src/image/draw/draw_test.go - go - Git at Google

 // Copyright 2010 The Go 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 draw

 import (
 	"image"
 	"image/color"
 	"image/png"
 	"os"
 	"testing"
 	"testing/quick"
 )

 func eq(c0, c1 color.Color) bool {
 	r0, g0, b0, a0 := c0.RGBA()
 	r1, g1, b1, a1 := c1.RGBA()
 	return r0 == r1 && g0 == g1 && b0 == b1 && a0 == a1
 }

 func fillBlue(alpha int) image.Image {
 	return image.NewUniform(color.RGBA{0, 0, uint8(alpha), uint8(alpha)})
 }

 func fillAlpha(alpha int) image.Image {
 	return image.NewUniform(color.Alpha{uint8(alpha)})
 }

 func vgradGreen(alpha int) image.Image {
 	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.RGBA{0, uint8(y * alpha / 15), 0, uint8(alpha)})
 		}
 	}
 	return m
 }

 func vgradAlpha(alpha int) image.Image {
 	m := image.NewAlpha(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.Alpha{uint8(y * alpha / 15)})
 		}
 	}
 	return m
 }

 func vgradGreenNRGBA(alpha int) image.Image {
 	m := image.NewNRGBA(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.RGBA{0, uint8(y * 0x11), 0, uint8(alpha)})
 		}
 	}
 	return m
 }

 func vgradCr() image.Image {
 	m := &image.YCbCr{
 		Y:              make([]byte, 16*16),
 		Cb:             make([]byte, 16*16),
 		Cr:             make([]byte, 16*16),
 		YStride:        16,
 		CStride:        16,
 		SubsampleRatio: image.YCbCrSubsampleRatio444,
 		Rect:           image.Rect(0, 0, 16, 16),
 	}
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Cr[y*m.CStride+x] = uint8(y * 0x11)
 		}
 	}
 	return m
 }

 func vgradGray() image.Image {
 	m := image.NewGray(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.Gray{uint8(y * 0x11)})
 		}
 	}
 	return m
 }

 func vgradMagenta() image.Image {
 	m := image.NewCMYK(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.CMYK{0, uint8(y * 0x11), 0, 0x3f})
 		}
 	}
 	return m
 }

 func hgradRed(alpha int) Image {
 	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.RGBA{uint8(x * alpha / 15), 0, 0, uint8(alpha)})
 		}
 	}
 	return m
 }

 func gradYellow(alpha int) Image {
 	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
 	for y := 0; y < 16; y++ {
 		for x := 0; x < 16; x++ {
 			m.Set(x, y, color.RGBA{uint8(x * alpha / 15), uint8(y * alpha / 15), 0, uint8(alpha)})
 		}
 	}
 	return m
 }

 type drawTest struct {
 	desc     string
 	src      image.Image
 	mask     image.Image
 	op       Op
 	expected color.Color
 }

