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// Copyright ©2013 The Gonum Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package mat
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import (
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"gonum.org/v1/gonum/blas"
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"gonum.org/v1/gonum/blas/blas64"
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)
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var (
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dense *Dense
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_ Matrix = dense
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_ Mutable = dense
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_ Cloner = dense
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_ RowViewer = dense
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_ ColViewer = dense
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_ RawRowViewer = dense
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_ Grower = dense
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_ RawMatrixSetter = dense
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_ RawMatrixer = dense
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_ Reseter = dense
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)
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// Dense is a dense matrix representation.
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type Dense struct {
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mat blas64.General
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capRows, capCols int
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}
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// NewDense creates a new Dense matrix with r rows and c columns. If data == nil,
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// a new slice is allocated for the backing slice. If len(data) == r*c, data is
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// used as the backing slice, and changes to the elements of the returned Dense
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// will be reflected in data. If neither of these is true, NewDense will panic.
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// NewDense will panic if either r or c is zero.
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//
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// The data must be arranged in row-major order, i.e. the (i*c + j)-th
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// element in the data slice is the {i, j}-th element in the matrix.
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func NewDense(r, c int, data []float64) *Dense {
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if r <= 0 || c <= 0 {
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if r == 0 || c == 0 {
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panic(ErrZeroLength)
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}
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panic("mat: negative dimension")
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}
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if data != nil && r*c != len(data) {
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panic(ErrShape)
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}
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if data == nil {
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data = make([]float64, r*c)
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}
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return &Dense{
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mat: blas64.General{
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Rows: r,
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Cols: c,
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Stride: c,
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Data: data,
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},
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capRows: r,
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capCols: c,
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}
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}
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// reuseAs resizes an empty matrix to a r×c matrix,
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// or checks that a non-empty matrix is r×c.
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//
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// reuseAs must be kept in sync with reuseAsZeroed.
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func (m *Dense) reuseAs(r, c int) {
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if m.mat.Rows > m.capRows || m.mat.Cols > m.capCols {
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// Panic as a string, not a mat.Error.
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panic("mat: caps not correctly set")
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}
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if r == 0 || c == 0 {
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panic(ErrZeroLength)
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}
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if m.IsZero() {
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m.mat = blas64.General{
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Rows: r,
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Cols: c,
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Stride: c,
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Data: use(m.mat.Data, r*c),
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}
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m.capRows = r
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m.capCols = c
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return
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}
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if r != m.mat.Rows || c != m.mat.Cols {
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panic(ErrShape)
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}
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}
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// reuseAsZeroed resizes an empty matrix to a r×c matrix,
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// or checks that a non-empty matrix is r×c. It zeroes
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// all the elements of the matrix.
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//
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// reuseAsZeroed must be kept in sync with reuseAs.
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func (m *Dense) reuseAsZeroed(r, c int) {
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if m.mat.Rows > m.capRows || m.mat.Cols > m.capCols {
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// Panic as a string, not a mat.Error.
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panic("mat: caps not correctly set")
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}
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if r == 0 || c == 0 {
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panic(ErrZeroLength)
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}
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if m.IsZero() {
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m.mat = blas64.General{
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Rows: r,
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Cols: c,
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Stride: c,
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Data: useZeroed(m.mat.Data, r*c),
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}
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m.capRows = r
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m.capCols = c
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return
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}
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if r != m.mat.Rows || c != m.mat.Cols {
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panic(ErrShape)
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}
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m.Zero()
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}
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// Zero sets all of the matrix elements to zero.
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func (m *Dense) Zero() {
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r := m.mat.Rows
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c := m.mat.Cols
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for i := 0; i < r; i++ {
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zero(m.mat.Data[i*m.mat.Stride : i*m.mat.Stride+c])
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}
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}
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// isolatedWorkspace returns a new dense matrix w with the size of a and
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// returns a callback to defer which performs cleanup at the return of the call.
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// This should be used when a method receiver is the same pointer as an input argument.
