go-resize/resize_test.go

package resize

import (
	"image"
	"image/color"
	"runtime"
	"testing"
)

var img = image.NewGray16(image.Rect(0, 0, 3, 3))

func init() {
	runtime.GOMAXPROCS(runtime.NumCPU())
	img.Set(1, 1, color.White)
}

func Test_Param1(t *testing.T) {
	m := Resize(0, 0, img, NearestNeighbor)
	if m.Bounds() != img.Bounds() {
		t.Fail()
	}
}

func Test_Param2(t *testing.T) {
	m := Resize(100, 0, img, NearestNeighbor)
	if m.Bounds() != image.Rect(0, 0, 100, 100) {
		t.Fail()
	}
}

func Test_ZeroImg(t *testing.T) {
	zeroImg := image.NewGray16(image.Rect(0, 0, 0, 0))

	m := Resize(0, 0, zeroImg, NearestNeighbor)
	if m.Bounds() != zeroImg.Bounds() {
		t.Fail()
	}
}

func Test_CorrectResize(t *testing.T) {
	zeroImg := image.NewGray16(image.Rect(0, 0, 256, 256))

	m := Resize(60, 0, zeroImg, NearestNeighbor)
	if m.Bounds() != image.Rect(0, 0, 60, 60) {
		t.Fail()
	}
}

func Test_SameColor(t *testing.T) {
	img := image.NewRGBA(image.Rect(0, 0, 20, 20))
	for y := img.Bounds().Min.Y; y < img.Bounds().Max.Y; y++ {
		for x := img.Bounds().Min.X; x < img.Bounds().Max.X; x++ {
			img.SetRGBA(x, y, color.RGBA{0x80, 0x80, 0x80, 0xFF})
		}
	}
	out := Resize(10, 10, img, Lanczos3)
	for y := out.Bounds().Min.Y; y < out.Bounds().Max.Y; y++ {
		for x := out.Bounds().Min.X; x < out.Bounds().Max.X; x++ {
			color := img.At(x, y).(color.RGBA)
			if color.R != 0x80 || color.G != 0x80 || color.B != 0x80 || color.A != 0xFF {
				t.Fail()
			}
		}
	}
}

func Test_Bounds(t *testing.T) {
	img := image.NewRGBA(image.Rect(20, 10, 200, 99))
	out := Resize(80, 80, img, Lanczos2)
	out.At(0, 0)
}

func Test_SameSizeReturnsOriginal(t *testing.T) {
	img := image.NewRGBA(image.Rect(0, 0, 10, 10))
	out := Resize(0, 0, img, Lanczos2)

	if img != out {
		t.Fail()
	}

	out = Resize(10, 10, img, Lanczos2)

	if img != out {
		t.Fail()
	}
}

const (
	// Use a small image size for benchmarks. We don't want memory performance
	// to affect the benchmark results.
	benchMaxX = 250
	benchMaxY = 250

	// Resize values near the original size require increase the amount of time
	// resize spends converting the image.
	benchWidth  = 200
	benchHeight = 200
)

func benchRGBA(b *testing.B, interp InterpolationFunction) {
	m := image.NewRGBA(image.Rect(0, 0, benchMaxX, benchMaxY))
	// Initialize m's pixels to create a non-uniform image.
	for y := m.Rect.Min.Y; y < m.Rect.Max.Y; y++ {
		for x := m.Rect.Min.X; x < m.Rect.Max.X; x++ {
			i := m.PixOffset(x, y)
			m.Pix[i+0] = uint8(y + 4*x)
			m.Pix[i+1] = uint8(y + 4*x)
			m.Pix[i+2] = uint8(y + 4*x)
			m.Pix[i+3] = uint8(4*y + x)
		}
	}

	var out image.Image
	b.ResetTimer()
	for i := 0; i < b.N; i++ {
		out = Resize(benchWidth, benchHeight, m, interp)
	}
	out.At(0, 0)
}

