 1}, _HHmatrix.dataType(), _HHmatrix.getContext());

	    for(int i = 0; i < diagSize; ++i)
	        colOfCoeffs.p(i, _HHmatrix.e<T>(i,i));

    	return HHsequence(_HHmatrix, colOfCoeffs, type);
    }
    else {

    	const int diagUpSize = _HHbidiag.sizeAt(0) - 1;
		NDArray colOfCoeffs = NDArrayFactory::create(_HHmatrix.ordering(), {diagUpSize, 1}, _HHmatrix.dataType(), _HHmatrix.getContext());

    	for(int i = 0; i < diagUpSize; ++i)
        	colOfCoeffs.p(i, _HHmatrix.e<T>(i,i+1));

    	HHsequence result(_HHmatrix, colOfCoeffs, type);
    	result._diagSize = diagUpSize;
    	result._shift  = 1;

    	return result;
    }
}

	HHsequence BiDiagonalUp::makeHHsequence(const char type) const {
		auto xType = _HHmatrix.dataType();

		BUILD_SINGLE_SELECTOR(xType, return makeHHsequence_, (type);, FLOAT_TYPES);
	}


BUILD_SINGLE_TEMPLATE(template void BiDiagonalUp::_evalData, (), FLOAT_TYPES);
BUILD_SINGLE_TEMPLATE(template HHsequence BiDiagonalUp::makeHHsequence_, (const char type) const, FLOAT_TYPES);

}
}
}
Eclipse Migration Initial Commit 2019-06-06 14:21:15 +02:00			`/*******************************************************************************`
			`* Copyright (c) 2015-2018 Skymind, Inc.`
			`*`
			`* This program and the accompanying materials are made available under the`
			`* terms of the Apache License, Version 2.0 which is available at`
			`* https://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.`
			`*`
			`* SPDX-License-Identifier: Apache-2.0`
			`******************************************************************************/`

			`//`
			`// Created by Yurii Shyrma on 18.12.2017`
			`//`


			`#include <householder.h>`
			`#include <biDiagonalUp.h>`
			`#include <NDArrayFactory.h>`


			`namespace nd4j {`
			`namespace ops {`
			`namespace helpers {`


			`//////////////////////////////////////////////////////////////////////////`
			`BiDiagonalUp::BiDiagonalUp(const NDArray& matrix): _HHmatrix(nd4j::NDArrayFactory::create(matrix.ordering(), {matrix.sizeAt(0), matrix.sizeAt(1)}, matrix.dataType(), matrix.getContext())),`
			`_HHbidiag(nd4j::NDArrayFactory::create(matrix.ordering(), {matrix.sizeAt(1), matrix.sizeAt(1)}, matrix.dataType(), matrix.getContext())) {`

			`// input validation`
			`if(matrix.rankOf() != 2 \|\| matrix.isScalar())`
			`throw std::runtime_error("ops::helpers::biDiagonalizeUp constructor: input array must be 2D matrix !");`

			`_HHmatrix.assign(&matrix);`
			`_HHbidiag.assign(0.);`

			`evalData();`

			`}`

			`template <typename T>`
			`void BiDiagonalUp::_evalData() {`

			`const auto rows = _HHmatrix.sizeAt(0);`
			`const auto cols = _HHmatrix.sizeAt(1);`

			`if(rows < cols)`
			`throw std::runtime_error("ops::helpers::BiDiagonalizeUp::evalData method: this procedure is applicable only for input matrix with rows >= cols !");`

			`NDArray* bottomRightCorner(nullptr), column(nullptr), row(nullptr);`
			`T coeff, normX;`

			`T _x, _y;`

			`for(int i = 0; i < cols-1; ++i ) {`

			`// evaluate Householder matrix nullifying columns`
			`column = new NDArray(_HHmatrix({i,rows, i,i+1}, true));`

			`_x = _HHmatrix.e<T>(i,i);`
			`_y = _HHbidiag.e<T>(i,i);`

			`Householder<T>::evalHHmatrixDataI(*column, _x, _y);`

			`_HHmatrix.p<T>(i, i, _x);`
			`_HHbidiag.p<T>(i, i, _y);`

			`// multiply corresponding matrix block on householder matrix from the left: P * bottomRightCorner`
			`bottomRightCorner = new NDArray(_HHmatrix({i,rows, i+1,cols}, true)); // {i, cols}`
			`Householder<T>::mulLeft(*bottomRightCorner, _HHmatrix({i+1,rows, i,i+1}, true), _HHmatrix.e<T>(i,i));`

