mirror of https://github.com/k3s-io/k3s
742 lines
16 KiB
Go
742 lines
16 KiB
Go
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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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"gonum.org/v1/gonum/internal/asm/f64"
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)
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var (
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vector *VecDense
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_ Matrix = vector
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_ Vector = vector
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_ Reseter = vector
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)
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// Vector is a vector.
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type Vector interface {
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Matrix
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AtVec(int) float64
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Len() int
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}
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// TransposeVec is a type for performing an implicit transpose of a Vector.
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// It implements the Vector interface, returning values from the transpose
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// of the vector within.
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type TransposeVec struct {
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Vector Vector
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}
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// At returns the value of the element at row i and column j of the transposed
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// matrix, that is, row j and column i of the Vector field.
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func (t TransposeVec) At(i, j int) float64 {
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return t.Vector.At(j, i)
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}
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// AtVec returns the element at position i. It panics if i is out of bounds.
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func (t TransposeVec) AtVec(i int) float64 {
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return t.Vector.AtVec(i)
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}
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// Dims returns the dimensions of the transposed vector.
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func (t TransposeVec) Dims() (r, c int) {
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c, r = t.Vector.Dims()
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return r, c
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}
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// T performs an implicit transpose by returning the Vector field.
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func (t TransposeVec) T() Matrix {
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return t.Vector
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}
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// Len returns the number of columns in the vector.
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func (t TransposeVec) Len() int {
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return t.Vector.Len()
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}
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// TVec performs an implicit transpose by returning the Vector field.
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func (t TransposeVec) TVec() Vector {
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return t.Vector
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}
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// Untranspose returns the Vector field.
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func (t TransposeVec) Untranspose() Matrix {
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return t.Vector
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}
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func (t TransposeVec) UntransposeVec() Vector {
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return t.Vector
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}
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// VecDense represents a column vector.
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type VecDense struct {
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mat blas64.Vector
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// A BLAS vector can have a negative increment, but allowing this
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// in the mat type complicates a lot of code, and doesn't gain anything.
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// VecDense must have positive increment in this package.
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}
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// NewVecDense creates a new VecDense of length n. If data == nil,
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// a new slice is allocated for the backing slice. If len(data) == n, data is
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// used as the backing slice, and changes to the elements of the returned VecDense
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// will be reflected in data. If neither of these is true, NewVecDense will panic.
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// NewVecDense will panic if n is zero.
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func NewVecDense(n int, data []float64) *VecDense {
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if n <= 0 {
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if n == 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 len(data) != n && data != nil {
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panic(ErrShape)
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}
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if data == nil {
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data = make([]float64, n)
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}
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return &VecDense{
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mat: blas64.Vector{
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N: n,
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Inc: 1,
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Data: data,
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},
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}
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}
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// SliceVec returns a new Vector that shares backing data with the receiver.
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// The returned matrix starts at i of the receiver and extends k-i elements.
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// SliceVec panics with ErrIndexOutOfRange if the slice is outside the capacity
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// of the receiver.
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func (v *VecDense) SliceVec(i, k int) Vector {
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if i < 0 || k <= i || v.Cap() < k {
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panic(ErrIndexOutOfRange)
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}
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return &VecDense{
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mat: blas64.Vector{
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N: k - i,
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Inc: v.mat.Inc,
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Data: v.mat.Data[i*v.mat.Inc : (k-1)*v.mat.Inc+1],
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},
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}
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}
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// Dims returns the number of rows and columns in the matrix. Columns is always 1
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// for a non-Reset vector.
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func (v *VecDense) Dims() (r, c int) {
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if v.IsZero() {
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return 0, 0
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}
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return v.mat.N, 1
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}
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// Caps returns the number of rows and columns in the backing matrix. Columns is always 1
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// for a non-Reset vector.
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func (v *VecDense) Caps() (r, c int) {
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if v.IsZero() {
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return 0, 0
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}
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return v.Cap(), 1
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}
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// Len returns the length of the vector.
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func (v *VecDense) Len() int {
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return v.mat.N
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}
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// Cap returns the capacity of the vector.
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func (v *VecDense) Cap() int {
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if v.IsZero() {
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return 0
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}
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return (cap(v.mat.Data)-1)/v.mat.Inc + 1
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}
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// T performs an implicit transpose by returning the receiver inside a Transpose.
