+++ /dev/null
-// 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.
-
-//+build !noasm,!appengine
-
-package f64
-
-// L1Norm is
-// for _, v := range x {
-// sum += math.Abs(v)
-// }
-// return sum
-func L1Norm(x []float64) (sum float64)
-
-// L1NormInc is
-// for i := 0; i < n*incX; i += incX {
-// sum += math.Abs(x[i])
-// }
-// return sum
-func L1NormInc(x []float64, n, incX int) (sum float64)
-
-// AddConst is
-// for i := range x {
-// x[i] += alpha
-// }
-func AddConst(alpha float64, x []float64)
-
-// Add is
-// for i, v := range s {
-// dst[i] += v
-// }
-func Add(dst, s []float64)
-
-// AxpyUnitary is
-// for i, v := range x {
-// y[i] += alpha * v
-// }
-func AxpyUnitary(alpha float64, x, y []float64)
-
-// AxpyUnitaryTo is
-// for i, v := range x {
-// dst[i] = alpha*v + y[i]
-// }
-func AxpyUnitaryTo(dst []float64, alpha float64, x, y []float64)
-
-// AxpyInc is
-// for i := 0; i < int(n); i++ {
-// y[iy] += alpha * x[ix]
-// ix += incX
-// iy += incY
-// }
-func AxpyInc(alpha float64, x, y []float64, n, incX, incY, ix, iy uintptr)
-
-// AxpyIncTo is
-// for i := 0; i < int(n); i++ {
-// dst[idst] = alpha*x[ix] + y[iy]
-// ix += incX
-// iy += incY
-// idst += incDst
-// }
-func AxpyIncTo(dst []float64, incDst, idst uintptr, alpha float64, x, y []float64, n, incX, incY, ix, iy uintptr)
-
-// CumSum is
-// if len(s) == 0 {
-// return dst
-// }
-// dst[0] = s[0]
-// for i, v := range s[1:] {
-// dst[i+1] = dst[i] + v
-// }
-// return dst
-func CumSum(dst, s []float64) []float64
-
-// CumProd is
-// if len(s) == 0 {
-// return dst
-// }
-// dst[0] = s[0]
-// for i, v := range s[1:] {
-// dst[i+1] = dst[i] * v
-// }
-// return dst
-func CumProd(dst, s []float64) []float64
-
-// Div is
-// for i, v := range s {
-// dst[i] /= v
-// }
-func Div(dst, s []float64)
-
-// DivTo is
-// for i, v := range s {
-// dst[i] = v / t[i]
-// }
-// return dst
-func DivTo(dst, x, y []float64) []float64
-
-// DotUnitary is
-// for i, v := range x {
-// sum += y[i] * v
-// }
-// return sum
-func DotUnitary(x, y []float64) (sum float64)
-
-// DotInc is
-// for i := 0; i < int(n); i++ {
-// sum += y[iy] * x[ix]
-// ix += incX
-// iy += incY
-// }
-// return sum
-func DotInc(x, y []float64, n, incX, incY, ix, iy uintptr) (sum float64)
-
-// L1Dist is
-// var norm float64
-// for i, v := range s {
-// norm += math.Abs(t[i] - v)
-// }
-// return norm
-func L1Dist(s, t []float64) float64
-
-// LinfDist is
-// var norm float64
-// if len(s) == 0 {
-// return 0
-// }
-// norm = math.Abs(t[0] - s[0])
-// for i, v := range s[1:] {
-// absDiff := math.Abs(t[i+1] - v)
-// if absDiff > norm || math.IsNaN(norm) {
-// norm = absDiff
-// }
-// }
-// return norm
-func LinfDist(s, t []float64) float64
-
-// ScalUnitary is
-// for i := range x {
-// x[i] *= alpha
-// }
-func ScalUnitary(alpha float64, x []float64)
-
-// ScalUnitaryTo is
-// for i, v := range x {
-// dst[i] = alpha * v
-// }
-func ScalUnitaryTo(dst []float64, alpha float64, x []float64)
-
-// ScalInc is
-// var ix uintptr
-// for i := 0; i < int(n); i++ {
-// x[ix] *= alpha
-// ix += incX
-// }
-func ScalInc(alpha float64, x []float64, n, incX uintptr)
-
-// ScalIncTo is
-// var idst, ix uintptr
-// for i := 0; i < int(n); i++ {
-// dst[idst] = alpha * x[ix]
-// ix += incX
-// idst += incDst
-// }
-func ScalIncTo(dst []float64, incDst uintptr, alpha float64, x []float64, n, incX uintptr)