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func (m *Dense) isolatedWorkspace(a Matrix) (w *Dense, restore func()) {
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r, c := a.Dims()
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if r == 0 || c == 0 {
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panic(ErrZeroLength)
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}
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w = getWorkspace(r, c, false)
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return w, func() {
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m.Copy(w)
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putWorkspace(w)
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}
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}
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// Reset zeros the dimensions of the matrix so that it can be reused as the
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// receiver of a dimensionally restricted operation.
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//
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// See the Reseter interface for more information.
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func (m *Dense) Reset() {
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// Row, Cols and Stride must be zeroed in unison.
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m.mat.Rows, m.mat.Cols, m.mat.Stride = 0, 0, 0
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m.capRows, m.capCols = 0, 0
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m.mat.Data = m.mat.Data[:0]
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}
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// IsZero returns whether the receiver is zero-sized. Zero-sized matrices can be the
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// receiver for size-restricted operations. Dense matrices can be zeroed using Reset.
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func (m *Dense) IsZero() bool {
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// It must be the case that m.Dims() returns
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// zeros in this case. See comment in Reset().
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return m.mat.Stride == 0
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}
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// asTriDense returns a TriDense with the given size and side. The backing data
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// of the TriDense is the same as the receiver.
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func (m *Dense) asTriDense(n int, diag blas.Diag, uplo blas.Uplo) *TriDense {
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return &TriDense{
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mat: blas64.Triangular{
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N: n,
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Stride: m.mat.Stride,
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Data: m.mat.Data,
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Uplo: uplo,
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Diag: diag,
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},
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cap: n,
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}
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}
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// DenseCopyOf returns a newly allocated copy of the elements of a.
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func DenseCopyOf(a Matrix) *Dense {
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d := &Dense{}
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d.Clone(a)
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return d
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}
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// SetRawMatrix sets the underlying blas64.General used by the receiver.
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// Changes to elements in the receiver following the call will be reflected
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// in b.
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func (m *Dense) SetRawMatrix(b blas64.General) {
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m.capRows, m.capCols = b.Rows, b.Cols
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m.mat = b
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}
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// RawMatrix returns the underlying blas64.General used by the receiver.
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// Changes to elements in the receiver following the call will be reflected
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// in returned blas64.General.
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func (m *Dense) RawMatrix() blas64.General { return m.mat }
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// Dims returns the number of rows and columns in the matrix.
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func (m *Dense) Dims() (r, c int) { return m.mat.Rows, m.mat.Cols }
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// Caps returns the number of rows and columns in the backing matrix.
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func (m *Dense) Caps() (r, c int) { return m.capRows, m.capCols }
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// T performs an implicit transpose by returning the receiver inside a Transpose.
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func (m *Dense) T() Matrix {
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return Transpose{m}
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}
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// ColView returns a Vector reflecting the column j, backed by the matrix data.
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//
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// See ColViewer for more information.
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func (m *Dense) ColView(j int) Vector {
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var v VecDense
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v.ColViewOf(m, j)
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return &v
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}
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// SetCol sets the values in the specified column of the matrix to the values
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// in src. len(src) must equal the number of rows in the receiver.
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func (m *Dense) SetCol(j int, src []float64) {
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if j >= m.mat.Cols || j < 0 {
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panic(ErrColAccess)
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}
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if len(src) != m.mat.Rows {
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panic(ErrColLength)
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}
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blas64.Copy(
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blas64.Vector{N: m.mat.Rows, Inc: 1, Data: src},
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blas64.Vector{N: m.mat.Rows, Inc: m.mat.Stride, Data: m.mat.Data[j:]},
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)
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}
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// SetRow sets the values in the specified rows of the matrix to the values
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// in src. len(src) must equal the number of columns in the receiver.
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func (m *Dense) SetRow(i int, src []float64) {
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if i >= m.mat.Rows || i < 0 {
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panic(ErrRowAccess)
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}
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if len(src) != m.mat.Cols {
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panic(ErrRowLength)
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}
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copy(m.rawRowView(i), src)
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}
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// RowView returns row i of the matrix data represented as a column vector,
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// backed by the matrix data.