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func (v *VecDense) T() Matrix {
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return Transpose{v}
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}
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// TVec performs an implicit transpose by returning the receiver inside a TransposeVec.
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func (v *VecDense) TVec() Vector {
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return TransposeVec{v}
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}
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// Reset zeros the length of the vector 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 (v *VecDense) Reset() {
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// No change of Inc or N to 0 may be
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// made unless both are set to 0.
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v.mat.Inc = 0
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v.mat.N = 0
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v.mat.Data = v.mat.Data[:0]
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}
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// Zero sets all of the matrix elements to zero.
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func (v *VecDense) Zero() {
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for i := 0; i < v.mat.N; i++ {
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v.mat.Data[v.mat.Inc*i] = 0
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}
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}
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// CloneVec makes a copy of a into the receiver, overwriting the previous value
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// of the receiver.
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func (v *VecDense) CloneVec(a Vector) {
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if v == a {
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return
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}
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n := a.Len()
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v.mat = blas64.Vector{
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N: n,
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Inc: 1,
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Data: use(v.mat.Data, n),
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}
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if r, ok := a.(RawVectorer); ok {
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blas64.Copy(r.RawVector(), v.mat)
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return
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}
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for i := 0; i < a.Len(); i++ {
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v.SetVec(i, a.AtVec(i))
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}
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}
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// VecDenseCopyOf returns a newly allocated copy of the elements of a.
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func VecDenseCopyOf(a Vector) *VecDense {
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v := &VecDense{}
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v.CloneVec(a)
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return v
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}
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func (v *VecDense) RawVector() blas64.Vector {
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return v.mat
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}
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// CopyVec 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 vectors and
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// returns the number of elements it copied.
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func (v *VecDense) CopyVec(a Vector) int {
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n := min(v.Len(), a.Len())
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if v == a {
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return n
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}
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if r, ok := a.(RawVectorer); ok {
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blas64.Copy(r.RawVector(), v.mat)
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return n
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}
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for i := 0; i < n; i++ {
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v.setVec(i, a.AtVec(i))
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}
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return n
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}
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// ScaleVec scales the vector a by alpha, placing the result in the receiver.
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func (v *VecDense) ScaleVec(alpha float64, a Vector) {
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n := a.Len()
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if v == a {
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if v.mat.Inc == 1 {
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f64.ScalUnitary(alpha, v.mat.Data)
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return
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}
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f64.ScalInc(alpha, v.mat.Data, uintptr(n), uintptr(v.mat.Inc))
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return
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}
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v.reuseAs(n)
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if rv, ok := a.(RawVectorer); ok {
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mat := rv.RawVector()
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v.checkOverlap(mat)
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if v.mat.Inc == 1 && mat.Inc == 1 {
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f64.ScalUnitaryTo(v.mat.Data, alpha, mat.Data)
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return
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}
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f64.ScalIncTo(v.mat.Data, uintptr(v.mat.Inc),
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alpha, mat.Data, uintptr(n), uintptr(mat.Inc))
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return
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}
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for i := 0; i < n; i++ {
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v.setVec(i, alpha*a.AtVec(i))
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}
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}
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// AddScaledVec adds the vectors a and alpha*b, placing the result in the receiver.
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func (v *VecDense) AddScaledVec(a Vector, alpha float64, b Vector) {
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if alpha == 1 {
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v.AddVec(a, b)
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return
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}
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if alpha == -1 {
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v.SubVec(a, b)
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return
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}
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ar := a.Len()
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br := b.Len()
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if ar != br {
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panic(ErrShape)
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}
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var amat, bmat blas64.Vector
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fast := true
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aU, _ := untranspose(a)
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if rv, ok := aU.(RawVectorer); ok {
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amat = rv.RawVector()
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if v != a {
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v.checkOverlap(amat)
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}
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} else {
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fast = false
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}
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bU, _ := untranspose(b)
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if rv, ok := bU.(RawVectorer); ok {
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bmat = rv.RawVector()
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if v != b {
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v.checkOverlap(bmat)
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}
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} else {
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fast = false
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}
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v.reuseAs(ar)
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switch {
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case alpha == 0: // v <- a
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if v == a {
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return
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}
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v.CopyVec(a)
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case v == a && v == b: // v <- v + alpha * v = (alpha + 1) * v
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blas64.Scal(alpha+1, v.mat)
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case !fast: // v <- a + alpha * b without blas64 support.