			`delete bottomRightCorner;`
			`delete column;`

			`if(i == cols-2)`
			`continue; // do not apply right multiplying at last iteration`

			`// evaluate Householder matrix nullifying rows`
			`row = new NDArray(_HHmatrix({i,i+1, i+1,cols}, true));`

			`_x = _HHmatrix.e<T>(i,i+1);`
			`_y = _HHbidiag.e<T>(i,i+1);`

			`Householder<T>::evalHHmatrixDataI(*row, _x, _y);`

			`_HHmatrix.p<T>(i, i+1, _x);`
			`_HHbidiag.p<T>(i, i+1, _y);`

			`// multiply corresponding matrix block on householder matrix from the right: bottomRightCorner * P`
			`bottomRightCorner = new NDArray(_HHmatrix({i+1,rows, i+1,cols}, true)); // {i, rows}`

			`Householder<T>::mulRight(*bottomRightCorner, _HHmatrix({i,i+1, i+2,cols}, true), _HHmatrix.e<T>(i,i+1));`

			`delete bottomRightCorner;`
			`delete row;`
			`}`

			`row = new NDArray(_HHmatrix({cols-2,cols-1, cols-1,cols}, true));`

			`_x = _HHmatrix.e<T>(cols-2,cols-1);`
			`_y = _HHbidiag.e<T>(cols-2,cols-1);`

			`Householder<T>::evalHHmatrixDataI(*row, _x, _y);`

			`_HHmatrix.p<T>(cols-2,cols-1, _x);`
			`_HHbidiag.p<T>(cols-2,cols-1, _y);`

			`delete row;`

			`column = new NDArray(_HHmatrix({cols-1,rows, cols-1,cols}, true));`

			`_x = _HHmatrix.e<T>(cols-1,cols-1);`
			`_y = _HHbidiag.e<T>(cols-1,cols-1);`

			`Householder<T>::evalHHmatrixDataI(*column, _x, _y);`

			`_HHmatrix.p<T>(cols-1, cols-1, _x);`
			`_HHbidiag.p<T>(cols-1, cols-1, _y);`

			`delete column;`
			`}`

			`//////////////////////////////////////////////////////////////////////////`
			`void BiDiagonalUp::evalData() {`
			`auto xType = _HHmatrix.dataType();`

			`BUILD_SINGLE_SELECTOR(xType, _evalData, ();, FLOAT_TYPES);`
			`}`


			`//////////////////////////////////////////////////////////////////////////`
			`template <typename T>`
			`HHsequence BiDiagonalUp::makeHHsequence_(const char type) const {`

			`if(type == 'u') {`

			`const int diagSize = _HHbidiag.sizeAt(0);`
			`auto colOfCoeffs = NDArrayFactory::create(_HHmatrix.ordering(), {diagSize, 1}, _HHmatrix.dataType(), _HHmatrix.getContext());`

			`for(int i = 0; i < diagSize; ++i)`
			`colOfCoeffs.p(i, _HHmatrix.e<T>(i,i));`

			`return HHsequence(_HHmatrix, colOfCoeffs, type);`
			`}`
			`else {`

			`const int diagUpSize = _HHbidiag.sizeAt(0) - 1;`
			`NDArray colOfCoeffs = NDArrayFactory::create(_HHmatrix.ordering(), {diagUpSize, 1}, _HHmatrix.dataType(), _HHmatrix.getContext());`

			`for(int i = 0; i < diagUpSize; ++i)`
			`colOfCoeffs.p(i, _HHmatrix.e<T>(i,i+1));`

			`HHsequence result(_HHmatrix, colOfCoeffs, type);`
			`result._diagSize = diagUpSize;`
			`result._shift = 1;`

			`return result;`
			`}`
			`}`

			`HHsequence BiDiagonalUp::makeHHsequence(const char type) const {`
			`auto xType = _HHmatrix.dataType();`

			`BUILD_SINGLE_SELECTOR(xType, return makeHHsequence_, (type);, FLOAT_TYPES);`
			`}`



			`BUILD_SINGLE_TEMPLATE(template void BiDiagonalUp::_evalData, (), FLOAT_TYPES);`
			`BUILD_SINGLE_TEMPLATE(template HHsequence BiDiagonalUp::makeHHsequence_, (const char type) const, FLOAT_TYPES);`

			`}`
			`}`
			`}`