ebiten/image.go

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// Copyright 2014 Hajime Hoshi
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
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package ebiten
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import (
"fmt"
"image"
"image/color"
"github.com/hajimehoshi/ebiten/v2/internal/affine"
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"github.com/hajimehoshi/ebiten/v2/internal/driver"
"github.com/hajimehoshi/ebiten/v2/internal/graphics"
"github.com/hajimehoshi/ebiten/v2/internal/mipmap"
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)
// panicOnErrorAtImageAt indicates whether (*Image).At panics on an error or not.
// This value is set only on testing.
var panicOnErrorAtImageAt bool
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// Image represents a rectangle set of pixels.
// The pixel format is alpha-premultiplied RGBA.
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// Image implements image.Image and draw.Image.
type Image struct {
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// addr holds self to check copying.
// See strings.Builder for similar examples.
addr *Image
mipmap *mipmap.Mipmap
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bounds image.Rectangle
original *Image
screen bool
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}
func (i *Image) copyCheck() {
if i.addr != i {
panic("ebiten: illegal use of non-zero Image copied by value")
}
}
// Size returns the size of the image.
func (i *Image) Size() (width, height int) {
s := i.Bounds().Size()
return s.X, s.Y
}
func (i *Image) isDisposed() bool {
return i.mipmap == nil
}
func (i *Image) isSubImage() bool {
return i.original != nil
}
// Clear resets the pixels of the image into 0.
//
// When the image is disposed, Clear does nothing.
func (i *Image) Clear() {
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i.Fill(color.Transparent)
}
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var (
emptyImage = NewImage(3, 3)
emptySubImage = emptyImage.SubImage(image.Rect(1, 1, 2, 2)).(*Image)
)
func init() {
w, h := emptyImage.Size()
pix := make([]byte, 4*w*h)
for i := range pix {
pix[i] = 0xff
}
// As emptyImage is used at Fill, use ReplacePixels instead.
emptyImage.ReplacePixels(pix)
}
// Fill fills the image with a solid color.
//
// When the image is disposed, Fill does nothing.
func (i *Image) Fill(clr color.Color) {
// Use the original size to cover the entire region (#1691).
// DrawImage automatically clips the rendering region.
orig := i
if i.isSubImage() {
orig = i.original
}
w, h := orig.Size()
op := &DrawImageOptions{}
op.GeoM.Scale(float64(w), float64(h))
r, g, b, a := clr.RGBA()
var rf, gf, bf, af float64
if a > 0 {
rf = float64(r) / float64(a)
gf = float64(g) / float64(a)
bf = float64(b) / float64(a)
af = float64(a) / 0xffff
}
op.ColorM.Scale(rf, gf, bf, af)
op.CompositeMode = CompositeModeCopy
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i.DrawImage(emptySubImage, op)
}
func canSkipMipmap(geom GeoM, filter driver.Filter) bool {
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if filter != driver.FilterLinear {
return true
}
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return geom.det2x2() >= 0.999
}
// DrawImageOptions represents options for DrawImage.
type DrawImageOptions struct {
// GeoM is a geometry matrix to draw.
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// The default (zero) value is identity, which draws the image at (0, 0).
GeoM GeoM
// ColorM is a color matrix to draw.
// The default (zero) value is identity, which doesn't change any color.
ColorM ColorM
// CompositeMode is a composite mode to draw.
// The default (zero) value is regular alpha blending.
CompositeMode CompositeMode
// Filter is a type of texture filter.
// The default (zero) value is FilterNearest.
Filter Filter
}
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// DrawImage draws the given image on the image i.
//
// DrawImage accepts the options. For details, see the document of
// DrawImageOptions.
//
// For drawing, the pixels of the argument image at the time of this call is
// adopted. Even if the argument image is mutated after this call, the drawing
// result is never affected.
//
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// When the image i is disposed, DrawImage does nothing.
// When the given image img is disposed, DrawImage panics.
//
// When the given image is as same as i, DrawImage panics.
//
// DrawImage works more efficiently as batches
// when the successive calls of DrawImages satisfy the below conditions:
//
// * All render targets are same (A in A.DrawImage(B, op))
// * Either all ColorM element values are same or all the ColorM have only
// diagonal ('scale') elements
// * If only (*ColorM).Scale is applied to a ColorM, the ColorM has only
// diagonal elements. The other ColorM functions might modify the other
// elements.
