mat/shadow.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2015 The Gonum 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 mat

 import "gonum.org/v1/gonum/blas/blas64"

 // checkOverlap returns false if the receiver does not overlap data elements
 // referenced by the parameter and panics otherwise.
 //
 // checkOverlap methods return a boolean to allow the check call to be added to a
 // boolean expression, making use of short-circuit operators.
 func checkOverlap(a, b blas64.General) bool {
 	if cap(a.Data) == 0 || cap(b.Data) == 0 {
 		return false
 	}

 	off := offset(a.Data[:1], b.Data[:1])

 	if off == 0 {
 		// At least one element overlaps.
 		if a.Cols == b.Cols && a.Rows == b.Rows && a.Stride == b.Stride {
 			panic(regionIdentity)
 		}
 		panic(regionOverlap)
 	}

 	if off > 0 && len(a.Data) <= off {
 		// We know a is completely before b.
 		return false
 	}
 	if off < 0 && len(b.Data) <= -off {
 		// We know a is completely after b.
 		return false
 	}

 	if a.Stride != b.Stride && a.Stride != 1 && b.Stride != 1 {
 		// Too hard, so assume the worst; if either stride
 		// is one it will be caught in rectanglesOverlap.
 		panic(mismatchedStrides)
 	}

 	if off < 0 {
 		off = -off
 		a.Cols, b.Cols = b.Cols, a.Cols
 	}
 	if rectanglesOverlap(off, a.Cols, b.Cols, min(a.Stride, b.Stride)) {
 		panic(regionOverlap)
 	}
 	return false
 }

 func (m *Dense) checkOverlap(a blas64.General) bool {
 	return checkOverlap(m.RawMatrix(), a)
 }

 func (m *Dense) checkOverlapMatrix(a Matrix) bool {
 	if m == a {
 		return false
 	}
 	var amat blas64.General
 	switch ar := a.(type) {
 	default:
 		return false
 	case RawMatrixer:
 		amat = ar.RawMatrix()
 	case RawSymmetricer:
 		amat = generalFromSymmetric(ar.RawSymmetric())
 	case RawSymBander:
 		amat = generalFromSymmetricBand(ar.RawSymBand())
 	case RawTriangular:
 		amat = generalFromTriangular(ar.RawTriangular())
 	case RawVectorer:
 		r, c := a.Dims()
 		amat = generalFromVector(ar.RawVector(), r, c)
 	}
 	return m.checkOverlap(amat)
 }

 func (s *SymDense) checkOverlap(a blas64.General) bool {
 	return checkOverlap(generalFromSymmetric(s.RawSymmetric()), a)
 }

 func (s *SymDense) checkOverlapMatrix(a Matrix) bool {
 	if s == a {
 		return false
 	}
 	var amat blas64.General
 	switch ar := a.(type) {
 	default:
 		return false
 	case RawMatrixer:
 		amat = ar.RawMatrix()
 	case RawSymmetricer:
 		amat = generalFromSymmetric(ar.RawSymmetric())
 	case RawSymBander:
 		amat = generalFromSymmetricBand(ar.RawSymBand())
 	case RawTriangular:
 		amat = generalFromTriangular(ar.RawTriangular())
 	case RawVectorer:
 		r, c := a.Dims()
 		amat = generalFromVector(ar.RawVector(), r, c)
 	}
 	return s.checkOverlap(amat)
 }

 // generalFromSymmetric returns a blas64.General with the backing
 // data and dimensions of a.
 func generalFromSymmetric(a blas64.Symmetric) blas64.General {
 	return blas64.General{
 		Rows:   a.N,
 		Cols:   a.N,
 		Stride: a.Stride,
 		Data:   a.Data,
 	}
 }

 func (t *TriDense) checkOverlap(a blas64.General) bool {
 	return checkOverlap(generalFromTriangular(t.RawTriangular()), a)
 }

 func (t *TriDense) checkOverlapMatrix(a Matrix) bool {
 	if t == a {
 		return false
 	}
 	var amat blas64.General
 	switch ar := a.(type) {
 	default:
 		return false
 	case RawMatrixer:
 		amat = ar.RawMatrix()
 	case RawSymmetricer:
 		amat = generalFromSymmetric(ar.RawSymmetric())
 	case RawSymBander:
 		amat = generalFromSymmetricBand(ar.RawSymBand())
 	case RawTriangular:
 		amat = generalFromTriangular(ar.RawTriangular())
 	case RawVectorer:
 		r, c := a.Dims()
 		amat = generalFromVector(ar.RawVector(), r, c)
 	}
 	return t.checkOverlap(amat)
 }

