ebiten/image.go
Hajime Hoshi 2d079b123f restorable: Add ResetRestoringState to reset the state
After Fill command, the image doesn't have to keep the restoring
information. Now Fill command is as same as DrawTriangles, there
is no way for restorable.Image to know whether it can reset the
state or not. ResetRestoringState clears the state explicitly.
2019-07-20 14:04:02 +09:00

745 lines
21 KiB
Go

// 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.
package ebiten
import (
"fmt"
"image"
"image/color"
"math"
"sync/atomic"
"github.com/hajimehoshi/ebiten/internal/driver"
"github.com/hajimehoshi/ebiten/internal/graphics"
"github.com/hajimehoshi/ebiten/internal/shareable"
)
// Image represents a rectangle set of pixels.
// The pixel format is alpha-premultiplied RGBA.
// Image implements image.Image and draw.Image.
//
// Functions of Image never returns error as of 1.5.0-alpha, and error values are always nil.
type Image struct {
// addr holds self to check copying.
// See strings.Builder for similar examples.
addr *Image
// mipmap is a set of shareable.Image sorted by the order of mipmap level.
// The level 0 image is a regular image and higher-level images are used for mipmap.
mipmap *mipmap
bounds image.Rectangle
original *Image
pendingPixels []byte
filter Filter
}
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.isDisposed()
}
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.
//
// Clear always returns nil as of 1.5.0-alpha.
func (i *Image) Clear() error {
i.Fill(color.Transparent)
return nil
}
var emptyImage *Image
func init() {
const w, h = 16, 16
emptyImage, _ = NewImage(w, h, FilterDefault)
pix := make([]byte, 4*w*h)
for i := range pix {
pix[i] = 0xff
}
emptyImage.ReplacePixels(pix)
}
// Fill fills the image with a solid color.
//
// When the image is disposed, Fill does nothing.
//
// Fill always returns nil as of 1.5.0-alpha.
func (i *Image) Fill(clr color.Color) error {
i.copyCheck()
if i.isDisposed() {
return nil
}
// TODO: Implement this.
if i.isSubImage() {
panic("ebiten: render to a subimage is not implemented (Fill)")
}
i.resolvePendingPixels(false)
r, g, b, a := clr.RGBA()
rf, gf, bf, af := 0.0, 0.0, 0.0, 0.0
if a > 0 {
rf = float64(r) / float64(a)
gf = float64(g) / float64(a)
bf = float64(b) / float64(a)
af = float64(a) / 0xffff
}
sw, sh := emptyImage.Size()
dw, dh := i.Size()
op := &DrawImageOptions{}
op.GeoM.Scale(float64(dw)/float64(sw), float64(dh)/float64(sh))
op.ColorM.Scale(rf, gf, bf, af)
// TODO: Use the previous composite mode if possible.
if af < 1.0 {
op.CompositeMode = CompositeModeCopy
}
// As Fill will change all the pixels of the image into the same color, all the information for restoring
// will be invalidated.
// TODO: This is a little hacky. Is there a better way?
i.mipmap.resetRestoringState()
i.DrawImage(emptyImage, op)
return nil
}
func (i *Image) disposeMipmaps() {
if i.isDisposed() {
panic("ebiten: the image is already disposed at disposeMipmap")
}
i.mipmap.disposeMipmaps()
}
// 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.
//
// 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
// share the texture atlas with high probability.
//
// For more performance tips, see https://github.com/hajimehoshi/ebiten/wiki/Performance-Tips.
//
// DrawImage always returns nil as of 1.5.0-alpha.
func (i *Image) DrawImage(img *Image, options *DrawImageOptions) error {
i.copyCheck()
if img.isDisposed() {
panic("ebiten: the given image to DrawImage must not be disposed")
}
if i.isDisposed() {
return nil
}
// TODO: Implement this.
if i.isSubImage() {
panic("ebiten: render to a subimage is not implemented (drawImage)")
}
img.resolvePendingPixels(true)
i.resolvePendingPixels(true)
// 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{}
}
parts := options.ImageParts
// Parts is deprecated. This implementations is for backward compatibility.
if parts == nil && options.Parts != nil {
parts = imageParts(options.Parts)
}
// ImageParts is deprecated. This implementations is for backward compatibility.
