resize/filters.go

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/*
Copyright (c) 2012, Jan Schlicht <jan.schlicht@gmail.com>
Permission to use, copy, modify, and/or distribute this software for any purpose
with or without fee is hereby granted, provided that the above copyright notice
and this permission notice appear in all copies.
THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH
REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND
FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT,
INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS
OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF
THIS SOFTWARE.
*/
package resize
import (
"image"
"image/color"
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"math"
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)
// restrict an input float32 to the
// range of uint16 values
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func clampToUint16(x float32) (y uint16) {
y = uint16(x)
if x < 0 {
y = 0
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} else if x > float32(0xfffe) {
// "else if x > float32(0xffff)" will cause overflows!
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y = 0xffff
}
return
}
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type filterModel struct {
converter
factor [2]float32
kernel func(float32) float32
tempRow, tempCol []colorArray
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}
func (f *filterModel) convolution1d(x float32, p []colorArray, isRow bool) colorArray {
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var k float32
var sum float32 = 0
c := colorArray{0.0, 0.0, 0.0, 0.0}
var index uint
if isRow {
index = 0
} else {
index = 1
}
for j := range p {
k = f.kernel((x - float32(j)) / f.factor[index])
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sum += k
for i := range c {
c[i] += p[j][i] * k
}
}
// normalize values
for i := range c {
c[i] = c[i] / sum
}
return c
}
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func (f *filterModel) Interpolate(x, y float32) color.RGBA64 {
xf, yf := int(x)-len(f.tempRow)/2+1, int(y)-len(f.tempCol)/2+1
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x -= float32(xf)
y -= float32(yf)
for i := 0; i < len(f.tempCol); i++ {
for j := 0; j < len(f.tempRow); j++ {
f.tempRow[j] = f.at(xf+j, yf+i)
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}
f.tempCol[i] = f.convolution1d(x, f.tempRow, true)
}
c := f.convolution1d(y, f.tempCol, false)
return color.RGBA64{
clampToUint16(c[0]),
clampToUint16(c[1]),
clampToUint16(c[2]),
clampToUint16(c[3]),
}
}
// createFilter tries to find an optimized converter for the given input image
// and initializes all filterModel members to their defaults
func createFilter(img image.Image, factor [2]float32, size int, kernel func(float32) float32) (f Filter) {
sizeX := size * (int(math.Ceil(float64(factor[0]))))
sizeY := size * (int(math.Ceil(float64(factor[1]))))
switch img.(type) {
default:
f = &filterModel{
&genericConverter{img},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
case *image.RGBA:
f = &filterModel{
&rgbaConverter{img.(*image.RGBA)},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
case *image.RGBA64:
f = &filterModel{
&rgba64Converter{img.(*image.RGBA64)},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
case *image.Gray:
f = &filterModel{
&grayConverter{img.(*image.Gray)},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
case *image.Gray16:
f = &filterModel{
&gray16Converter{img.(*image.Gray16)},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
case *image.YCbCr:
f = &filterModel{
&ycbcrConverter{img.(*image.YCbCr)},
factor, kernel,
make([]colorArray, sizeX), make([]colorArray, sizeY),
}
}
return
}
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// Nearest-neighbor interpolation
func NearestNeighbor(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 2, func(x float32) (y float32) {
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if x >= -0.5 && x < 0.5 {
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y = 1
} else {
y = 0
}
return
})
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}
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// Bilinear interpolation
func Bilinear(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 2, func(x float32) (y float32) {
absX := float32(math.Abs(float64(x)))
if absX <= 1 {
y = 1 - absX
} else {
y = 0
}
return
})
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}
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// Bicubic interpolation (with cubic hermite spline)
func Bicubic(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 4, func(x float32) (y float32) {
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absX := float32(math.Abs(float64(x)))
if absX <= 1 {
y = absX*absX*(1.5*absX-2.5) + 1
} else if absX <= 2 {
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y = absX*(absX*(2.5-0.5*absX)-4) + 2
} else {
y = 0
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}
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return
})
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}
// Mitchell-Netravali interpolation
func MitchellNetravali(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 4, func(x float32) (y float32) {
absX := float32(math.Abs(float64(x)))
if absX <= 1 {
y = absX*absX*(7*absX-12) + 16.0/3
} else if absX <= 2 {
y = -(absX - 2) * (absX - 2) / 3 * (7*absX - 8)
} else {
y = 0
}
return
})
}
func lanczosKernel(a uint) func(float32) float32 {
return func(x float32) (y float32) {
if x > -float32(a) && x < float32(a) {
y = float32(Sinc(float64(x))) * float32(Sinc(float64(x/float32(a))))
} else {
y = 0
}
return
}
}
// Lanczos interpolation (a=2)
func Lanczos2(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 4, lanczosKernel(2))
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}
// Lanczos interpolation (a=3)
func Lanczos3(img image.Image, factor [2]float32) Filter {
return createFilter(img, factor, 6, lanczosKernel(3))
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}