 // generalFromTriangular returns a blas64.General with the backing
 // data and dimensions of a.
 func generalFromTriangular(a blas64.Triangular) blas64.General {
 	return blas64.General{
 		Rows:   a.N,
 		Cols:   a.N,
 		Stride: a.Stride,
 		Data:   a.Data,
 	}
 }

 func (v *VecDense) checkOverlap(a blas64.Vector) bool {
 	mat := v.mat
 	if cap(mat.Data) == 0 || cap(a.Data) == 0 {
 		return false
 	}

 	off := offset(mat.Data[:1], a.Data[:1])

 	if off == 0 {
 		// At least one element overlaps.
 		if mat.Inc == a.Inc && len(mat.Data) == len(a.Data) {
 			panic(regionIdentity)
 		}
 		panic(regionOverlap)
 	}

 	if off > 0 && len(mat.Data) <= off {
 		// We know v is completely before a.
 		return false
 	}
 	if off < 0 && len(a.Data) <= -off {
 		// We know v is completely after a.
 		return false
 	}

 	if mat.Inc != a.Inc && mat.Inc != 1 && a.Inc != 1 {
 		// Too hard, so assume the worst; if either
 		// increment is one it will be caught below.
 		panic(mismatchedStrides)
 	}
 	inc := min(mat.Inc, a.Inc)

 	if inc == 1 || off&inc == 0 {
 		panic(regionOverlap)
 	}
 	return false
 }

 // generalFromVector returns a blas64.General with the backing
 // data and dimensions of a.
 func generalFromVector(a blas64.Vector, r, c int) blas64.General {
 	return blas64.General{
 		Rows:   r,
 		Cols:   c,
 		Stride: a.Inc,
 		Data:   a.Data,
 	}
 }

 func (s *SymBandDense) checkOverlap(a blas64.General) bool {
 	return checkOverlap(generalFromSymmetricBand(s.RawSymBand()), a)
 }

 func (s *SymBandDense) checkOverlapMatrix(a Matrix) bool {
 	if s == a {
 		return false
 	}
 	var amat blas64.General
 	switch ar := a.(type) {
 	default:
 		return false
 	case RawMatrixer:
 		amat = ar.RawMatrix()
 	case RawSymmetricer:
 		amat = generalFromSymmetric(ar.RawSymmetric())
 	case RawSymBander:
 		amat = generalFromSymmetricBand(ar.RawSymBand())
 	case RawTriangular:
 		amat = generalFromTriangular(ar.RawTriangular())
 	case RawVectorer:
 		r, c := a.Dims()
 		amat = generalFromVector(ar.RawVector(), r, c)
 	}
 	return s.checkOverlap(amat)
 }

 // generalFromSymmetricBand returns a blas64.General with the backing
 // data and dimensions of a.
 func generalFromSymmetricBand(a blas64.SymmetricBand) blas64.General {
 	return blas64.General{
 		Rows:   a.N,
 		Cols:   a.K + 1,
 		Data:   a.Data,
 		Stride: a.Stride,
 	}
 }
	// Copyright ©2015 The Gonum 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 mat

	import "gonum.org/v1/gonum/blas/blas64"

	// checkOverlap returns false if the receiver does not overlap data elements
	// referenced by the parameter and panics otherwise.
	//
	// checkOverlap methods return a boolean to allow the check call to be added to a
	// boolean expression, making use of short-circuit operators.
	func checkOverlap(a, b blas64.General) bool {
	if cap(a.Data) == 0 \|\| cap(b.Data) == 0 {
	return false
	}

	off := offset(a.Data[:1], b.Data[:1])

	if off == 0 {
	// At least one element overlaps.
	if a.Cols == b.Cols && a.Rows == b.Rows && a.Stride == b.Stride {
	panic(regionIdentity)
	}
	panic(regionOverlap)
	}

	if off > 0 && len(a.Data) <= off {
	// We know a is completely before b.
	return false
	}
	if off < 0 && len(b.Data) <= -off {
	// We know a is completely after b.
	return false
	}

	if a.Stride != b.Stride && a.Stride != 1 && b.Stride != 1 {
	// Too hard, so assume the worst; if either stride
	// is one it will be caught in rectanglesOverlap.
	panic(mismatchedStrides)
	}

	if off < 0 {
	off = -off
	a.Cols, b.Cols = b.Cols, a.Cols
	}
	if rectanglesOverlap(off, a.Cols, b.Cols, min(a.Stride, b.Stride)) {
	panic(regionOverlap)
	}
	return false
	}

	func (m *Dense) checkOverlap(a blas64.General) bool {
	return checkOverlap(m.RawMatrix(), a)
	}

	func (m *Dense) checkOverlapMatrix(a Matrix) bool {
	if m == a {
	return false
	}
	var amat blas64.General
	switch ar := a.(type) {
	default:
	return false
	case RawMatrixer:
	amat = ar.RawMatrix()
	case RawSymmetricer:
	amat = generalFromSymmetric(ar.RawSymmetric())
	case RawSymBander:
	amat = generalFromSymmetricBand(ar.RawSymBand())
	case RawTriangular:
	amat = generalFromTriangular(ar.RawTriangular())
	case RawVectorer:
	r, c := a.Dims()
	amat = generalFromVector(ar.RawVector(), r, c)
	}
	return m.checkOverlap(amat)
	}