if parts != nil {
l := parts.Len()
for idx := 0; idx < l; idx++ {
sx0, sy0, sx1, sy1 := parts.Src(idx)
dx0, dy0, dx1, dy1 := parts.Dst(idx)
op := &DrawImageOptions{
ColorM: options.ColorM,
CompositeMode: options.CompositeMode,
Filter: options.Filter,
}
op.GeoM.Scale(
float64(dx1-dx0)/float64(sx1-sx0),
float64(dy1-dy0)/float64(sy1-sy0))
op.GeoM.Translate(float64(dx0), float64(dy0))
op.GeoM.Concat(options.GeoM)
i.DrawImage(img.SubImage(image.Rect(sx0, sy0, sx1, sy1)).(*Image), op)
}
return nil
}
bounds := img.Bounds()
// SourceRect is deprecated. This implementation is for backward compatibility.
if options.SourceRect != nil {
bounds = bounds.Intersect(*options.SourceRect)
if bounds.Empty() {
return nil
}
}
geom := &options.GeoM
mode := driver.CompositeMode(options.CompositeMode)
filter := driver.FilterNearest
if options.Filter != FilterDefault {
filter = driver.Filter(options.Filter)
} else if img.filter != FilterDefault {
filter = driver.Filter(img.filter)
}
a, b, c, d, tx, ty := geom.elements()
level := 0
if filter == driver.FilterLinear && !img.mipmap.original().IsVolatile() {
det := geom.det()
if det == 0 {
return nil
}
if math.IsNaN(float64(det)) {
return nil
}
level = mipmapLevel(det)
if level < 0 {
panic(fmt.Sprintf("ebiten: level must be >= 0 but %d", level))
}
// If the image can be scaled into 0 size, adjust the level. (#839)
w, h := bounds.Dx(), bounds.Dy()
for level >= 0 {
s := 1 << uint(level)
if w/s == 0 || h/s == 0 {
level--
continue
}
break
}
if level < 0 {
// As the render source is too small, nothing is rendered.
return nil
}
}
if level > 6 {
level = 6
}
// TODO: Add (*mipmap).drawImage and move the below code.
colorm := options.ColorM.impl
cr, cg, cb, ca := float32(1), float32(1), float32(1), float32(1)
if colorm.ScaleOnly() {
body, _ := colorm.UnsafeElements()
cr = body[0]
cg = body[5]
cb = body[10]
ca = body[15]
colorm = nil
}
if level == 0 {
src := img.mipmap.original()
vs := vertexSlice(4)
graphics.PutQuadVertices(vs, src, bounds.Min.X, bounds.Min.Y, bounds.Max.X, bounds.Max.Y, a, b, c, d, tx, ty, cr, cg, cb, ca)
is := graphics.QuadIndices()
i.mipmap.original().DrawTriangles(src, vs, is, colorm, mode, filter, driver.AddressClampToZero)
} else if src := img.mipmap.level(bounds, level); src != nil {
w, h := src.Size()
s := 1 << uint(level)
a *= float32(s)
b *= float32(s)
c *= float32(s)
d *= float32(s)
vs := vertexSlice(4)
graphics.PutQuadVertices(vs, src, 0, 0, w, h, a, b, c, d, tx, ty, cr, cg, cb, ca)
is := graphics.QuadIndices()
i.mipmap.original().DrawTriangles(src, vs, is, colorm, mode, filter, driver.AddressClampToZero)
}
i.disposeMipmaps()
return nil
}
// Vertex represents a vertex passed to DrawTriangles.
//
// Note that this API is experimental.
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.
// 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).
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 (
// 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 to render triangles on an image.
//
// Note that this API is experimental.
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.
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 FilterDefault.
Filter Filter
// Address is a sampler address mode.
// The default (zero) value is AddressClampToZero.
Address Address
}
// MaxIndicesNum is the maximum number of indices for DrawTriangles.
const MaxIndicesNum = graphics.IndicesNum
// DrawTriangles draws a triangle with the specified vertices and their indices.
//
// If len(indices) is not multiple of 3, DrawTriangles panics.
//
// If len(indices) is more than MaxIndicesNum, DrawTriangles panics.
//
// The rule in which DrawTriangles works effectively is same as DrawImage's.
//
// When the image i is disposed, DrawTriangles does nothing.
//
// Internal mipmap is not used on DrawTriangles.