 var drawTests = []drawTest{
 	// Uniform mask (0% opaque).
 	{"nop", vgradGreen(255), fillAlpha(0), Over, color.RGBA{136, 0, 0, 255}},
 	{"clear", vgradGreen(255), fillAlpha(0), Src, color.RGBA{0, 0, 0, 0}},
 	// Uniform mask (100%, 75%, nil) and uniform source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 0, 90, 90}.
 	{"fill", fillBlue(90), fillAlpha(255), Over, color.RGBA{88, 0, 90, 255}},
 	{"fillSrc", fillBlue(90), fillAlpha(255), Src, color.RGBA{0, 0, 90, 90}},
 	{"fillAlpha", fillBlue(90), fillAlpha(192), Over, color.RGBA{100, 0, 68, 255}},
 	{"fillAlphaSrc", fillBlue(90), fillAlpha(192), Src, color.RGBA{0, 0, 68, 68}},
 	{"fillNil", fillBlue(90), nil, Over, color.RGBA{88, 0, 90, 255}},
 	{"fillNilSrc", fillBlue(90), nil, Src, color.RGBA{0, 0, 90, 90}},
 	// Uniform mask (100%, 75%, nil) and variable source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 48, 0, 90}.
 	{"copy", vgradGreen(90), fillAlpha(255), Over, color.RGBA{88, 48, 0, 255}},
 	{"copySrc", vgradGreen(90), fillAlpha(255), Src, color.RGBA{0, 48, 0, 90}},
 	{"copyAlpha", vgradGreen(90), fillAlpha(192), Over, color.RGBA{100, 36, 0, 255}},
 	{"copyAlphaSrc", vgradGreen(90), fillAlpha(192), Src, color.RGBA{0, 36, 0, 68}},
 	{"copyNil", vgradGreen(90), nil, Over, color.RGBA{88, 48, 0, 255}},
 	{"copyNilSrc", vgradGreen(90), nil, Src, color.RGBA{0, 48, 0, 90}},
 	// Uniform mask (100%, 75%, nil) and variable NRGBA source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 136, 0, 90} in NRGBA-space, which is {0, 48, 0, 90} in RGBA-space.
 	// The result pixel is different than in the "copy*" test cases because of rounding errors.
 	{"nrgba", vgradGreenNRGBA(90), fillAlpha(255), Over, color.RGBA{88, 46, 0, 255}},
 	{"nrgbaSrc", vgradGreenNRGBA(90), fillAlpha(255), Src, color.RGBA{0, 46, 0, 90}},
 	{"nrgbaAlpha", vgradGreenNRGBA(90), fillAlpha(192), Over, color.RGBA{100, 34, 0, 255}},
 	{"nrgbaAlphaSrc", vgradGreenNRGBA(90), fillAlpha(192), Src, color.RGBA{0, 34, 0, 68}},
 	{"nrgbaNil", vgradGreenNRGBA(90), nil, Over, color.RGBA{88, 46, 0, 255}},
 	{"nrgbaNilSrc", vgradGreenNRGBA(90), nil, Src, color.RGBA{0, 46, 0, 90}},
 	// Uniform mask (100%, 75%, nil) and variable YCbCr source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 0, 136} in YCbCr-space, which is {11, 38, 0, 255} in RGB-space.
 	{"ycbcr", vgradCr(), fillAlpha(255), Over, color.RGBA{11, 38, 0, 255}},
 	{"ycbcrSrc", vgradCr(), fillAlpha(255), Src, color.RGBA{11, 38, 0, 255}},
 	{"ycbcrAlpha", vgradCr(), fillAlpha(192), Over, color.RGBA{42, 28, 0, 255}},
 	{"ycbcrAlphaSrc", vgradCr(), fillAlpha(192), Src, color.RGBA{8, 28, 0, 192}},
 	{"ycbcrNil", vgradCr(), nil, Over, color.RGBA{11, 38, 0, 255}},
 	{"ycbcrNilSrc", vgradCr(), nil, Src, color.RGBA{11, 38, 0, 255}},
 	// Uniform mask (100%, 75%, nil) and variable Gray source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {136} in Gray-space, which is {136, 136, 136, 255} in RGBA-space.
 	{"gray", vgradGray(), fillAlpha(255), Over, color.RGBA{136, 136, 136, 255}},
 	{"graySrc", vgradGray(), fillAlpha(255), Src, color.RGBA{136, 136, 136, 255}},
 	{"grayAlpha", vgradGray(), fillAlpha(192), Over, color.RGBA{136, 102, 102, 255}},
 	{"grayAlphaSrc", vgradGray(), fillAlpha(192), Src, color.RGBA{102, 102, 102, 192}},
 	{"grayNil", vgradGray(), nil, Over, color.RGBA{136, 136, 136, 255}},
 	{"grayNilSrc", vgradGray(), nil, Src, color.RGBA{136, 136, 136, 255}},
 	// Uniform mask (100%, 75%, nil) and variable CMYK source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 136, 0, 63} in CMYK-space, which is {192, 89, 192} in RGB-space.
 	{"cmyk", vgradMagenta(), fillAlpha(255), Over, color.RGBA{192, 89, 192, 255}},
 	{"cmykSrc", vgradMagenta(), fillAlpha(255), Src, color.RGBA{192, 89, 192, 255}},
 	{"cmykAlpha", vgradMagenta(), fillAlpha(192), Over, color.RGBA{178, 67, 145, 255}},
 	{"cmykAlphaSrc", vgradMagenta(), fillAlpha(192), Src, color.RGBA{145, 67, 145, 192}},
 	{"cmykNil", vgradMagenta(), nil, Over, color.RGBA{192, 89, 192, 255}},
 	{"cmykNilSrc", vgradMagenta(), nil, Src, color.RGBA{192, 89, 192, 255}},
 	// Variable mask and variable source.
 	// At (x, y) == (8, 8):
 	// The destination pixel is {136, 0, 0, 255}.
 	// The source pixel is {0, 0, 255, 255}.
 	// The mask pixel's alpha is 102, or 40%.
 	{"generic", fillBlue(255), vgradAlpha(192), Over, color.RGBA{81, 0, 102, 255}},
 	{"genericSrc", fillBlue(255), vgradAlpha(192), Src, color.RGBA{0, 0, 102, 102}},
 }

 func makeGolden(dst image.Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, op Op) image.Image {
 	// Since golden is a newly allocated image, we don't have to check if the
 	// input source and mask images and the output golden image overlap.
 	b := dst.Bounds()
 	sb := src.Bounds()
 	mb := image.Rect(-1e9, -1e9, 1e9, 1e9)
 	if mask != nil {
 		mb = mask.Bounds()
 	}
 	golden := image.NewRGBA(image.Rect(0, 0, b.Max.X, b.Max.Y))
 	for y := r.Min.Y; y < r.Max.Y; y++ {
 		sy := y + sp.Y - r.Min.Y
 		my := y + mp.Y - r.Min.Y
 		for x := r.Min.X; x < r.Max.X; x++ {
 			if !(image.Pt(x, y).In(b)) {
 				continue
 			}
 			sx := x + sp.X - r.Min.X
 			if !(image.Pt(sx, sy).In(sb)) {
 				continue
 			}
 			mx := x + mp.X - r.Min.X
 			if !(image.Pt(mx, my).In(mb)) {
 				continue
 			}

 			const M = 1<<16 - 1
 			var dr, dg, db, da uint32
 			if op == Over {
 				dr, dg, db, da = dst.At(x, y).RGBA()
 			}
 			sr, sg, sb, sa := src.At(sx, sy).RGBA()
 			ma := uint32(M)
 			if mask != nil {
 				_, _, _, ma = mask.At(mx, my).RGBA()
 			}
 			a := M - (sa * ma / M)
 			golden.Set(x, y, color.RGBA64{
 				uint16((dr*a + sr*ma) / M),
 				uint16((dg*a + sg*ma) / M),
 				uint16((db*a + sb*ma) / M),
 				uint16((da*a + sa*ma) / M),
 			})
 		}
 	}
 	return golden.SubImage(b)
 }