// The names of some interpolation functions are truncated so that the columns
// of 'go test -bench' line up.
func Benchmark_Nearest_RGBA(b *testing.B) {
	benchRGBA(b, NearestNeighbor)
}

func Benchmark_Bilinear_RGBA(b *testing.B) {
	benchRGBA(b, Bilinear)
}

func Benchmark_Bicubic_RGBA(b *testing.B) {
	benchRGBA(b, Bicubic)
}

func Benchmark_Mitchell_RGBA(b *testing.B) {
	benchRGBA(b, MitchellNetravali)
}

func Benchmark_Lanczos2_RGBA(b *testing.B) {
	benchRGBA(b, Lanczos2)
}

func Benchmark_Lanczos3_RGBA(b *testing.B) {
	benchRGBA(b, Lanczos3)
}

func benchYCbCr(b *testing.B, interp InterpolationFunction) {
	m := image.NewYCbCr(image.Rect(0, 0, benchMaxX, benchMaxY), image.YCbCrSubsampleRatio422)
	// Initialize m's pixels to create a non-uniform image.
	for y := m.Rect.Min.Y; y < m.Rect.Max.Y; y++ {
		for x := m.Rect.Min.X; x < m.Rect.Max.X; x++ {
			yi := m.YOffset(x, y)
			ci := m.COffset(x, y)
			m.Y[yi] = uint8(16*y + x)
			m.Cb[ci] = uint8(y + 16*x)
			m.Cr[ci] = uint8(y + 16*x)
		}
	}
	var out image.Image
	b.ResetTimer()
	for i := 0; i < b.N; i++ {
		out = Resize(benchWidth, benchHeight, m, interp)
	}
	out.At(0, 0)
}

func Benchmark_Nearest_YCC(b *testing.B) {
	benchYCbCr(b, NearestNeighbor)
}

func Benchmark_Bilinear_YCC(b *testing.B) {
	benchYCbCr(b, Bilinear)
}

func Benchmark_Bicubic_YCC(b *testing.B) {
	benchYCbCr(b, Bicubic)
}

func Benchmark_Mitchell_YCC(b *testing.B) {
	benchYCbCr(b, MitchellNetravali)
}

func Benchmark_Lanczos2_YCC(b *testing.B) {
	benchYCbCr(b, Lanczos2)
}

func Benchmark_Lanczos3_YCC(b *testing.B) {
	benchYCbCr(b, Lanczos3)
}
initial commit 2012-08-02 21:59:40 +02:00			`package resize`

			`import (`
			`"image"`
			`"image/color"`
Remove unnecessary benchmark 2014-09-15 11:58:05 +02:00			`"runtime"`
initial commit 2012-08-02 21:59:40 +02:00			`"testing"`
			`)`

Tests added 2012-08-03 18:12:26 +02:00			`var img = image.NewGray16(image.Rect(0, 0, 3, 3))`

Speed up calculation by avoiding dynamic casting 2012-09-01 00:21:10 +02:00			`func init() {`
Remove unnecessary benchmark 2014-09-15 11:58:05 +02:00			`runtime.GOMAXPROCS(runtime.NumCPU())`
Tests added 2012-08-03 18:12:26 +02:00			`img.Set(1, 1, color.White)`
Speed up calculation by avoiding dynamic casting 2012-09-01 00:21:10 +02:00			`}`
Tests added 2012-08-03 18:12:26 +02:00
			`func Test_Param1(t *testing.T) {`
Function signature changed again, no need for multiple return value 2012-08-09 18:56:42 +02:00			`m := Resize(0, 0, img, NearestNeighbor)`
			`if m.Bounds() != img.Bounds() {`
Tests added 2012-08-03 18:12:26 +02:00			`t.Fail()`
			`}`
			`}`

			`func Test_Param2(t *testing.T) {`
Function signature changed again, no need for multiple return value 2012-08-09 18:56:42 +02:00			`m := Resize(100, 0, img, NearestNeighbor)`
			`if m.Bounds() != image.Rect(0, 0, 100, 100) {`
Tests added 2012-08-03 18:12:26 +02:00			`t.Fail()`
			`}`
			`}`

			`func Test_ZeroImg(t *testing.T) {`
			`zeroImg := image.NewGray16(image.Rect(0, 0, 0, 0))`