// * All CompositeMode values are same
// * All Filter values are same
//
// Even when all the above conditions are satisfied, multiple draw commands can
// be used in really rare cases. Ebiten images usually share an internal
// automatic texture atlas, but when you consume the atlas, or you create a huge
// image, those images cannot be on the same texture atlas. In this case, draw
// commands are separated. The texture atlas size is 4096x4096 so far. Another
// case is when you use an offscreen as a render source. An offscreen doesn't
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// share the texture atlas with high probability.
//
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// For more performance tips, see https://ebiten.org/documents/performancetips.html
func (i *Image) DrawImage(img *Image, options *DrawImageOptions) {
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i.copyCheck()
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if img.isDisposed() {
panic("ebiten: the given image to DrawImage must not be disposed")
}
if i.isDisposed() {
return
}
dstBounds := i.Bounds()
dstRegion := driver.Region{
X: float32(dstBounds.Min.X),
Y: float32(dstBounds.Min.Y),
Width: float32(dstBounds.Dx()),
Height: float32(dstBounds.Dy()),
}
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// Calculate vertices before locking because the user can do anything in
// options.ImageParts interface without deadlock (e.g. Call Image functions).
if options == nil {
options = &DrawImageOptions{}
}
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bounds := img.Bounds()
mode := driver.CompositeMode(options.CompositeMode)
filter := driver.Filter(options.Filter)
a, b, c, d, tx, ty := options.GeoM.elements32()
sx0 := float32(bounds.Min.X)
sy0 := float32(bounds.Min.Y)
sx1 := float32(bounds.Max.X)
sy1 := float32(bounds.Max.Y)
vs := graphics.QuadVertices(sx0, sy0, sx1, sy1, a, b, c, d, tx, ty, 1, 1, 1, 1)
is := graphics.QuadIndices()
srcs := [graphics.ShaderImageNum]*mipmap.Mipmap{img.mipmap}
i.mipmap.DrawTriangles(srcs, vs, is, options.ColorM.affineColorM(), mode, filter, driver.AddressUnsafe, dstRegion, driver.Region{}, [graphics.ShaderImageNum - 1][2]float32{}, nil, nil, false, canSkipMipmap(options.GeoM, filter))
}
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// Vertex represents a vertex passed to DrawTriangles.
type Vertex struct {
// DstX and DstY represents a point on a destination image.
DstX float32
DstY float32
// SrcX and SrcY represents a point on a source image.
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// Be careful that SrcX/SrcY coordinates are on the image's bounds.
// This means that a left-upper point of a sub-image might not be (0, 0).
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SrcX float32
SrcY float32
// ColorR/ColorG/ColorB/ColorA represents color scaling values.
// 1 means the original source image color is used.
// 0 means a transparent color is used.
ColorR float32
ColorG float32
ColorB float32
ColorA float32
}
// Address represents a sampler address mode.
type Address int
const (
// AddressUnsafe means there is no guarantee when the texture coodinates are out of range.
AddressUnsafe Address = Address(driver.AddressUnsafe)
// AddressClampToZero means that out-of-range texture coordinates return 0 (transparent).
AddressClampToZero Address = Address(driver.AddressClampToZero)
// AddressRepeat means that texture coordinates wrap to the other side of the texture.
AddressRepeat Address = Address(driver.AddressRepeat)
)
// DrawTrianglesOptions represents options for DrawTriangles.
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type DrawTrianglesOptions struct {
// ColorM is a color matrix to draw.
// The default (zero) value is identity, which doesn't change any color.
// ColorM is applied before vertex color scale is applied.
//
// If Shader is not nil, ColorM is ignored.
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ColorM ColorM
// CompositeMode is a composite mode to draw.
// The default (zero) value is regular alpha blending.
CompositeMode CompositeMode
// Filter is a type of texture filter.
// The default (zero) value is FilterNearest.
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Filter Filter
// Address is a sampler address mode.
// The default (zero) value is AddressUnsafe.
Address Address
// EvenOdd represents whether the even-odd rule is applied or not.
//
// If EvenOdd is true, triangles are rendered based on the even-odd rule. If false, triangles are rendered without condition.
// Whether overlapped regions by multiple triangles is rendered or not depends on the number of the overlapping:
// if and only if the number is odd, the region is rendered.
//
// EvenOdd is useful when you want to render a complex polygon.
// A complex polygon is a non-convex polygon like a concave polygon, a polygon with holes, or a self-intersecting polygon.
// See examples/vector for actual usages.
//
// The default value is false.
EvenOdd bool
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}
// MaxIndicesNum is the maximum number of indices for DrawTriangles.
const MaxIndicesNum = graphics.IndicesNum
// DrawTriangles draws triangles with the specified vertices and their indices.