 func TestDraw(t *testing.T) {
 	rr := []image.Rectangle{
 		image.Rect(0, 0, 0, 0),
 		image.Rect(0, 0, 16, 16),
 		image.Rect(3, 5, 12, 10),
 		image.Rect(0, 0, 9, 9),
 		image.Rect(8, 8, 16, 16),
 		image.Rect(8, 0, 9, 16),
 		image.Rect(0, 8, 16, 9),
 		image.Rect(8, 8, 9, 9),
 		image.Rect(8, 8, 8, 8),
 	}
 	for _, r := range rr {
 	loop:
 		for _, test := range drawTests {
 			dst := hgradRed(255).(*image.RGBA).SubImage(r).(Image)
 			// Draw the (src, mask, op) onto a copy of dst using a slow but obviously correct implementation.
 			golden := makeGolden(dst, image.Rect(0, 0, 16, 16), test.src, image.ZP, test.mask, image.ZP, test.op)
 			b := dst.Bounds()
 			if !b.Eq(golden.Bounds()) {
 				t.Errorf("draw %v %s: bounds %v versus %v", r, test.desc, dst.Bounds(), golden.Bounds())
 				continue
 			}
 			// Draw the same combination onto the actual dst using the optimized DrawMask implementation.
 			DrawMask(dst, image.Rect(0, 0, 16, 16), test.src, image.ZP, test.mask, image.ZP, test.op)
 			if image.Pt(8, 8).In(r) {
 				// Check that the resultant pixel at (8, 8) matches what we expect
 				// (the expected value can be verified by hand).
 				if !eq(dst.At(8, 8), test.expected) {
 					t.Errorf("draw %v %s: at (8, 8) %v versus %v", r, test.desc, dst.At(8, 8), test.expected)
 					continue
 				}
 			}
 			// Check that the resultant dst image matches the golden output.
 			for y := b.Min.Y; y < b.Max.Y; y++ {
 				for x := b.Min.X; x < b.Max.X; x++ {
 					if !eq(dst.At(x, y), golden.At(x, y)) {
 						t.Errorf("draw %v %s: at (%d, %d), %v versus golden %v", r, test.desc, x, y, dst.At(x, y), golden.At(x, y))
 						continue loop
 					}
 				}
 			}
 		}
 	}
 }

 func TestDrawOverlap(t *testing.T) {
 	for _, op := range []Op{Over, Src} {
 		for yoff := -2; yoff <= 2; yoff++ {
 		loop:
 			for xoff := -2; xoff <= 2; xoff++ {
 				m := gradYellow(127).(*image.RGBA)
 				dst := m.SubImage(image.Rect(5, 5, 10, 10)).(*image.RGBA)
 				src := m.SubImage(image.Rect(5+xoff, 5+yoff, 10+xoff, 10+yoff)).(*image.RGBA)
 				b := dst.Bounds()
 				// Draw the (src, mask, op) onto a copy of dst using a slow but obviously correct implementation.
 				golden := makeGolden(dst, b, src, src.Bounds().Min, nil, image.ZP, op)
 				if !b.Eq(golden.Bounds()) {
 					t.Errorf("drawOverlap xoff=%d,yoff=%d: bounds %v versus %v", xoff, yoff, dst.Bounds(), golden.Bounds())
 					continue
 				}
 				// Draw the same combination onto the actual dst using the optimized DrawMask implementation.
 				DrawMask(dst, b, src, src.Bounds().Min, nil, image.ZP, op)
 				// Check that the resultant dst image matches the golden output.
 				for y := b.Min.Y; y < b.Max.Y; y++ {
 					for x := b.Min.X; x < b.Max.X; x++ {
 						if !eq(dst.At(x, y), golden.At(x, y)) {
 							t.Errorf("drawOverlap xoff=%d,yoff=%d: at (%d, %d), %v versus golden %v", xoff, yoff, x, y, dst.At(x, y), golden.At(x, y))
 							continue loop
 						}
 					}
 				}
 			}
 		}
 	}
 }

 // TestNonZeroSrcPt checks drawing with a non-zero src point parameter.
 func TestNonZeroSrcPt(t *testing.T) {
 	a := image.NewRGBA(image.Rect(0, 0, 1, 1))
 	b := image.NewRGBA(image.Rect(0, 0, 2, 2))
 	b.Set(0, 0, color.RGBA{0, 0, 0, 5})
 	b.Set(1, 0, color.RGBA{0, 0, 5, 5})
 	b.Set(0, 1, color.RGBA{0, 5, 0, 5})
 	b.Set(1, 1, color.RGBA{5, 0, 0, 5})
 	Draw(a, image.Rect(0, 0, 1, 1), b, image.Pt(1, 1), Over)
 	if !eq(color.RGBA{5, 0, 0, 5}, a.At(0, 0)) {
 		t.Errorf("non-zero src pt: want %v got %v", color.RGBA{5, 0, 0, 5}, a.At(0, 0))
 	}
 }