//
// Note that this API is experimental.
func (i *Image) DrawTriangles(vertices []Vertex, indices []uint16, img *Image, options *DrawTrianglesOptions) {
i.copyCheck()
if i.isDisposed() {
return
}
if i.isSubImage() {
panic("ebiten: render to a subimage is not implemented (DrawTriangles)")
}
img.resolvePendingPixels(true)
i.resolvePendingPixels(true)
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)?
if options == nil {
options = &DrawTrianglesOptions{}
}
mode := driver.CompositeMode(options.CompositeMode)
filter := driver.FilterNearest
if options.Filter != FilterDefault {
filter = driver.Filter(options.Filter)
} else if img.filter != FilterDefault {
filter = driver.Filter(img.filter)
}
vs := vertexSlice(len(vertices))
src := img.mipmap.original()
r := img.Bounds()
for idx, v := range vertices {
src.PutVertex(vs[idx*graphics.VertexFloatNum:(idx+1)*graphics.VertexFloatNum],
float32(v.DstX), float32(v.DstY), v.SrcX, v.SrcY,
float32(r.Min.X), float32(r.Min.Y), float32(r.Max.X), float32(r.Max.Y),
v.ColorR, v.ColorG, v.ColorB, v.ColorA)
}
i.mipmap.original().DrawTriangles(src, vs, indices, options.ColorM.impl, mode, filter, driver.Address(options.Address))
i.disposeMipmaps()
}
// 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.
//
// In the current Ebiten implementation, SubImage is available only as a rendering source.
func (i *Image) SubImage(r image.Rectangle) image.Image {
i.copyCheck()
if i.isDisposed() {
return nil
}
img := &Image{
mipmap: i.mipmap,
filter: i.filter,
}
// Keep the original image's reference not to dispose that by GC.
if i.isSubImage() {
img.original = i.original
} else {
img.original = i
}
img.addr = img
r = r.Intersect(i.Bounds())
// Need to check Empty explicitly. See the standard image package implementations.
if r.Empty() {
img.bounds = image.ZR
} else {
img.bounds = r
}
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")
}
if !i.isSubImage() {
w, h := i.mipmap.original().Size()
return image.Rect(0, 0, w, h)
}
return i.bounds
}
// ColorModel returns the color model of the image.
func (i *Image) ColorModel() color.Model {
return color.RGBAModel
}
// At returns the color of the image at (x, y).
//
// 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.
//
// Note that important logic should not rely on values returned by At, since
// the returned values can include very slight differences between some machines.
//
// At can't be called outside the main loop (ebiten.Run's updating function) starts (as of version 1.4.0-alpha).
func (i *Image) At(x, y int) color.Color {
if atomic.LoadInt32(&isRunning) == 0 {
panic("ebiten: (*Image).At is not available outside the main loop so far")
}
if i.isDisposed() {
return color.RGBA{}
}
if i.isSubImage() && !image.Pt(x, y).In(i.bounds) {
return color.RGBA{}
}
i.resolvePendingPixels(true)
r, g, b, a := i.mipmap.original().At(x, y)
return color.RGBA{r, g, b, a}
}
// Set sets the color at (x, y).
//
// Set loads pixels from GPU to system memory if necessary, which means that Set can be slow.
//
// Set can't be called outside the main loop (ebiten.Run's updating function) starts.
//
// If the image is disposed, Set does nothing.
func (img *Image) Set(x, y int, clr color.Color) {
if atomic.LoadInt32(&isRunning) == 0 {
panic("ebiten: (*Image).Set is not available outside the main loop so far")
}
img.copyCheck()
if img.isDisposed() {
return
}
if img.isSubImage() && !image.Pt(x, y).In(img.bounds) {
return
}
if img.isSubImage() {
img = img.original
}
w, h := img.Size()
if img.pendingPixels == nil {
pix := make([]byte, 4*w*h)
idx := 0
for j := 0; j < h; j++ {
for i := 0; i < w; i++ {
r, g, b, a := img.mipmap.original().At(i, j)
pix[4*idx] = r
pix[4*idx+1] = g
pix[4*idx+2] = b
pix[4*idx+3] = a
idx++
}
}
img.pendingPixels = pix
}
r, g, b, a := clr.RGBA()
img.pendingPixels[4*(x+y*w)] = byte(r >> 8)
img.pendingPixels[4*(x+y*w)+1] = byte(g >> 8)
img.pendingPixels[4*(x+y*w)+2] = byte(b >> 8)
img.pendingPixels[4*(x+y*w)+3] = byte(a >> 8)
}
func (i *Image) resolvePendingPixels(draw bool) {
if i.isSubImage() {
i.original.resolvePendingPixels(draw)
return
}
if i.pendingPixels == nil {
return
}
if !draw {
i.pendingPixels = nil
return
}
i.ReplacePixels(i.pendingPixels)
i.pendingPixels = nil
}
// Dispose disposes the image data. After disposing, most of image functions do nothing and returns meaningless values.
//
// Dispose is useful to save memory.