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//
// If len(indices) is not multiple of 3, DrawTriangles panics.
//
// If len(indices) is more than MaxIndicesNum, DrawTriangles panics.
//
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// The rule in which DrawTriangles works effectively is same as DrawImage's.
//
// When the given image is disposed, DrawTriangles panics.
//
// When the image i is disposed, DrawTriangles does nothing.
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func (i *Image) DrawTriangles(vertices []Vertex, indices []uint16, img *Image, options *DrawTrianglesOptions) {
i.copyCheck()
if img != nil && img.isDisposed() {
panic("ebiten: the given image to DrawTriangles must not be disposed")
}
if i.isDisposed() {
return
}
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if len(indices)%3 != 0 {
panic("ebiten: len(indices) % 3 must be 0")
}
if len(indices) > MaxIndicesNum {
panic("ebiten: len(indices) must be <= MaxIndicesNum")
}
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// TODO: Check the maximum value of indices and len(vertices)?
dstBounds := i.Bounds()
dstRegion := driver.Region{
X: float32(dstBounds.Min.X),
Y: float32(dstBounds.Min.Y),
Width: float32(dstBounds.Dx()),
Height: float32(dstBounds.Dy()),
}
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if options == nil {
options = &DrawTrianglesOptions{}
}
mode := driver.CompositeMode(options.CompositeMode)
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address := driver.Address(options.Address)
var sr driver.Region
if address != driver.AddressUnsafe {
b := img.Bounds()
sr = driver.Region{
X: float32(b.Min.X),
Y: float32(b.Min.Y),
Width: float32(b.Dx()),
Height: float32(b.Dy()),
}
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}
filter := driver.Filter(options.Filter)
vs := graphics.Vertices(len(vertices))
for i, v := range vertices {
vs[i*graphics.VertexFloatNum] = v.DstX
vs[i*graphics.VertexFloatNum+1] = v.DstY
vs[i*graphics.VertexFloatNum+2] = v.SrcX
vs[i*graphics.VertexFloatNum+3] = v.SrcY
vs[i*graphics.VertexFloatNum+4] = v.ColorR
vs[i*graphics.VertexFloatNum+5] = v.ColorG
vs[i*graphics.VertexFloatNum+6] = v.ColorB
vs[i*graphics.VertexFloatNum+7] = v.ColorA
}
is := make([]uint16, len(indices))
copy(is, indices)
srcs := [graphics.ShaderImageNum]*mipmap.Mipmap{img.mipmap}
i.mipmap.DrawTriangles(srcs, vs, is, options.ColorM.affineColorM(), mode, filter, address, dstRegion, sr, [graphics.ShaderImageNum - 1][2]float32{}, nil, nil, options.EvenOdd, false)
}
// DrawTrianglesShaderOptions represents options for DrawTrianglesShader.
//
// This API is experimental.
type DrawTrianglesShaderOptions struct {
// CompositeMode is a composite mode to draw.
// The default (zero) value is regular alpha blending.
CompositeMode CompositeMode
// Uniforms is a set of uniform variables for the shader.
// The keys are the names of the uniform variables.
// The values must be float or []float.
// If the uniform variable type is an array, a vector or a matrix,
// you have to specify linearly flattened values as a slice.
// For example, if the uniform variable type is [4]vec4, the number of the slice values will be 16.
Uniforms map[string]interface{}
// Images is a set of the source images.
// All the image must be the same size.
Images [4]*Image
// EvenOdd represents whether the even-odd rule is applied or not.
//
// If EvenOdd is true, triangles are rendered based on the even-odd rule. If false, triangles are rendered without condition.
// Whether overlapped regions by multiple triangles is rendered or not depends on the number of the overlapping:
// if and only if the number is odd, the region is rendered.
//
// EvenOdd is useful when you want to render a complex polygon.
// A complex polygon is a non-convex polygon like a concave polygon, a polygon with holes, or a self-intersecting polygon.
// See examples/vector for actual usages.
//
// The default value is false.
EvenOdd bool
}
func init() {
var op DrawTrianglesShaderOptions
if got, want := len(op.Images), graphics.ShaderImageNum; got != want {
panic(fmt.Sprintf("ebiten: len((DrawTrianglesShaderOptions{}).Images) must be %d but %d", want, got))
}
}
// DrawTrianglesShader draws triangles with the specified vertices and their indices with the specified shader.
//
// For the details about the shader, see https://ebiten.org/documents/shader.html.
