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sparse_arithmetic.go
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// Copyright 2009 The GoMatrix Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package matrix
/*
The sum of this matrix and another.
*/
func (A *SparseMatrix) Plus(B MatrixRO) (Matrix, error) {
C := A.Copy()
err := C.Add(B)
return C, err
}
/*
The sum of this matrix and another sparse matrix, optimized for sparsity.
*/
func (A *SparseMatrix) PlusSparse(B *SparseMatrix) (*SparseMatrix, error) {
C := A.Copy()
err := C.AddSparse(B)
return C, err
}
/*
The difference between this matrix and another.
*/
func (A *SparseMatrix) Minus(B MatrixRO) (Matrix, error) {
C := A.Copy()
err := C.Subtract(B)
return C, err
}
/*
The difference between this matrix and another sparse matrix, optimized for sparsity.
*/
func (A *SparseMatrix) MinusSparse(B *SparseMatrix) (*SparseMatrix, error) {
C := A.Copy()
err := C.SubtractSparse(B)
return C, err
}
/*
Add another matrix to this one in place.
*/
func (A *SparseMatrix) Add(B MatrixRO) error {
if Bs, ok := B.(*SparseMatrix); ok {
return A.AddSparse(Bs)
}
if A.rows != B.Rows() || A.cols != B.Cols() {
return ErrorDimensionMismatch
}
for i := 0; i < A.rows; i++ {
for j := 0; j < A.cols; j++ {
A.Set(i, j, A.Get(i, j)+B.Get(i, j))
}
}
return nil
}
/*
Add another matrix to this one in place, optimized for sparsity.
*/
func (A *SparseMatrix) AddSparse(B *SparseMatrix) error {
if A.rows != B.Rows() || A.cols != B.Cols() {
return ErrorDimensionMismatch
}
for index, value := range B.elements {
i, j := A.GetRowColIndex(index)
A.Set(i, j, A.Get(i, j)+value)
}
return nil
}
/*
Subtract another matrix from this one in place.
*/
func (A *SparseMatrix) Subtract(B MatrixRO) error {
if Bs, ok := B.(*SparseMatrix); ok {
return A.SubtractSparse(Bs)
}
if A.rows != B.Rows() || A.cols != B.Cols() {
return ErrorDimensionMismatch
}
for i := 0; i < A.rows; i++ {
for j := 0; j < A.cols; j++ {
A.Set(i, j, A.Get(i, j)-B.Get(i, j))
}
}
return nil
}
/*
Subtract another matrix from this one in place, optimized for sparsity.
*/
func (A *SparseMatrix) SubtractSparse(B *SparseMatrix) error {
if A.rows != B.Rows() || A.cols != B.Cols() {
return ErrorDimensionMismatch
}
for index, value := range B.elements {
i, j := A.GetRowColIndex(index)
A.Set(i, j, A.Get(i, j)-value)
}
return nil
}
/*
Get the product of this matrix and another.
*/
func (A *SparseMatrix) Times(B MatrixRO) (Matrix, error) {
/* uncomment this if an efficient version is written
if Bs, ok := B.(*SparseMatrix); ok {
return A.TimesSparse(Bs);
}
*/
if A.cols != B.Rows() {
return nil, ErrorDimensionMismatch
}
C := ZerosSparse(A.rows, B.Cols())
for index, value := range A.elements {
i, k := A.GetRowColIndex(index)
//not sure if there is a more efficient way to do this without using
//a different data structure
for j := 0; j < B.Cols(); j++ {
v := B.Get(k, j)
if v != 0 {
C.Set(i, j, C.Get(i, j)+value*v)
}
}
}
return C, nil
}
/*
Get the product of this matrix and another, optimized for sparsity.
*/
func (A *SparseMatrix) TimesSparse(B *SparseMatrix) (*SparseMatrix, error) {
if A.cols != B.Rows() {
return nil, ErrorDimensionMismatch
}
C := ZerosSparse(A.rows, B.Cols())
for index, value := range A.elements {
i, k := A.GetRowColIndex(index)
//not sure if there is a more efficient way to do this without using
//a different data structure
for j := 0; j < B.Cols(); j++ {
v := B.Get(k, j)
if v != 0 {
C.Set(i, j, C.Get(i, j)+value*v)
}
}
}
return C, nil
}
/*
Scale this matrix by f.
*/
func (A *SparseMatrix) Scale(f float64) {
for index, value := range A.elements {
A.elements[index] = value * f
}
}
/*
Get the element-wise product of this matrix and another.
*/
func (A *SparseMatrix) ElementMult(B MatrixRO) (*SparseMatrix, error) {
C := A.Copy()
err := C.ScaleMatrix(B)
return C, err
}
/*
Get the element-wise product of this matrix and another, optimized for sparsity.
*/
func (A *SparseMatrix) ElementMultSparse(B *SparseMatrix) (*SparseMatrix, error) {
C := A.Copy()
err := C.ScaleMatrixSparse(B)
return C, err
}
/*
Scale this matrix by another, element-wise.
*/
func (A *SparseMatrix) ScaleMatrix(B MatrixRO) error {
if A.rows != B.Rows() || A.cols != B.Cols() {
return ErrorDimensionMismatch
}
for index, value := range A.elements {
i, j := A.GetRowColIndex(index)
A.Set(i, j, value*B.Get(i, j))
}
return nil
}
/*
Scale this matrix by another sparse matrix, element-wise. Optimized for sparsity.
*/
func (A *SparseMatrix) ScaleMatrixSparse(B *SparseMatrix) error {
if len(B.elements) > len(A.elements) {
if A.rows != B.rows || A.cols != B.cols {
return ErrorDimensionMismatch
}
for index, value := range A.elements {
i, j := A.GetRowColIndex(index)
A.Set(i, j, value*B.Get(i, j))
}
}
return A.ScaleMatrix(B)
}