 func TestFill(t *testing.T) {
 	rr := []image.Rectangle{
 		image.Rect(0, 0, 0, 0),
 		image.Rect(0, 0, 40, 30),
 		image.Rect(10, 0, 40, 30),
 		image.Rect(0, 20, 40, 30),
 		image.Rect(10, 20, 40, 30),
 		image.Rect(10, 20, 15, 25),
 		image.Rect(10, 0, 35, 30),
 		image.Rect(0, 15, 40, 16),
 		image.Rect(24, 24, 25, 25),
 		image.Rect(23, 23, 26, 26),
 		image.Rect(22, 22, 27, 27),
 		image.Rect(21, 21, 28, 28),
 		image.Rect(20, 20, 29, 29),
 	}
 	for _, r := range rr {
 		m := image.NewRGBA(image.Rect(0, 0, 40, 30)).SubImage(r).(*image.RGBA)
 		b := m.Bounds()
 		c := color.RGBA{11, 0, 0, 255}
 		src := &image.Uniform{C: c}
 		check := func(desc string) {
 			for y := b.Min.Y; y < b.Max.Y; y++ {
 				for x := b.Min.X; x < b.Max.X; x++ {
 					if !eq(c, m.At(x, y)) {
 						t.Errorf("%s fill: at (%d, %d), sub-image bounds=%v: want %v got %v", desc, x, y, r, c, m.At(x, y))
 						return
 					}
 				}
 			}
 		}
 		// Draw 1 pixel at a time.
 		for y := b.Min.Y; y < b.Max.Y; y++ {
 			for x := b.Min.X; x < b.Max.X; x++ {
 				DrawMask(m, image.Rect(x, y, x+1, y+1), src, image.ZP, nil, image.ZP, Src)
 			}
 		}
 		check("pixel")
 		// Draw 1 row at a time.
 		c = color.RGBA{0, 22, 0, 255}
 		src = &image.Uniform{C: c}
 		for y := b.Min.Y; y < b.Max.Y; y++ {
 			DrawMask(m, image.Rect(b.Min.X, y, b.Max.X, y+1), src, image.ZP, nil, image.ZP, Src)
 		}
 		check("row")
 		// Draw 1 column at a time.
 		c = color.RGBA{0, 0, 33, 255}
 		src = &image.Uniform{C: c}
 		for x := b.Min.X; x < b.Max.X; x++ {
 			DrawMask(m, image.Rect(x, b.Min.Y, x+1, b.Max.Y), src, image.ZP, nil, image.ZP, Src)
 		}
 		check("column")
 		// Draw the whole image at once.
 		c = color.RGBA{44, 55, 66, 77}
 		src = &image.Uniform{C: c}
 		DrawMask(m, b, src, image.ZP, nil, image.ZP, Src)
 		check("whole")
 	}
 }

 // TestFloydSteinbergCheckerboard tests that the result of Floyd-Steinberg
 // error diffusion of a uniform 50% gray source image with a black-and-white
 // palette is a checkerboard pattern.
 func TestFloydSteinbergCheckerboard(t *testing.T) {
 	b := image.Rect(0, 0, 640, 480)
 	// We can't represent 50% exactly, but 0x7fff / 0xffff is close enough.
 	src := &image.Uniform{color.Gray16{0x7fff}}
 	dst := image.NewPaletted(b, color.Palette{color.Black, color.White})
 	FloydSteinberg.Draw(dst, b, src, image.Point{})
 	nErr := 0
 	for y := b.Min.Y; y < b.Max.Y; y++ {
 		for x := b.Min.X; x < b.Max.X; x++ {
 			got := dst.Pix[dst.PixOffset(x, y)]
 			want := uint8(x+y) % 2
 			if got != want {
 				t.Errorf("at (%d, %d): got %d, want %d", x, y, got, want)
 				if nErr++; nErr == 10 {
 					t.Fatal("there may be more errors")
 				}
 			}
 		}
 	}
 }

 // embeddedPaletted is an Image that behaves like an *image.Paletted but whose
 // type is not *image.Paletted.
 type embeddedPaletted struct {
 	*image.Paletted
 }

 // TestPaletted tests that the drawPaletted function behaves the same
 // regardless of whether dst is an *image.Paletted.
 func TestPaletted(t *testing.T) {
 	f, err := os.Open("../testdata/video-001.png")
 	if err != nil {
 		t.Fatalf("open: %v", err)
 	}
 	defer f.Close()
 	src, err := png.Decode(f)
 	if err != nil {
 		t.Fatalf("decode: %v", err)
 	}
 	b := src.Bounds()

 	cgaPalette := color.Palette{
 		color.RGBA{0x00, 0x00, 0x00, 0xff},
 		color.RGBA{0x55, 0xff, 0xff, 0xff},
 		color.RGBA{0xff, 0x55, 0xff, 0xff},
 		color.RGBA{0xff, 0xff, 0xff, 0xff},
 	}
 	drawers := map[string]Drawer{
 		"src":             Src,
 		"floyd-steinberg": FloydSteinberg,
 	}

 loop:
 	for dName, d := range drawers {
 		dst0 := image.NewPaletted(b, cgaPalette)
 		dst1 := image.NewPaletted(b, cgaPalette)
 		d.Draw(dst0, b, src, image.Point{})
 		d.Draw(embeddedPaletted{dst1}, b, src, image.Point{})
 		for y := b.Min.Y; y < b.Max.Y; y++ {
 			for x := b.Min.X; x < b.Max.X; x++ {
 				if !eq(dst0.At(x, y), dst1.At(x, y)) {
 					t.Errorf("%s: at (%d, %d), %v versus %v",
 						dName, x, y, dst0.At(x, y), dst1.At(x, y))
 					continue loop
 				}
 			}
 		}
 	}
 }

 func TestSqDiff(t *testing.T) {
 	// This test is similar to the one from the image/color package, but
 	// sqDiff in this package accepts int32 instead of uint32, so test it
 	// for appropriate input.