//
// If len(indices) is not multiple of 3, DrawTrianglesShader panics.
//
// If len(indices) is more than MaxIndicesNum, DrawTrianglesShader panics.
//
// When a specified image is non-nil and is disposed, DrawTrianglesShader panics.
//
// When the image i is disposed, DrawTrianglesShader does nothing.
//
// This API is experimental.
func (i *Image) DrawTrianglesShader(vertices []Vertex, indices []uint16, shader *Shader, options *DrawTrianglesShaderOptions) {
i.copyCheck()
if i.isDisposed() {
return
}
if len(indices)%3 != 0 {
panic("ebiten: len(indices) % 3 must be 0")
}
if len(indices) > MaxIndicesNum {
panic("ebiten: len(indices) must be <= MaxIndicesNum")
}
// TODO: Check the maximum value of indices and len(vertices)?
dstBounds := i.Bounds()
dstRegion := driver.Region{
X: float32(dstBounds.Min.X),
Y: float32(dstBounds.Min.Y),
Width: float32(dstBounds.Dx()),
Height: float32(dstBounds.Dy()),
}
if options == nil {
options = &DrawTrianglesShaderOptions{}
}
mode := driver.CompositeMode(options.CompositeMode)
vs := graphics.Vertices(len(vertices))
for i, v := range vertices {
vs[i*graphics.VertexFloatNum] = v.DstX
vs[i*graphics.VertexFloatNum+1] = v.DstY
vs[i*graphics.VertexFloatNum+2] = v.SrcX
vs[i*graphics.VertexFloatNum+3] = v.SrcY
vs[i*graphics.VertexFloatNum+4] = v.ColorR
vs[i*graphics.VertexFloatNum+5] = v.ColorG
vs[i*graphics.VertexFloatNum+6] = v.ColorB
vs[i*graphics.VertexFloatNum+7] = v.ColorA
}
is := make([]uint16, len(indices))
copy(is, indices)
var imgs [graphics.ShaderImageNum]*mipmap.Mipmap
var imgw, imgh int
for i, img := range options.Images {
if img == nil {
continue
}
if img.isDisposed() {
panic("ebiten: the given image to DrawRectShader must not be disposed")
}
if i == 0 {
imgw, imgh = img.Size()
} else {
// TODO: Check imgw > 0 && imgh > 0
if w, h := img.Size(); imgw != w || imgh != h {
panic("ebiten: all the source images must be the same size with the rectangle")
}
}
imgs[i] = img.mipmap
}
var sx, sy float32
if options.Images[0] != nil {
b := options.Images[0].Bounds()
sx = float32(b.Min.X)
sy = float32(b.Min.Y)
}
var sr driver.Region
if img := options.Images[0]; img != nil {
b := img.Bounds()
sr = driver.Region{
X: float32(b.Min.X),
Y: float32(b.Min.Y),
Width: float32(b.Dx()),
Height: float32(b.Dy()),
}
}
var offsets [graphics.ShaderImageNum - 1][2]float32
for i, img := range options.Images[1:] {
if img == nil {
continue
}
b := img.Bounds()
offsets[i][0] = -sx + float32(b.Min.X)
offsets[i][1] = -sy + float32(b.Min.Y)
}
us := shader.convertUniforms(options.Uniforms)
i.mipmap.DrawTriangles(imgs, vs, is, affine.ColorMIdentity{}, mode, driver.FilterNearest, driver.AddressUnsafe, dstRegion, sr, offsets, shader.shader, us, options.EvenOdd, false)
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}
// DrawRectShaderOptions represents options for DrawRectShader.
//
// This API is experimental.
type DrawRectShaderOptions struct {
// GeoM is a geometry matrix to draw.
// The default (zero) value is identity, which draws the rectangle at (0, 0).
GeoM GeoM
// CompositeMode is a composite mode to draw.
// The default (zero) value is regular alpha blending.
CompositeMode CompositeMode
// Uniforms is a set of uniform variables for the shader.
// The keys are the names of the uniform variables.
// The values must be float or []float.
// If the uniform variable type is an array, a vector or a matrix,
// you have to specify linearly flattened values as a slice.
// For example, if the uniform variable type is [4]vec4, the number of the slice values will be 16.
Uniforms map[string]interface{}
// Images is a set of the source images.
// All the image must be the same size with the rectangle.