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for i := 0; i < ar; i++ {
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v.setVec(i, a.AtVec(i)+alpha*b.AtVec(i))
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}
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case v == a && v != b: // v <- v + alpha * b
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if v.mat.Inc == 1 && bmat.Inc == 1 {
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// Fast path for a common case.
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f64.AxpyUnitaryTo(v.mat.Data, alpha, bmat.Data, amat.Data)
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} else {
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f64.AxpyInc(alpha, bmat.Data, v.mat.Data,
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uintptr(ar), uintptr(bmat.Inc), uintptr(v.mat.Inc), 0, 0)
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}
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default: // v <- a + alpha * b or v <- a + alpha * v
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if v.mat.Inc == 1 && amat.Inc == 1 && bmat.Inc == 1 {
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// Fast path for a common case.
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f64.AxpyUnitaryTo(v.mat.Data, alpha, bmat.Data, amat.Data)
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} else {
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f64.AxpyIncTo(v.mat.Data, uintptr(v.mat.Inc), 0,
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alpha, bmat.Data, amat.Data,
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uintptr(ar), uintptr(bmat.Inc), uintptr(amat.Inc), 0, 0)
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}
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}
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}
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// AddVec adds the vectors a and b, placing the result in the receiver.
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func (v *VecDense) AddVec(a, b Vector) {
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ar := a.Len()
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br := b.Len()
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if ar != br {
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panic(ErrShape)
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}
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v.reuseAs(ar)
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aU, _ := untranspose(a)
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bU, _ := untranspose(b)
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if arv, ok := aU.(RawVectorer); ok {
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if brv, ok := bU.(RawVectorer); ok {
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amat := arv.RawVector()
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bmat := brv.RawVector()
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if v != a {
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v.checkOverlap(amat)
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}
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if v != b {
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v.checkOverlap(bmat)
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}
|
|||
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if v.mat.Inc == 1 && amat.Inc == 1 && bmat.Inc == 1 {
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// Fast path for a common case.
|
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f64.AxpyUnitaryTo(v.mat.Data, 1, bmat.Data, amat.Data)
|
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return
|
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|
}
|
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f64.AxpyIncTo(v.mat.Data, uintptr(v.mat.Inc), 0,
|
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1, bmat.Data, amat.Data,
|
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uintptr(ar), uintptr(bmat.Inc), uintptr(amat.Inc), 0, 0)
|
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|
return
|
|||
|
}
|
|||
|
}
|
|||
|
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|||
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for i := 0; i < ar; i++ {
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v.setVec(i, a.AtVec(i)+b.AtVec(i))
|
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}
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}
|
|||
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// SubVec subtracts the vector b from a, placing the result in the receiver.
|
|||
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func (v *VecDense) SubVec(a, b Vector) {
|
|||
|
ar := a.Len()
|
|||
|
br := b.Len()
|
|||
|
|
|||
|
if ar != br {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
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v.reuseAs(ar)
|
|||
|
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aU, _ := untranspose(a)
|
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bU, _ := untranspose(b)
|
|||
|
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if arv, ok := aU.(RawVectorer); ok {
|
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if brv, ok := bU.(RawVectorer); ok {
|
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amat := arv.RawVector()
|
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bmat := brv.RawVector()
|
|||
|
|
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if v != a {
|
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v.checkOverlap(amat)
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|
}
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|
if v != b {
|
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|
v.checkOverlap(bmat)
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}
|
|||
|
|
|||
|
if v.mat.Inc == 1 && amat.Inc == 1 && bmat.Inc == 1 {
|
|||
|
// Fast path for a common case.
|
|||
|
f64.AxpyUnitaryTo(v.mat.Data, -1, bmat.Data, amat.Data)
|
|||
|
return
|
|||
|
}
|
|||
|
f64.AxpyIncTo(v.mat.Data, uintptr(v.mat.Inc), 0,
|
|||
|
-1, bmat.Data, amat.Data,
|
|||
|
uintptr(ar), uintptr(bmat.Inc), uintptr(amat.Inc), 0, 0)
|
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|
return
|
|||
|
}
|
|||
|
}
|
|||
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|
|||
|
for i := 0; i < ar; i++ {
|
|||
|
v.setVec(i, a.AtVec(i)-b.AtVec(i))
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// MulElemVec performs element-wise multiplication of a and b, placing the result
|
|||
|
// in the receiver.