 	// canonical sqDiff implementation
 	orig := func(x, y int32) uint32 {
 		var d uint32
 		if x > y {
 			d = uint32(x - y)
 		} else {
 			d = uint32(y - x)
 		}
 		return (d * d) >> 2
 	}
 	testCases := []int32{
 		0,
 		1,
 		2,
 		0x0fffd,
 		0x0fffe,
 		0x0ffff,
 		0x10000,
 		0x10001,
 		0x10002,
 		0x7ffffffd,
 		0x7ffffffe,
 		0x7fffffff,
 		-0x7ffffffd,
 		-0x7ffffffe,
 		-0x80000000,
 	}
 	for _, x := range testCases {
 		for _, y := range testCases {
 			if got, want := sqDiff(x, y), orig(x, y); got != want {
 				t.Fatalf("sqDiff(%#x, %#x): got %d, want %d", x, y, got, want)
 			}
 		}
 	}
 	if err := quick.CheckEqual(orig, sqDiff, &quick.Config{MaxCountScale: 10}); err != nil {
 		t.Fatal(err)
 	}
 }
	// Copyright 2010 The Go 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 draw

	import (
	"image"
	"image/color"
	"image/png"
	"os"
	"testing"
	"testing/quick"
	)

	func eq(c0, c1 color.Color) bool {
	r0, g0, b0, a0 := c0.RGBA()
	r1, g1, b1, a1 := c1.RGBA()
	return r0 == r1 && g0 == g1 && b0 == b1 && a0 == a1
	}

	func fillBlue(alpha int) image.Image {
	return image.NewUniform(color.RGBA{0, 0, uint8(alpha), uint8(alpha)})
	}

	func fillAlpha(alpha int) image.Image {
	return image.NewUniform(color.Alpha{uint8(alpha)})
	}

	func vgradGreen(alpha int) image.Image {
	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.RGBA{0, uint8(y * alpha / 15), 0, uint8(alpha)})
	}
	}
	return m
	}

	func vgradAlpha(alpha int) image.Image {
	m := image.NewAlpha(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.Alpha{uint8(y * alpha / 15)})
	}
	}
	return m
	}

	func vgradGreenNRGBA(alpha int) image.Image {
	m := image.NewNRGBA(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.RGBA{0, uint8(y * 0x11), 0, uint8(alpha)})
	}
	}
	return m
	}

	func vgradCr() image.Image {
	m := &image.YCbCr{
	Y: make([]byte, 16*16),
	Cb: make([]byte, 16*16),
	Cr: make([]byte, 16*16),
	YStride: 16,
	CStride: 16,
	SubsampleRatio: image.YCbCrSubsampleRatio444,
	Rect: image.Rect(0, 0, 16, 16),
	}
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Cr[ym.CStride+x] = uint8(y 0x11)
	}
	}
	return m
	}

	func vgradGray() image.Image {
	m := image.NewGray(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.Gray{uint8(y * 0x11)})
	}
	}
	return m
	}

	func vgradMagenta() image.Image {
	m := image.NewCMYK(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.CMYK{0, uint8(y * 0x11), 0, 0x3f})
	}
	}
	return m
	}

	func hgradRed(alpha int) Image {
	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.RGBA{uint8(x * alpha / 15), 0, 0, uint8(alpha)})
	}
	}
	return m
	}

	func gradYellow(alpha int) Image {
	m := image.NewRGBA(image.Rect(0, 0, 16, 16))
	for y := 0; y < 16; y++ {
	for x := 0; x < 16; x++ {
	m.Set(x, y, color.RGBA{uint8(x * alpha / 15), uint8(y * alpha / 15), 0, uint8(alpha)})
	}
	}
	return m
	}

	type drawTest struct {
	desc string
	src image.Image
	mask image.Image
	op Op
	expected color.Color
	}