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//
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// See RowViewer for more information.
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func (m *Dense) RowView(i int) Vector {
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var v VecDense
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v.RowViewOf(m, i)
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return &v
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}
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// RawRowView returns a slice backed by the same array as backing the
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// receiver.
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func (m *Dense) RawRowView(i int) []float64 {
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if i >= m.mat.Rows || i < 0 {
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panic(ErrRowAccess)
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}
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return m.rawRowView(i)
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}
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func (m *Dense) rawRowView(i int) []float64 {
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return m.mat.Data[i*m.mat.Stride : i*m.mat.Stride+m.mat.Cols]
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}
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// DiagView returns the diagonal as a matrix backed by the original data.
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func (m *Dense) DiagView() Diagonal {
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n := min(m.mat.Rows, m.mat.Cols)
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return &DiagDense{
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mat: blas64.Vector{
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N: n,
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Inc: m.mat.Stride + 1,
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Data: m.mat.Data[:(n-1)*m.mat.Stride+n],
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},
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}
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}
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// Slice returns a new Matrix that shares backing data with the receiver.
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// The returned matrix starts at {i,j} of the receiver and extends k-i rows
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// and l-j columns. The final row in the resulting matrix is k-1 and the
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// final column is l-1.
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// Slice panics with ErrIndexOutOfRange if the slice is outside the capacity
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// of the receiver.
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func (m *Dense) Slice(i, k, j, l int) Matrix {
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mr, mc := m.Caps()
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if i < 0 || mr <= i || j < 0 || mc <= j || k < i || mr < k || l < j || mc < l {
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if i == k || j == l {
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panic(ErrZeroLength)
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}
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panic(ErrIndexOutOfRange)
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}
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t := *m
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t.mat.Data = t.mat.Data[i*t.mat.Stride+j : (k-1)*t.mat.Stride+l]
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t.mat.Rows = k - i
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t.mat.Cols = l - j
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t.capRows -= i
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t.capCols -= j
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return &t
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}
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// Grow returns the receiver expanded by r rows and c columns. If the dimensions
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// of the expanded matrix are outside the capacities of the receiver a new
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// allocation is made, otherwise not. Note the receiver itself is not modified
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// during the call to Grow.
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func (m *Dense) Grow(r, c int) Matrix {
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if r < 0 || c < 0 {
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panic(ErrIndexOutOfRange)
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}
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if r == 0 && c == 0 {
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return m
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}
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r += m.mat.Rows
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c += m.mat.Cols
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var t Dense
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switch {
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case m.mat.Rows == 0 || m.mat.Cols == 0:
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t.mat = blas64.General{
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Rows: r,
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Cols: c,
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Stride: c,
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// We zero because we don't know how the matrix will be used.
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// In other places, the mat is immediately filled with a result;
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// this is not the case here.
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Data: useZeroed(m.mat.Data, r*c),
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}
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case r > m.capRows || c > m.capCols:
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cr := max(r, m.capRows)
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cc := max(c, m.capCols)
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t.mat = blas64.General{
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Rows: r,
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Cols: c,
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Stride: cc,
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Data: make([]float64, cr*cc),
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}
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t.capRows = cr
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t.capCols = cc
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// Copy the complete matrix over to the new matrix.
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// Including elements not currently visible. Use a temporary structure
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// to avoid modifying the receiver.
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var tmp Dense
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tmp.mat = blas64.General{
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Rows: m.mat.Rows,
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Cols: m.mat.Cols,
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Stride: m.mat.Stride,
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Data: m.mat.Data,
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}
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tmp.capRows = m.capRows
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tmp.capCols = m.capCols
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t.Copy(&tmp)
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return &t
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default:
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t.mat = blas64.General{
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Data: m.mat.Data[:(r-1)*m.mat.Stride+c],
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Rows: r,
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Cols: c,
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Stride: m.mat.Stride,
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}
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}
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t.capRows = r
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t.capCols = c
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return &t
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}
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// Clone makes a copy of a into the receiver, overwriting the previous value of
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// the receiver. The clone operation does not make any restriction on shape and
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// will not cause shadowing.