Images [4]*Image
}
func init() {
var op DrawRectShaderOptions
if got, want := len(op.Images), graphics.ShaderImageNum; got != want {
panic(fmt.Sprintf("ebiten: len((DrawRectShaderOptions{}).Images) must be %d but %d", want, got))
}
}
// DrawRectShader draws a rectangle with the specified width and height with the specified shader.
//
// For the details about the shader, see https://ebiten.org/documents/shader.html.
//
// When one of the specified image is non-nil and is disposed, DrawRectShader panics.
//
// When the image i is disposed, DrawRectShader does nothing.
//
// This API is experimental.
func (i *Image) DrawRectShader(width, height int, shader *Shader, options *DrawRectShaderOptions) {
i.copyCheck()
if i.isDisposed() {
return
}
dstBounds := i.Bounds()
dstRegion := driver.Region{
X: float32(dstBounds.Min.X),
Y: float32(dstBounds.Min.Y),
Width: float32(dstBounds.Dx()),
Height: float32(dstBounds.Dy()),
}
if options == nil {
options = &DrawRectShaderOptions{}
}
mode := driver.CompositeMode(options.CompositeMode)
var imgs [graphics.ShaderImageNum]*mipmap.Mipmap
for i, img := range options.Images {
if img == nil {
continue
}
if img.isDisposed() {
panic("ebiten: the given image to DrawRectShader must not be disposed")
}
if w, h := img.Size(); width != w || height != h {
panic("ebiten: all the source images must be the same size with the rectangle")
}
imgs[i] = img.mipmap
}
var sx, sy float32
if options.Images[0] != nil {
b := options.Images[0].Bounds()
sx = float32(b.Min.X)
sy = float32(b.Min.Y)
}
a, b, c, d, tx, ty := options.GeoM.elements32()
vs := graphics.QuadVertices(sx, sy, sx+float32(width), sy+float32(height), a, b, c, d, tx, ty, 1, 1, 1, 1)
is := graphics.QuadIndices()
var sr driver.Region
if img := options.Images[0]; img != nil {
b := img.Bounds()
sr = driver.Region{
X: float32(b.Min.X),
Y: float32(b.Min.Y),
Width: float32(b.Dx()),
Height: float32(b.Dy()),
}
}
var offsets [graphics.ShaderImageNum - 1][2]float32
for i, img := range options.Images[1:] {
if img == nil {
continue
}
b := img.Bounds()
offsets[i][0] = -sx + float32(b.Min.X)
offsets[i][1] = -sy + float32(b.Min.Y)
}
us := shader.convertUniforms(options.Uniforms)
i.mipmap.DrawTriangles(imgs, vs, is, affine.ColorMIdentity{}, mode, driver.FilterNearest, driver.AddressUnsafe, dstRegion, sr, offsets, shader.shader, us, false, canSkipMipmap(options.GeoM, driver.FilterNearest))
}
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// SubImage returns an image representing the portion of the image p visible through r.
// The returned value shares pixels with the original image.
//
// The returned value is always *ebiten.Image.
//
// If the image is disposed, SubImage returns nil.
//
// A sub-image returned by SubImage can be used as a rendering source and a rendering destination.
// If a sub-image is used as a rendering source, the image is used as if it is a small image.
// If a sub-image is used as a rendering destination, the region being rendered is clipped.
func (i *Image) SubImage(r image.Rectangle) image.Image {
i.copyCheck()
if i.isDisposed() {
return nil
}
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r = r.Intersect(i.Bounds())
// Need to check Empty explicitly. See the standard image package implementations.
if r.Empty() {
r = image.ZR
}
// Keep the original image's reference not to dispose that by GC.
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var orig = i
if i.isSubImage() {
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orig = i.original
}
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img := &Image{
mipmap: i.mipmap,
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bounds: r,
original: orig,
}
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img.addr = img
return img
}
// Bounds returns the bounds of the image.
func (i *Image) Bounds() image.Rectangle {
if i.isDisposed() {
panic("ebiten: the image is already disposed")
}
return i.bounds
}
// ColorModel returns the color model of the image.
func (i *Image) ColorModel() color.Model {
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return color.RGBAModel
}
// At returns the color of the image at (x, y).
//
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// At loads pixels from GPU to system memory if necessary, which means that At can be slow.
//
// At always returns a transparent color if the image is disposed.
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//
// Note that an important logic should not rely on values returned by At, since
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// the returned values can include very slight differences between some machines.