	var drawTests = []drawTest{
	// Uniform mask (0% opaque).
	{"nop", vgradGreen(255), fillAlpha(0), Over, color.RGBA{136, 0, 0, 255}},
	{"clear", vgradGreen(255), fillAlpha(0), Src, color.RGBA{0, 0, 0, 0}},
	// Uniform mask (100%, 75%, nil) and uniform source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 0, 90, 90}.
	{"fill", fillBlue(90), fillAlpha(255), Over, color.RGBA{88, 0, 90, 255}},
	{"fillSrc", fillBlue(90), fillAlpha(255), Src, color.RGBA{0, 0, 90, 90}},
	{"fillAlpha", fillBlue(90), fillAlpha(192), Over, color.RGBA{100, 0, 68, 255}},
	{"fillAlphaSrc", fillBlue(90), fillAlpha(192), Src, color.RGBA{0, 0, 68, 68}},
	{"fillNil", fillBlue(90), nil, Over, color.RGBA{88, 0, 90, 255}},
	{"fillNilSrc", fillBlue(90), nil, Src, color.RGBA{0, 0, 90, 90}},
	// Uniform mask (100%, 75%, nil) and variable source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 48, 0, 90}.
	{"copy", vgradGreen(90), fillAlpha(255), Over, color.RGBA{88, 48, 0, 255}},
	{"copySrc", vgradGreen(90), fillAlpha(255), Src, color.RGBA{0, 48, 0, 90}},
	{"copyAlpha", vgradGreen(90), fillAlpha(192), Over, color.RGBA{100, 36, 0, 255}},
	{"copyAlphaSrc", vgradGreen(90), fillAlpha(192), Src, color.RGBA{0, 36, 0, 68}},
	{"copyNil", vgradGreen(90), nil, Over, color.RGBA{88, 48, 0, 255}},
	{"copyNilSrc", vgradGreen(90), nil, Src, color.RGBA{0, 48, 0, 90}},
	// Uniform mask (100%, 75%, nil) and variable NRGBA source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 136, 0, 90} in NRGBA-space, which is {0, 48, 0, 90} in RGBA-space.
	// The result pixel is different than in the "copy*" test cases because of rounding errors.
	{"nrgba", vgradGreenNRGBA(90), fillAlpha(255), Over, color.RGBA{88, 46, 0, 255}},
	{"nrgbaSrc", vgradGreenNRGBA(90), fillAlpha(255), Src, color.RGBA{0, 46, 0, 90}},
	{"nrgbaAlpha", vgradGreenNRGBA(90), fillAlpha(192), Over, color.RGBA{100, 34, 0, 255}},
	{"nrgbaAlphaSrc", vgradGreenNRGBA(90), fillAlpha(192), Src, color.RGBA{0, 34, 0, 68}},
	{"nrgbaNil", vgradGreenNRGBA(90), nil, Over, color.RGBA{88, 46, 0, 255}},
	{"nrgbaNilSrc", vgradGreenNRGBA(90), nil, Src, color.RGBA{0, 46, 0, 90}},
	// Uniform mask (100%, 75%, nil) and variable YCbCr source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 0, 136} in YCbCr-space, which is {11, 38, 0, 255} in RGB-space.
	{"ycbcr", vgradCr(), fillAlpha(255), Over, color.RGBA{11, 38, 0, 255}},
	{"ycbcrSrc", vgradCr(), fillAlpha(255), Src, color.RGBA{11, 38, 0, 255}},
	{"ycbcrAlpha", vgradCr(), fillAlpha(192), Over, color.RGBA{42, 28, 0, 255}},
	{"ycbcrAlphaSrc", vgradCr(), fillAlpha(192), Src, color.RGBA{8, 28, 0, 192}},
	{"ycbcrNil", vgradCr(), nil, Over, color.RGBA{11, 38, 0, 255}},
	{"ycbcrNilSrc", vgradCr(), nil, Src, color.RGBA{11, 38, 0, 255}},
	// Uniform mask (100%, 75%, nil) and variable Gray source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {136} in Gray-space, which is {136, 136, 136, 255} in RGBA-space.
	{"gray", vgradGray(), fillAlpha(255), Over, color.RGBA{136, 136, 136, 255}},
	{"graySrc", vgradGray(), fillAlpha(255), Src, color.RGBA{136, 136, 136, 255}},
	{"grayAlpha", vgradGray(), fillAlpha(192), Over, color.RGBA{136, 102, 102, 255}},
	{"grayAlphaSrc", vgradGray(), fillAlpha(192), Src, color.RGBA{102, 102, 102, 192}},
	{"grayNil", vgradGray(), nil, Over, color.RGBA{136, 136, 136, 255}},
	{"grayNilSrc", vgradGray(), nil, Src, color.RGBA{136, 136, 136, 255}},
	// Uniform mask (100%, 75%, nil) and variable CMYK source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 136, 0, 63} in CMYK-space, which is {192, 89, 192} in RGB-space.
	{"cmyk", vgradMagenta(), fillAlpha(255), Over, color.RGBA{192, 89, 192, 255}},
	{"cmykSrc", vgradMagenta(), fillAlpha(255), Src, color.RGBA{192, 89, 192, 255}},
	{"cmykAlpha", vgradMagenta(), fillAlpha(192), Over, color.RGBA{178, 67, 145, 255}},
	{"cmykAlphaSrc", vgradMagenta(), fillAlpha(192), Src, color.RGBA{145, 67, 145, 192}},
	{"cmykNil", vgradMagenta(), nil, Over, color.RGBA{192, 89, 192, 255}},
	{"cmykNilSrc", vgradMagenta(), nil, Src, color.RGBA{192, 89, 192, 255}},
	// Variable mask and variable source.
	// At (x, y) == (8, 8):
	// The destination pixel is {136, 0, 0, 255}.
	// The source pixel is {0, 0, 255, 255}.
	// The mask pixel's alpha is 102, or 40%.
	{"generic", fillBlue(255), vgradAlpha(192), Over, color.RGBA{81, 0, 102, 255}},
	{"genericSrc", fillBlue(255), vgradAlpha(192), Src, color.RGBA{0, 0, 102, 102}},
	}

	func makeGolden(dst image.Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, op Op) image.Image {
	// Since golden is a newly allocated image, we don't have to check if the
	// input source and mask images and the output golden image overlap.
	b := dst.Bounds()
	sb := src.Bounds()
	mb := image.Rect(-1e9, -1e9, 1e9, 1e9)
	if mask != nil {
	mb = mask.Bounds()
	}
	golden := image.NewRGBA(image.Rect(0, 0, b.Max.X, b.Max.Y))
	for y := r.Min.Y; y < r.Max.Y; y++ {
	sy := y + sp.Y - r.Min.Y
	my := y + mp.Y - r.Min.Y
	for x := r.Min.X; x < r.Max.X; x++ {
	if !(image.Pt(x, y).In(b)) {
	continue
	}
	sx := x + sp.X - r.Min.X
	if !(image.Pt(sx, sy).In(sb)) {
	continue
	}
	mx := x + mp.X - r.Min.X
	if !(image.Pt(mx, my).In(mb)) {
	continue
	}

	const M = 1<<16 - 1
	var dr, dg, db, da uint32
	if op == Over {
	dr, dg, db, da = dst.At(x, y).RGBA()
	}
	sr, sg, sb, sa := src.At(sx, sy).RGBA()
	ma := uint32(M)
	if mask != nil {
	_, _, _, ma = mask.At(mx, my).RGBA()
	}
	a := M - (sa * ma / M)
	golden.Set(x, y, color.RGBA64{
	uint16((dra + srma) / M),
	uint16((dga + sgma) / M),
	uint16((dba + sbma) / M),
	uint16((daa + sama) / M),
	})
	}
	}
	return golden.SubImage(b)
	}