|
|||
|
func (v *VecDense) MulElemVec(a, b Vector) {
|
|||
|
ar := a.Len()
|
|||
|
br := b.Len()
|
|||
|
|
|||
|
if ar != br {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
|||
|
v.reuseAs(ar)
|
|||
|
|
|||
|
aU, _ := untranspose(a)
|
|||
|
bU, _ := untranspose(b)
|
|||
|
|
|||
|
if arv, ok := aU.(RawVectorer); ok {
|
|||
|
if brv, ok := bU.(RawVectorer); ok {
|
|||
|
amat := arv.RawVector()
|
|||
|
bmat := brv.RawVector()
|
|||
|
|
|||
|
if v != a {
|
|||
|
v.checkOverlap(amat)
|
|||
|
}
|
|||
|
if v != b {
|
|||
|
v.checkOverlap(bmat)
|
|||
|
}
|
|||
|
|
|||
|
if v.mat.Inc == 1 && amat.Inc == 1 && bmat.Inc == 1 {
|
|||
|
// Fast path for a common case.
|
|||
|
for i, a := range amat.Data {
|
|||
|
v.mat.Data[i] = a * bmat.Data[i]
|
|||
|
}
|
|||
|
return
|
|||
|
}
|
|||
|
var ia, ib int
|
|||
|
for i := 0; i < ar; i++ {
|
|||
|
v.setVec(i, amat.Data[ia]*bmat.Data[ib])
|
|||
|
ia += amat.Inc
|
|||
|
ib += bmat.Inc
|
|||
|
}
|
|||
|
return
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
for i := 0; i < ar; i++ {
|
|||
|
v.setVec(i, a.AtVec(i)*b.AtVec(i))
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// DivElemVec performs element-wise division of a by b, placing the result
|
|||
|
// in the receiver.
|
|||
|
func (v *VecDense) DivElemVec(a, b Vector) {
|
|||
|
ar := a.Len()
|
|||
|
br := b.Len()
|
|||
|
|
|||
|
if ar != br {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
|||
|
v.reuseAs(ar)
|
|||
|
|
|||
|
aU, _ := untranspose(a)
|
|||
|
bU, _ := untranspose(b)
|
|||
|
|
|||
|
if arv, ok := aU.(RawVectorer); ok {
|
|||
|
if brv, ok := bU.(RawVectorer); ok {
|
|||
|
amat := arv.RawVector()
|
|||
|
bmat := brv.RawVector()
|
|||
|
|
|||
|
if v != a {
|
|||
|
v.checkOverlap(amat)
|
|||
|
}
|
|||
|
if v != b {
|
|||
|
v.checkOverlap(bmat)
|
|||
|
}
|
|||
|
|
|||
|
if v.mat.Inc == 1 && amat.Inc == 1 && bmat.Inc == 1 {
|
|||
|
// Fast path for a common case.
|
|||
|
for i, a := range amat.Data {
|
|||
|
v.setVec(i, a/bmat.Data[i])
|
|||
|
}
|
|||
|
return
|
|||
|
}
|
|||
|
var ia, ib int
|
|||
|
for i := 0; i < ar; i++ {
|
|||
|
v.setVec(i, amat.Data[ia]/bmat.Data[ib])
|
|||
|
ia += amat.Inc
|
|||
|
ib += bmat.Inc
|
|||
|
}
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
for i := 0; i < ar; i++ {
|
|||
|
v.setVec(i, a.AtVec(i)/b.AtVec(i))
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// MulVec computes a * b. The result is stored into the receiver.
|
|||
|
// MulVec panics if the number of columns in a does not equal the number of rows in b
|
|||
|
// or if the number of columns in b does not equal 1.