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//
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// At can't be called outside the main loop (ebiten.Run's updating function) starts.
func (i *Image) At(x, y int) color.Color {
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if i.isDisposed() {
return color.RGBA{}
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}
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if !image.Pt(x, y).In(i.Bounds()) {
return color.RGBA{}
}
pix, err := i.mipmap.Pixels(x, y, 1, 1)
if err != nil {
if panicOnErrorAtImageAt {
panic(err)
}
theUIContext.setError(err)
return color.RGBA{}
}
return color.RGBA{pix[0], pix[1], pix[2], pix[3]}
}
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// Set sets the color at (x, y).
//
// Set loads pixels from GPU to system memory if necessary, which means that Set can be slow.
//
// In the current implementation, successive calls of Set invokes loading pixels at most once, so this is efficient.
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//
// If the image is disposed, Set does nothing.
func (i *Image) Set(x, y int, clr color.Color) {
i.copyCheck()
if i.isDisposed() {
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return
}
if !image.Pt(x, y).In(i.Bounds()) {
return
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}
if i.isSubImage() {
i = i.original
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}
r, g, b, a := clr.RGBA()
pix := []byte{byte(r >> 8), byte(g >> 8), byte(b >> 8), byte(a >> 8)}
if err := i.mipmap.ReplacePixels(pix, x, y, 1, 1); err != nil {
theUIContext.setError(err)
}
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}
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// Dispose disposes the image data.
// After disposing, most of image functions do nothing and returns meaningless values.
//
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// Calling Dispose is not mandatory. GC automatically collects internal resources that no objects refer to.
// However, calling Dispose explicitly is helpful if memory usage matters.
//
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// If the image is a sub-image, Dispose does nothing.
//
// When the image is disposed, Dipose does nothing.
func (i *Image) Dispose() {
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i.copyCheck()
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if i.isDisposed() {
return
}
if i.isSubImage() {
return
}
i.mipmap.MarkDisposed()
i.mipmap = nil
}
// ReplacePixels replaces the pixels of the image with p.
//
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// The given p must represent RGBA pre-multiplied alpha values.
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// len(pix) must equal to 4 * (bounds width) * (bounds height).
//
// ReplacePixels works on a sub-image.
//
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// When len(pix) is not appropriate, ReplacePixels panics.
//
// When the image is disposed, ReplacePixels does nothing.
func (i *Image) ReplacePixels(pixels []byte) {
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i.copyCheck()
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if i.isDisposed() {
return
}
r := i.Bounds()
// Do not need to copy pixels here.
// * In internal/mipmap, pixels are copied when necessary.
// * In internal/shareable, pixels are copied to make its paddings.
if err := i.mipmap.ReplacePixels(pixels, r.Min.X, r.Min.Y, r.Dx(), r.Dy()); err != nil {
theUIContext.setError(err)
}
}
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// NewImage returns an empty image.
//
// If width or height is less than 1 or more than device-dependent maximum size, NewImage panics.
//
// NewImage panics if RunGame already finishes.
func NewImage(width, height int) *Image {
if isRunGameEnded() {
panic(fmt.Sprintf("ebiten: NewImage cannot be called after RunGame finishes"))
}
if width <= 0 {
panic(fmt.Sprintf("ebiten: width at NewImage must be positive but %d", width))
}
if height <= 0 {
panic(fmt.Sprintf("ebiten: height at NewImage must be positive but %d", height))
}
i := &Image{
mipmap: mipmap.New(width, height),
bounds: image.Rect(0, 0, width, height),
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}
i.addr = i
return i
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}
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// NewImageFromImage creates a new image with the given image (source).
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//
// If source's width or height is less than 1 or more than device-dependent maximum size, NewImageFromImage panics.
//
// NewImageFromImage panics if RunGame already finishes.
func NewImageFromImage(source image.Image) *Image {
if isRunGameEnded() {
panic(fmt.Sprintf("ebiten: NewImage cannot be called after RunGame finishes"))
}
size := source.Bounds().Size()
width, height := size.X, size.Y
if width <= 0 {
panic(fmt.Sprintf("ebiten: source width at NewImageFromImage must be positive but %d", width))
}
if height <= 0 {
panic(fmt.Sprintf("ebiten: source height at NewImageFromImage must be positive but %d", height))
}
i := &Image{
mipmap: mipmap.New(width, height),
bounds: image.Rect(0, 0, width, height),
}
i.addr = i
i.ReplacePixels(imageToBytes(source))
return i
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}
func newScreenFramebufferImage(width, height int) *Image {
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i := &Image{
mipmap: mipmap.NewScreenFramebufferMipmap(width, height),
bounds: image.Rect(0, 0, width, height),
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screen: true,
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}
i.addr = i
return i
}