Function signature changed again, no need for multiple return value 2012-08-09 18:56:42 +02:00			`m := Resize(0, 0, zeroImg, NearestNeighbor)`
			`if m.Bounds() != zeroImg.Bounds() {`
initial commit 2012-08-02 21:59:40 +02:00			`t.Fail()`
			`}`
			`}`
Speed up calculation by avoiding dynamic casting 2012-09-01 00:21:10 +02:00
Test for correct canvas size. 2013-03-10 10:58:08 +01:00			`func Test_CorrectResize(t *testing.T) {`
go fmt 2013-03-10 11:55:50 +01:00			`zeroImg := image.NewGray16(image.Rect(0, 0, 256, 256))`
Test for correct canvas size. 2013-03-10 10:58:08 +01:00
			`m := Resize(60, 0, zeroImg, NearestNeighbor)`
go fmt 2013-03-10 11:55:50 +01:00			`if m.Bounds() != image.Rect(0, 0, 60, 60) {`
Test for correct canvas size. 2013-03-10 10:58:08 +01:00			`t.Fail()`
			`}`
			`}`

Optimize data-locality for a huge increase in processing speed. This is a complete rewrite! The tight scaling loop needs data locality for optimal performance. The old version used lots of pointer redirections to access image data which was bad for data locality. By providing the complete loop for each image type, this problem is solved. Unfortunately this increases code duplication but the result should be worth it: I could measure a ~6x speed-up for certain test cases! 2014-07-19 13:19:31 +02:00			`func Test_SameColor(t *testing.T) {`
			`img := image.NewRGBA(image.Rect(0, 0, 20, 20))`
			`for y := img.Bounds().Min.Y; y < img.Bounds().Max.Y; y++ {`
			`for x := img.Bounds().Min.X; x < img.Bounds().Max.X; x++ {`
			`img.SetRGBA(x, y, color.RGBA{0x80, 0x80, 0x80, 0xFF})`
			`}`
			`}`
			`out := Resize(10, 10, img, Lanczos3)`
			`for y := out.Bounds().Min.Y; y < out.Bounds().Max.Y; y++ {`
			`for x := out.Bounds().Min.X; x < out.Bounds().Max.X; x++ {`
			`color := img.At(x, y).(color.RGBA)`
			`if color.R != 0x80 \|\| color.G != 0x80 \|\| color.B != 0x80 \|\| color.A != 0xFF {`
			`t.Fail()`
			`}`
			`}`
			`}`
			`}`

Add simple test case for input image with non-trivial bounds. 2014-08-13 20:12:18 +02:00			`func Test_Bounds(t *testing.T) {`
			`img := image.NewRGBA(image.Rect(20, 10, 200, 99))`
			`out := Resize(80, 80, img, Lanczos2)`
			`out.At(0, 0)`
			`}`

Return input image if output dimensions equal input dimensions. 2014-12-17 11:10:53 +01:00			`func Test_SameSizeReturnsOriginal(t *testing.T) {`
			`img := image.NewRGBA(image.Rect(0, 0, 10, 10))`
			`out := Resize(0, 0, img, Lanczos2)`

			`if img != out {`
			`t.Fail()`
			`}`

			`out = Resize(10, 10, img, Lanczos2)`

			`if img != out {`
			`t.Fail()`
			`}`
			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`const (`
			`// Use a small image size for benchmarks. We don't want memory performance`
			`// to affect the benchmark results.`
			`benchMaxX = 250`
			`benchMaxY = 250`

			`// Resize values near the original size require increase the amount of time`
			`// resize spends converting the image.`
			`benchWidth = 200`
			`benchHeight = 200`
			`)`

			`func benchRGBA(b *testing.B, interp InterpolationFunction) {`
			`m := image.NewRGBA(image.Rect(0, 0, benchMaxX, benchMaxY))`
			`// Initialize m's pixels to create a non-uniform image.`
			`for y := m.Rect.Min.Y; y < m.Rect.Max.Y; y++ {`
			`for x := m.Rect.Min.X; x < m.Rect.Max.X; x++ {`
			`i := m.PixOffset(x, y)`
			`m.Pix[i+0] = uint8(y + 4*x)`
			`m.Pix[i+1] = uint8(y + 4*x)`
			`m.Pix[i+2] = uint8(y + 4*x)`
			`m.Pix[i+3] = uint8(4*y + x)`
			`}`
			`}`