|
|||
|
func (v *VecDense) MulVec(a Matrix, b Vector) {
|
|||
|
r, c := a.Dims()
|
|||
|
br, bc := b.Dims()
|
|||
|
if c != br || bc != 1 {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
|||
|
aU, trans := untranspose(a)
|
|||
|
var bmat blas64.Vector
|
|||
|
fast := true
|
|||
|
bU, _ := untranspose(b)
|
|||
|
if rv, ok := bU.(RawVectorer); ok {
|
|||
|
bmat = rv.RawVector()
|
|||
|
if v != b {
|
|||
|
v.checkOverlap(bmat)
|
|||
|
}
|
|||
|
} else {
|
|||
|
fast = false
|
|||
|
}
|
|||
|
|
|||
|
v.reuseAs(r)
|
|||
|
var restore func()
|
|||
|
if v == aU {
|
|||
|
v, restore = v.isolatedWorkspace(aU.(*VecDense))
|
|||
|
defer restore()
|
|||
|
} else if v == b {
|
|||
|
v, restore = v.isolatedWorkspace(b)
|
|||
|
defer restore()
|
|||
|
}
|
|||
|
|
|||
|
// TODO(kortschak): Improve the non-fast paths.
|
|||
|
switch aU := aU.(type) {
|
|||
|
case Vector:
|
|||
|
if b.Len() == 1 {
|
|||
|
// {n,1} x {1,1}
|
|||
|
v.ScaleVec(b.AtVec(0), aU)
|
|||
|
return
|
|||
|
}
|
|||
|
|
|||
|
// {1,n} x {n,1}
|
|||
|
if fast {
|
|||
|
if rv, ok := aU.(RawVectorer); ok {
|
|||
|
amat := rv.RawVector()
|
|||
|
if v != aU {
|
|||
|
v.checkOverlap(amat)
|
|||
|
}
|
|||
|
|
|||
|
if amat.Inc == 1 && bmat.Inc == 1 {
|
|||
|
// Fast path for a common case.
|
|||
|
v.setVec(0, f64.DotUnitary(amat.Data, bmat.Data))
|
|||
|
return
|
|||
|
}
|
|||
|
v.setVec(0, f64.DotInc(amat.Data, bmat.Data,
|
|||
|
uintptr(c), uintptr(amat.Inc), uintptr(bmat.Inc), 0, 0))
|
|||
|
return
|
|||
|
}
|
|||
|
}
|
|||
|
var sum float64
|
|||
|
for i := 0; i < c; i++ {
|
|||
|
sum += aU.AtVec(i) * b.AtVec(i)
|
|||
|
}
|
|||
|
v.setVec(0, sum)
|
|||
|
return
|
|||
|
case RawSymmetricer:
|
|||
|
if fast {
|
|||
|
amat := aU.RawSymmetric()
|
|||
|
// We don't know that a is a *SymDense, so make
|
|||
|
// a temporary SymDense to check overlap.
|
|||
|
(&SymDense{mat: amat}).checkOverlap(v.asGeneral())
|
|||
|
blas64.Symv(1, amat, bmat, 0, v.mat)
|
|||
|
return
|
|||
|
}
|
|||
|
case RawTriangular:
|
|||
|
v.CopyVec(b)
|
|||
|
amat := aU.RawTriangular()
|
|||
|
// We don't know that a is a *TriDense, so make
|
|||
|
// a temporary TriDense to check overlap.
|
|||
|
(&TriDense{mat: amat}).checkOverlap(v.asGeneral())
|
|||
|
ta := blas.NoTrans
|
|||
|
if trans {
|
|||
|
ta = blas.Trans
|
|||
|
}
|
|||
|
blas64.Trmv(ta, amat, v.mat)
|
|||
|
case RawMatrixer:
|
|||
|
if fast {
|
|||
|
amat := aU.RawMatrix()
|
|||
|
// We don't know that a is a *Dense, so make
|
|||
|
// a temporary Dense to check overlap.
|
|||
|
(&Dense{mat: amat}).checkOverlap(v.asGeneral())
|
|||
|
t := blas.NoTrans
|
|||
|
if trans {
|
|||
|
t = blas.Trans
|
|||
|
}
|
|||
|
blas64.Gemv(t, 1, amat, bmat, 0, v.mat)
|
|||
|
return
|
|||
|
}
|
|||
|
default:
|
|||
|
if fast {
|
|||
|
for i := 0; i < r; i++ {
|
|||
|
var f float64
|
|||
|
for j := 0; j < c; j++ {
|
|||
|
f += a.At(i, j) * bmat.Data[j*bmat.Inc]
|
|||
|
}
|
|||
|
v.setVec(i, f)
|
|||
|
}
|
|||
|
return
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
for i := 0; i < r; i++ {
|
|||
|
var f float64
|
|||
|
for j := 0; j < c; j++ {
|
|||
|
f += a.At(i, j) * b.AtVec(j)
|
|||
|
}
|
|||
|
v.setVec(i, f)
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// reuseAs resizes an empty vector to a r×1 vector,
|
|||
|
// or checks that a non-empty matrix is r×1.