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//
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// See the Cloner interface for more information.
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func (m *Dense) Clone(a Matrix) {
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r, c := a.Dims()
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mat := blas64.General{
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Rows: r,
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Cols: c,
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Stride: c,
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}
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m.capRows, m.capCols = r, c
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aU, trans := untranspose(a)
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switch aU := aU.(type) {
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case RawMatrixer:
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amat := aU.RawMatrix()
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mat.Data = make([]float64, r*c)
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if trans {
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for i := 0; i < r; i++ {
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blas64.Copy(blas64.Vector{N: c, Inc: amat.Stride, Data: amat.Data[i : i+(c-1)*amat.Stride+1]},
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blas64.Vector{N: c, Inc: 1, Data: mat.Data[i*c : (i+1)*c]})
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}
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} else {
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for i := 0; i < r; i++ {
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copy(mat.Data[i*c:(i+1)*c], amat.Data[i*amat.Stride:i*amat.Stride+c])
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}
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}
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case *VecDense:
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amat := aU.mat
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mat.Data = make([]float64, aU.mat.N)
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blas64.Copy(blas64.Vector{N: aU.mat.N, Inc: amat.Inc, Data: amat.Data},
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blas64.Vector{N: aU.mat.N, Inc: 1, Data: mat.Data})
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default:
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mat.Data = make([]float64, r*c)
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w := *m
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w.mat = mat
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for i := 0; i < r; i++ {
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for j := 0; j < c; j++ {
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w.set(i, j, a.At(i, j))
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}
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}
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*m = w
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return
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}
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m.mat = mat
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}
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// Copy makes a copy of elements of a into the receiver. It is similar to the
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|
|
// built-in copy; it copies as much as the overlap between the two matrices and
|
|
|
// returns the number of rows and columns it copied. If a aliases the receiver
|
|
|
// and is a transposed Dense or VecDense, with a non-unitary increment, Copy will
|
|
|
// panic.
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|
|
//
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|
|
// See the Copier interface for more information.
|
|
|
func (m *Dense) Copy(a Matrix) (r, c int) {
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|
|
r, c = a.Dims()
|
|
|
if a == m {
|
|
|
return r, c
|
|
|
}
|
|
|
r = min(r, m.mat.Rows)
|
|
|
c = min(c, m.mat.Cols)
|
|
|
if r == 0 || c == 0 {
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|
|
return 0, 0
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|
}
|
|
|
|
|
|
aU, trans := untranspose(a)
|
|
|
switch aU := aU.(type) {
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|
|
case RawMatrixer:
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|
|
amat := aU.RawMatrix()
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|
|
if trans {
|
|
|
if amat.Stride != 1 {
|
|
|
m.checkOverlap(amat)
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|
|
}
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|
|
for i := 0; i < r; i++ {
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|
|
blas64.Copy(blas64.Vector{N: c, Inc: amat.Stride, Data: amat.Data[i : i+(c-1)*amat.Stride+1]},
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|
|
blas64.Vector{N: c, Inc: 1, Data: m.mat.Data[i*m.mat.Stride : i*m.mat.Stride+c]})
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|
|
}
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|
|
} else {
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|
|
switch o := offset(m.mat.Data, amat.Data); {
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|
|
case o < 0:
|
|
|
for i := r - 1; i >= 0; i-- {
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|
|
copy(m.mat.Data[i*m.mat.Stride:i*m.mat.Stride+c], amat.Data[i*amat.Stride:i*amat.Stride+c])
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|
|
}
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|
|
case o > 0:
|
|
|
for i := 0; i < r; i++ {
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|
|
copy(m.mat.Data[i*m.mat.Stride:i*m.mat.Stride+c], amat.Data[i*amat.Stride:i*amat.Stride+c])
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|
|
}
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|
|
default:
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|
|
// Nothing to do.