			`var out image.Image`
			`b.ResetTimer()`
Added MitchellNetravali, changed Lanczos a bit 2012-09-19 19:32:00 +02:00			`for i := 0; i < b.N; i++ {`
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`out = Resize(benchWidth, benchHeight, m, interp)`
Added MitchellNetravali, changed Lanczos a bit 2012-09-19 19:32:00 +02:00			`}`
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`out.At(0, 0)`
Speed up calculation by avoiding dynamic casting 2012-09-01 00:21:10 +02:00			`}`
Blur input image during downscaling by scaling the filter kernel to prevent moires in the output image 2012-09-19 21:03:56 +02:00
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`// The names of some interpolation functions are truncated so that the columns`
			`// of 'go test -bench' line up.`
			`func Benchmark_Nearest_RGBA(b *testing.B) {`
			`benchRGBA(b, NearestNeighbor)`
			`}`
Blur input image during downscaling by scaling the filter kernel to prevent moires in the output image 2012-09-19 21:03:56 +02:00
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Bilinear_RGBA(b *testing.B) {`
			`benchRGBA(b, Bilinear)`
			`}`

			`func Benchmark_Bicubic_RGBA(b *testing.B) {`
			`benchRGBA(b, Bicubic)`
			`}`

			`func Benchmark_Mitchell_RGBA(b *testing.B) {`
			`benchRGBA(b, MitchellNetravali)`
			`}`

			`func Benchmark_Lanczos2_RGBA(b *testing.B) {`
			`benchRGBA(b, Lanczos2)`
Blur input image during downscaling by scaling the filter kernel to prevent moires in the output image 2012-09-19 21:03:56 +02:00			`}`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Lanczos3_RGBA(b *testing.B) {`
			`benchRGBA(b, Lanczos3)`
			`}`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func benchYCbCr(b *testing.B, interp InterpolationFunction) {`
			`m := image.NewYCbCr(image.Rect(0, 0, benchMaxX, benchMaxY), image.YCbCrSubsampleRatio422)`
			`// Initialize m's pixels to create a non-uniform image.`
			`for y := m.Rect.Min.Y; y < m.Rect.Max.Y; y++ {`
			`for x := m.Rect.Min.X; x < m.Rect.Max.X; x++ {`
			`yi := m.YOffset(x, y)`
			`ci := m.COffset(x, y)`
			`m.Y[yi] = uint8(16*y + x)`
			`m.Cb[ci] = uint8(y + 16*x)`
			`m.Cr[ci] = uint8(y + 16*x)`
			`}`
			`}`
			`var out image.Image`
			`b.ResetTimer()`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`for i := 0; i < b.N; i++ {`
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`out = Resize(benchWidth, benchHeight, m, interp)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`
Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`out.At(0, 0)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Nearest_YCC(b *testing.B) {`
			`benchYCbCr(b, NearestNeighbor)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Bilinear_YCC(b *testing.B) {`
			`benchYCbCr(b, Bilinear)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Bicubic_YCC(b *testing.B) {`
			`benchYCbCr(b, Bicubic)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Mitchell_YCC(b *testing.B) {`
			`benchYCbCr(b, MitchellNetravali)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Lanczos2_YCC(b *testing.B) {`
			`benchYCbCr(b, Lanczos2)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`

Update benchmarks to focus on conversion performance. Benchmark each interpolation function for RGBA and YCbCr images. Reduce the image size used when benchmarking to reduce the influence of memory performance on results. 2015-03-15 22:40:38 +01:00			`func Benchmark_Lanczos3_YCC(b *testing.B) {`
			`benchYCbCr(b, Lanczos3)`
Add benchmarks to compare execution times. Run "go test -bench LargeJpegThumb" to benchmark all functions at once. 2014-01-18 11:55:34 +01:00			`}`