|
|||
|
func (v *VecDense) reuseAs(r int) {
|
|||
|
if r == 0 {
|
|||
|
panic(ErrZeroLength)
|
|||
|
}
|
|||
|
if v.IsZero() {
|
|||
|
v.mat = blas64.Vector{
|
|||
|
N: r,
|
|||
|
Inc: 1,
|
|||
|
Data: use(v.mat.Data, r),
|
|||
|
}
|
|||
|
return
|
|||
|
}
|
|||
|
if r != v.mat.N {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// IsZero returns whether the receiver is zero-sized. Zero-sized vectors can be the
|
|||
|
// receiver for size-restricted operations. VecDenses can be zeroed using Reset.
|
|||
|
func (v *VecDense) IsZero() bool {
|
|||
|
// It must be the case that v.Dims() returns
|
|||
|
// zeros in this case. See comment in Reset().
|
|||
|
return v.mat.Inc == 0
|
|||
|
}
|
|||
|
|
|||
|
func (v *VecDense) isolatedWorkspace(a Vector) (n *VecDense, restore func()) {
|
|||
|
l := a.Len()
|
|||
|
if l == 0 {
|
|||
|
panic(ErrZeroLength)
|
|||
|
}
|
|||
|
n = getWorkspaceVec(l, false)
|
|||
|
return n, func() {
|
|||
|
v.CopyVec(n)
|
|||
|
putWorkspaceVec(n)
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// asDense returns a Dense representation of the receiver with the same
|
|||
|
// underlying data.
|
|||
|
func (v *VecDense) asDense() *Dense {
|
|||
|
return &Dense{
|
|||
|
mat: v.asGeneral(),
|
|||
|
capRows: v.mat.N,
|
|||
|
capCols: 1,
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// asGeneral returns a blas64.General representation of the receiver with the
|
|||
|
// same underlying data.
|
|||
|
func (v *VecDense) asGeneral() blas64.General {
|
|||
|
return blas64.General{
|
|||
|
Rows: v.mat.N,
|
|||
|
Cols: 1,
|
|||
|
Stride: v.mat.Inc,
|
|||
|
Data: v.mat.Data,
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
// ColViewOf reflects the column j of the RawMatrixer m, into the receiver
|
|||
|
// backed by the same underlying data. The length of the receiver must either be
|
|||
|
// zero or match the number of rows in m.
|
|||
|
func (v *VecDense) ColViewOf(m RawMatrixer, j int) {
|
|||
|
rm := m.RawMatrix()
|
|||
|
|
|||
|
if j >= rm.Cols || j < 0 {
|
|||
|
panic(ErrColAccess)
|
|||
|
}
|
|||
|
if !v.IsZero() && v.mat.N != rm.Rows {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
|||
|
v.mat.Inc = rm.Stride
|
|||
|
v.mat.Data = rm.Data[j : (rm.Rows-1)*rm.Stride+j+1]
|
|||
|
v.mat.N = rm.Rows
|
|||
|
}
|
|||
|
|
|||
|
// RowViewOf reflects the row i of the RawMatrixer m, into the receiver
|
|||
|
// backed by the same underlying data. The length of the receiver must either be
|
|||
|
// zero or match the number of columns in m.
|
|||
|
func (v *VecDense) RowViewOf(m RawMatrixer, i int) {
|
|||
|
rm := m.RawMatrix()
|
|||
|
|
|||
|
if i >= rm.Rows || i < 0 {
|
|||
|
panic(ErrRowAccess)
|
|||
|
}
|
|||
|
if !v.IsZero() && v.mat.N != rm.Cols {
|
|||
|
panic(ErrShape)
|
|||
|
}
|
|||
|
|
|||
|
v.mat.Inc = 1
|
|||
|
v.mat.Data = rm.Data[i*rm.Stride : i*rm.Stride+rm.Cols]
|
|||
|
v.mat.N = rm.Cols
|
|||
|
}
|