	func TestDraw(t *testing.T) {
	rr := []image.Rectangle{
	image.Rect(0, 0, 0, 0),
	image.Rect(0, 0, 16, 16),
	image.Rect(3, 5, 12, 10),
	image.Rect(0, 0, 9, 9),
	image.Rect(8, 8, 16, 16),
	image.Rect(8, 0, 9, 16),
	image.Rect(0, 8, 16, 9),
	image.Rect(8, 8, 9, 9),
	image.Rect(8, 8, 8, 8),
	}
	for _, r := range rr {
	loop:
	for _, test := range drawTests {
	dst := hgradRed(255).(*image.RGBA).SubImage(r).(Image)
	// Draw the (src, mask, op) onto a copy of dst using a slow but obviously correct implementation.
	golden := makeGolden(dst, image.Rect(0, 0, 16, 16), test.src, image.ZP, test.mask, image.ZP, test.op)
	b := dst.Bounds()
	if !b.Eq(golden.Bounds()) {
	t.Errorf("draw %v %s: bounds %v versus %v", r, test.desc, dst.Bounds(), golden.Bounds())
	continue
	}
	// Draw the same combination onto the actual dst using the optimized DrawMask implementation.
	DrawMask(dst, image.Rect(0, 0, 16, 16), test.src, image.ZP, test.mask, image.ZP, test.op)
	if image.Pt(8, 8).In(r) {
	// Check that the resultant pixel at (8, 8) matches what we expect
	// (the expected value can be verified by hand).
	if !eq(dst.At(8, 8), test.expected) {
	t.Errorf("draw %v %s: at (8, 8) %v versus %v", r, test.desc, dst.At(8, 8), test.expected)
	continue
	}
	}
	// Check that the resultant dst image matches the golden output.
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	if !eq(dst.At(x, y), golden.At(x, y)) {
	t.Errorf("draw %v %s: at (%d, %d), %v versus golden %v", r, test.desc, x, y, dst.At(x, y), golden.At(x, y))
	continue loop
	}
	}
	}
	}
	}
	}

	func TestDrawOverlap(t *testing.T) {
	for _, op := range []Op{Over, Src} {
	for yoff := -2; yoff <= 2; yoff++ {
	loop:
	for xoff := -2; xoff <= 2; xoff++ {
	m := gradYellow(127).(*image.RGBA)
	dst := m.SubImage(image.Rect(5, 5, 10, 10)).(*image.RGBA)
	src := m.SubImage(image.Rect(5+xoff, 5+yoff, 10+xoff, 10+yoff)).(*image.RGBA)
	b := dst.Bounds()
	// Draw the (src, mask, op) onto a copy of dst using a slow but obviously correct implementation.
	golden := makeGolden(dst, b, src, src.Bounds().Min, nil, image.ZP, op)
	if !b.Eq(golden.Bounds()) {
	t.Errorf("drawOverlap xoff=%d,yoff=%d: bounds %v versus %v", xoff, yoff, dst.Bounds(), golden.Bounds())
	continue
	}
	// Draw the same combination onto the actual dst using the optimized DrawMask implementation.
	DrawMask(dst, b, src, src.Bounds().Min, nil, image.ZP, op)
	// Check that the resultant dst image matches the golden output.
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	if !eq(dst.At(x, y), golden.At(x, y)) {
	t.Errorf("drawOverlap xoff=%d,yoff=%d: at (%d, %d), %v versus golden %v", xoff, yoff, x, y, dst.At(x, y), golden.At(x, y))
	continue loop
	}
	}
	}
	}
	}
	}
	}

	// TestNonZeroSrcPt checks drawing with a non-zero src point parameter.
	func TestNonZeroSrcPt(t *testing.T) {
	a := image.NewRGBA(image.Rect(0, 0, 1, 1))
	b := image.NewRGBA(image.Rect(0, 0, 2, 2))
	b.Set(0, 0, color.RGBA{0, 0, 0, 5})
	b.Set(1, 0, color.RGBA{0, 0, 5, 5})
	b.Set(0, 1, color.RGBA{0, 5, 0, 5})
	b.Set(1, 1, color.RGBA{5, 0, 0, 5})
	Draw(a, image.Rect(0, 0, 1, 1), b, image.Pt(1, 1), Over)
	if !eq(color.RGBA{5, 0, 0, 5}, a.At(0, 0)) {
	t.Errorf("non-zero src pt: want %v got %v", color.RGBA{5, 0, 0, 5}, a.At(0, 0))
	}
	}