	func (s *SymDense) checkOverlap(a blas64.General) bool {
	return checkOverlap(generalFromSymmetric(s.RawSymmetric()), a)
	}

	func (s *SymDense) checkOverlapMatrix(a Matrix) bool {
	if s == a {
	return false
	}
	var amat blas64.General
	switch ar := a.(type) {
	default:
	return false
	case RawMatrixer:
	amat = ar.RawMatrix()
	case RawSymmetricer:
	amat = generalFromSymmetric(ar.RawSymmetric())
	case RawSymBander:
	amat = generalFromSymmetricBand(ar.RawSymBand())
	case RawTriangular:
	amat = generalFromTriangular(ar.RawTriangular())
	case RawVectorer:
	r, c := a.Dims()
	amat = generalFromVector(ar.RawVector(), r, c)
	}
	return s.checkOverlap(amat)
	}

	// generalFromSymmetric returns a blas64.General with the backing
	// data and dimensions of a.
	func generalFromSymmetric(a blas64.Symmetric) blas64.General {
	return blas64.General{
	Rows: a.N,
	Cols: a.N,
	Stride: a.Stride,
	Data: a.Data,
	}
	}

	func (t *TriDense) checkOverlap(a blas64.General) bool {
	return checkOverlap(generalFromTriangular(t.RawTriangular()), a)
	}

	func (t *TriDense) checkOverlapMatrix(a Matrix) bool {
	if t == a {
	return false
	}
	var amat blas64.General
	switch ar := a.(type) {
	default:
	return false
	case RawMatrixer:
	amat = ar.RawMatrix()
	case RawSymmetricer:
	amat = generalFromSymmetric(ar.RawSymmetric())
	case RawSymBander:
	amat = generalFromSymmetricBand(ar.RawSymBand())
	case RawTriangular:
	amat = generalFromTriangular(ar.RawTriangular())
	case RawVectorer:
	r, c := a.Dims()
	amat = generalFromVector(ar.RawVector(), r, c)
	}
	return t.checkOverlap(amat)
	}

	// generalFromTriangular returns a blas64.General with the backing
	// data and dimensions of a.
	func generalFromTriangular(a blas64.Triangular) blas64.General {
	return blas64.General{
	Rows: a.N,
	Cols: a.N,
	Stride: a.Stride,
	Data: a.Data,
	}
	}

	func (v *VecDense) checkOverlap(a blas64.Vector) bool {
	mat := v.mat
	if cap(mat.Data) == 0 \|\| cap(a.Data) == 0 {
	return false
	}

	off := offset(mat.Data[:1], a.Data[:1])

	if off == 0 {
	// At least one element overlaps.
	if mat.Inc == a.Inc && len(mat.Data) == len(a.Data) {
	panic(regionIdentity)
	}
	panic(regionOverlap)
	}

	if off > 0 && len(mat.Data) <= off {
	// We know v is completely before a.
	return false
	}
	if off < 0 && len(a.Data) <= -off {
	// We know v is completely after a.
	return false
	}

	if mat.Inc != a.Inc && mat.Inc != 1 && a.Inc != 1 {
	// Too hard, so assume the worst; if either
	// increment is one it will be caught below.
	panic(mismatchedStrides)
	}
	inc := min(mat.Inc, a.Inc)

	if inc == 1 \|\| off&inc == 0 {
	panic(regionOverlap)
	}
	return false
	}

	// generalFromVector returns a blas64.General with the backing
	// data and dimensions of a.
	func generalFromVector(a blas64.Vector, r, c int) blas64.General {
	return blas64.General{
	Rows: r,
	Cols: c,
	Stride: a.Inc,
	Data: a.Data,
	}
	}

	func (s *SymBandDense) checkOverlap(a blas64.General) bool {
	return checkOverlap(generalFromSymmetricBand(s.RawSymBand()), a)
	}

	func (s *SymBandDense) checkOverlapMatrix(a Matrix) bool {
	if s == a {
	return false
	}
	var amat blas64.General
	switch ar := a.(type) {
	default:
	return false
	case RawMatrixer:
	amat = ar.RawMatrix()
	case RawSymmetricer:
	amat = generalFromSymmetric(ar.RawSymmetric())
	case RawSymBander:
	amat = generalFromSymmetricBand(ar.RawSymBand())
	case RawTriangular:
	amat = generalFromTriangular(ar.RawTriangular())
	case RawVectorer:
	r, c := a.Dims()
	amat = generalFromVector(ar.RawVector(), r, c)
	}
	return s.checkOverlap(amat)
	}

	// generalFromSymmetricBand returns a blas64.General with the backing
	// data and dimensions of a.
	func generalFromSymmetricBand(a blas64.SymmetricBand) blas64.General {
	return blas64.General{
	Rows: a.N,
	Cols: a.K + 1,
	Data: a.Data,
	Stride: a.Stride,
	}
	}