//
// When the image is disposed, Dipose does nothing.
//
// Dipose always return nil as of 1.5.0-alpha.
func (i *Image) Dispose() error {
i.copyCheck()
if i.isDisposed() {
return nil
}
if i.isSubImage() {
return nil
}
i.mipmap.dispose()
i.resolvePendingPixels(false)
return nil
}
// ReplacePixels replaces the pixels of the image with p.
//
// The given p must represent RGBA pre-multiplied alpha values. len(p) must equal to 4 * (image width) * (image height).
//
// ReplacePixels may be slow (as for implementation, this calls glTexSubImage2D).
//
// When len(p) is not appropriate, ReplacePixels panics.
//
// When the image is disposed, ReplacePixels does nothing.
//
// ReplacePixels always returns nil as of 1.5.0-alpha.
func (i *Image) ReplacePixels(p []byte) error {
i.copyCheck()
if i.isDisposed() {
return nil
}
// TODO: Implement this.
if i.isSubImage() {
panic("ebiten: render to a subimage is not implemented (ReplacePixels)")
}
i.resolvePendingPixels(false)
s := i.Bounds().Size()
if l := 4 * s.X * s.Y; len(p) != l {
panic(fmt.Sprintf("ebiten: len(p) was %d but must be %d", len(p), l))
}
i.mipmap.original().ReplacePixels(p)
i.disposeMipmaps()
return nil
}
// A DrawImageOptions represents options to render an image on an image.
type DrawImageOptions struct {
// GeoM is a geometry matrix to draw.
// The default (zero) value is identify, 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 FilterDefault.
//
// Filter can also be specified at NewImage* functions, but
// specifying filter at DrawImageOptions is recommended (as of 1.7.0-alpha).
//
// If both Filter specified at NewImage* and DrawImageOptions are FilterDefault,
// FilterNearest is used.
// If either is FilterDefault and the other is not, the latter is used.
// Otherwise, Filter specified at DrawImageOptions is used.
Filter Filter
// Deprecated (as of 1.5.0-alpha): Use SubImage instead.
ImageParts ImageParts
// Deprecated (as of 1.1.0-alpha): Use SubImage instead.
Parts []ImagePart
// Deprecated (as of 1.9.0-alpha): Use SubImage instead.
SourceRect *image.Rectangle
}
// NewImage returns an empty image.
//
// If width or height is less than 1 or more than device-dependent maximum size, NewImage panics.
//
// filter argument is just for backward compatibility.
// If you are not sure, specify FilterDefault.
//
// Error returned by NewImage is always nil as of 1.5.0-alpha.
func NewImage(width, height int, filter Filter) (*Image, error) {
s := shareable.NewImage(width, height)
i := &Image{
mipmap: newMipmap(s),
filter: filter,
}
i.addr = i
return i, nil
}
// makeVolatile makes the image 'volatile'.
// A volatile image is always cleared at the start of a frame.
//
// This is suitable for offscreen images that pixels are changed often.
//
// Regular non-volatile images need to record drawing history or read its pixels from GPU if necessary so that all
// the images can be restored automatically from the context lost. However, such recording the drawing history or
// reading pixels from GPU are expensive operations. Volatile images can skip such oprations, but the image content
// is cleared every frame instead.
//
// When the image is disposed, makeVolatile does nothing.
func (i *Image) makeVolatile() {
if i.isDisposed() {
return
}
i.mipmap.orig.MakeVolatile()
i.disposeMipmaps()
}
// NewImageFromImage creates a new image with the given image (source).
//
// If source's width or height is less than 1 or more than device-dependent maximum size, NewImageFromImage panics.
//
// filter argument is just for backward compatibility.
// If you are not sure, specify FilterDefault.
//
// Error returned by NewImageFromImage is always nil as of 1.5.0-alpha.
func NewImageFromImage(source image.Image, filter Filter) (*Image, error) {
size := source.Bounds().Size()
width, height := size.X, size.Y
s := shareable.NewImage(width, height)
i := &Image{
mipmap: newMipmap(s),
filter: filter,
}
i.addr = i
_ = i.ReplacePixels(copyImage(source))
return i, nil
}
func newImageWithScreenFramebuffer(width, height int) *Image {
i := &Image{
mipmap: newMipmap(shareable.NewScreenFramebufferImage(width, height)),
filter: FilterDefault,
}
i.addr = i
return i
}
// MaxImageSize is deprecated as of 1.7.0-alpha. No replacement so far.
//
// TODO: Make this replacement (#541)
var MaxImageSize = 4096