	func TestFill(t *testing.T) {
	rr := []image.Rectangle{
	image.Rect(0, 0, 0, 0),
	image.Rect(0, 0, 40, 30),
	image.Rect(10, 0, 40, 30),
	image.Rect(0, 20, 40, 30),
	image.Rect(10, 20, 40, 30),
	image.Rect(10, 20, 15, 25),
	image.Rect(10, 0, 35, 30),
	image.Rect(0, 15, 40, 16),
	image.Rect(24, 24, 25, 25),
	image.Rect(23, 23, 26, 26),
	image.Rect(22, 22, 27, 27),
	image.Rect(21, 21, 28, 28),
	image.Rect(20, 20, 29, 29),
	}
	for _, r := range rr {
	m := image.NewRGBA(image.Rect(0, 0, 40, 30)).SubImage(r).(*image.RGBA)
	b := m.Bounds()
	c := color.RGBA{11, 0, 0, 255}
	src := &image.Uniform{C: c}
	check := func(desc string) {
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	if !eq(c, m.At(x, y)) {
	t.Errorf("%s fill: at (%d, %d), sub-image bounds=%v: want %v got %v", desc, x, y, r, c, m.At(x, y))
	return
	}
	}
	}
	}
	// Draw 1 pixel at a time.
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	DrawMask(m, image.Rect(x, y, x+1, y+1), src, image.ZP, nil, image.ZP, Src)
	}
	}
	check("pixel")
	// Draw 1 row at a time.
	c = color.RGBA{0, 22, 0, 255}
	src = &image.Uniform{C: c}
	for y := b.Min.Y; y < b.Max.Y; y++ {
	DrawMask(m, image.Rect(b.Min.X, y, b.Max.X, y+1), src, image.ZP, nil, image.ZP, Src)
	}
	check("row")
	// Draw 1 column at a time.
	c = color.RGBA{0, 0, 33, 255}
	src = &image.Uniform{C: c}
	for x := b.Min.X; x < b.Max.X; x++ {
	DrawMask(m, image.Rect(x, b.Min.Y, x+1, b.Max.Y), src, image.ZP, nil, image.ZP, Src)
	}
	check("column")
	// Draw the whole image at once.
	c = color.RGBA{44, 55, 66, 77}
	src = &image.Uniform{C: c}
	DrawMask(m, b, src, image.ZP, nil, image.ZP, Src)
	check("whole")
	}
	}

	// TestFloydSteinbergCheckerboard tests that the result of Floyd-Steinberg
	// error diffusion of a uniform 50% gray source image with a black-and-white
	// palette is a checkerboard pattern.
	func TestFloydSteinbergCheckerboard(t *testing.T) {
	b := image.Rect(0, 0, 640, 480)
	// We can't represent 50% exactly, but 0x7fff / 0xffff is close enough.
	src := &image.Uniform{color.Gray16{0x7fff}}
	dst := image.NewPaletted(b, color.Palette{color.Black, color.White})
	FloydSteinberg.Draw(dst, b, src, image.Point{})
	nErr := 0
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	got := dst.Pix[dst.PixOffset(x, y)]
	want := uint8(x+y) % 2
	if got != want {
	t.Errorf("at (%d, %d): got %d, want %d", x, y, got, want)
	if nErr++; nErr == 10 {
	t.Fatal("there may be more errors")
	}
	}
	}
	}
	}

	// embeddedPaletted is an Image that behaves like an *image.Paletted but whose
	// type is not *image.Paletted.
	type embeddedPaletted struct {
	*image.Paletted
	}

	// TestPaletted tests that the drawPaletted function behaves the same
	// regardless of whether dst is an *image.Paletted.
	func TestPaletted(t *testing.T) {
	f, err := os.Open("../testdata/video-001.png")
	if err != nil {
	t.Fatalf("open: %v", err)
	}
	defer f.Close()
	src, err := png.Decode(f)
	if err != nil {
	t.Fatalf("decode: %v", err)
	}
	b := src.Bounds()

	cgaPalette := color.Palette{
	color.RGBA{0x00, 0x00, 0x00, 0xff},
	color.RGBA{0x55, 0xff, 0xff, 0xff},
	color.RGBA{0xff, 0x55, 0xff, 0xff},
	color.RGBA{0xff, 0xff, 0xff, 0xff},
	}
	drawers := map[string]Drawer{
	"src": Src,
	"floyd-steinberg": FloydSteinberg,
	}

	loop:
	for dName, d := range drawers {
	dst0 := image.NewPaletted(b, cgaPalette)
	dst1 := image.NewPaletted(b, cgaPalette)
	d.Draw(dst0, b, src, image.Point{})
	d.Draw(embeddedPaletted{dst1}, b, src, image.Point{})
	for y := b.Min.Y; y < b.Max.Y; y++ {
	for x := b.Min.X; x < b.Max.X; x++ {
	if !eq(dst0.At(x, y), dst1.At(x, y)) {
	t.Errorf("%s: at (%d, %d), %v versus %v",
	dName, x, y, dst0.At(x, y), dst1.At(x, y))
	continue loop
	}
	}
	}
	}
	}

	func TestSqDiff(t *testing.T) {
	// This test is similar to the one from the image/color package, but
	// sqDiff in this package accepts int32 instead of uint32, so test it
	// for appropriate input.

	// canonical sqDiff implementation
	orig := func(x, y int32) uint32 {
	var d uint32
	if x > y {
	d = uint32(x - y)
	} else {
	d = uint32(y - x)
	}
	return (d * d) >> 2
	}
	testCases := []int32{
	0,
	1,
	2,
	0x0fffd,
	0x0fffe,
	0x0ffff,
	0x10000,
	0x10001,
	0x10002,
	0x7ffffffd,
	0x7ffffffe,
	0x7fffffff,
	-0x7ffffffd,
	-0x7ffffffe,
	-0x80000000,
	}
	for _, x := range testCases {
	for _, y := range testCases {
	if got, want := sqDiff(x, y), orig(x, y); got != want {
	t.Fatalf("sqDiff(%#x, %#x): got %d, want %d", x, y, got, want)
	}
	}
	}
	if err := quick.CheckEqual(orig, sqDiff, &quick.Config{MaxCountScale: 10}); err != nil {
	t.Fatal(err)
	}
	}