|
|
|
}
|
|
|
}
|
|
|
case *VecDense:
|
|
|
var n, stride int
|
|
|
amat := aU.mat
|
|
|
if trans {
|
|
|
if amat.Inc != 1 {
|
|
|
m.checkOverlap(aU.asGeneral())
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|
|
}
|
|
|
n = c
|
|
|
stride = 1
|
|
|
} else {
|
|
|
n = r
|
|
|
stride = m.mat.Stride
|
|
|
}
|
|
|
if amat.Inc == 1 && stride == 1 {
|
|
|
copy(m.mat.Data, amat.Data[:n])
|
|
|
break
|
|
|
}
|
|
|
switch o := offset(m.mat.Data, amat.Data); {
|
|
|
case o < 0:
|
|
|
blas64.Copy(blas64.Vector{N: n, Inc: -amat.Inc, Data: amat.Data},
|
|
|
blas64.Vector{N: n, Inc: -stride, Data: m.mat.Data})
|
|
|
case o > 0:
|
|
|
blas64.Copy(blas64.Vector{N: n, Inc: amat.Inc, Data: amat.Data},
|
|
|
blas64.Vector{N: n, Inc: stride, Data: m.mat.Data})
|
|
|
default:
|
|
|
// Nothing to do.
|
|
|
}
|
|
|
default:
|
|
|
m.checkOverlapMatrix(aU)
|
|
|
for i := 0; i < r; i++ {
|
|
|
for j := 0; j < c; j++ {
|
|
|
m.set(i, j, a.At(i, j))
|
|
|
}
|
|
|
}
|
|
|
}
|
|
|
|
|
|
return r, c
|
|
|
}
|
|
|
|
|
|
// Stack appends the rows of b onto the rows of a, placing the result into the
|
|
|
// receiver with b placed in the greater indexed rows. Stack will panic if the
|
|
|
// two input matrices do not have the same number of columns or the constructed
|
|
|
// stacked matrix is not the same shape as the receiver.
|
|
|
func (m *Dense) Stack(a, b Matrix) {
|
|
|
ar, ac := a.Dims()
|
|
|
br, bc := b.Dims()
|
|
|
if ac != bc || m == a || m == b {
|
|
|
panic(ErrShape)
|
|
|
}
|
|
|
|
|
|
m.reuseAs(ar+br, ac)
|
|
|
|
|
|
m.Copy(a)
|
|
|
w := m.Slice(ar, ar+br, 0, bc).(*Dense)
|
|
|
w.Copy(b)
|
|
|
}
|
|
|
|
|
|
// Augment creates the augmented matrix of a and b, where b is placed in the
|
|
|
// greater indexed columns. Augment will panic if the two input matrices do
|
|
|
// not have the same number of rows or the constructed augmented matrix is
|
|
|
// not the same shape as the receiver.
|
|
|
func (m *Dense) Augment(a, b Matrix) {
|
|
|
ar, ac := a.Dims()
|
|
|
br, bc := b.Dims()
|
|
|
if ar != br || m == a || m == b {
|
|
|
panic(ErrShape)
|
|
|
}
|
|
|
|
|
|
m.reuseAs(ar, ac+bc)
|
|
|
|
|
|
m.Copy(a)
|
|
|
w := m.Slice(0, br, ac, ac+bc).(*Dense)
|
|
|
w.Copy(b)
|
|
|
}
|
|
|
|
|
|
// Trace returns the trace of the matrix. The matrix must be square or Trace
|
|
|
// will panic.
|
|
|
func (m *Dense) Trace() float64 {
|
|
|
if m.mat.Rows != m.mat.Cols {
|
|
|
panic(ErrSquare)
|
|
|
}
|
|
|
// TODO(btracey): could use internal asm sum routine.
|
|
|
var v float64
|
|
|
for i := 0; i < m.mat.Rows; i++ {
|
|
|
v += m.mat.Data[i*m.mat.Stride+i]
|
|
|
}
|
|
|
return v
|
|
|
}
|