func checkPsnrs(t *testing.T, ref, img image.Image, sub image.Rectangle, min []float64) {
var a, b image.Image
a, b = ref, img
if !sub.Empty() {
switch a.(type) {
case *image.RGBA:
a = a.(*image.RGBA).SubImage(sub)
b = b.(*image.RGBA).SubImage(sub)
case *image.NRGBA:
a = a.(*image.NRGBA).SubImage(sub)
b = b.(*image.NRGBA).SubImage(sub)
case *image.YCbCr:
a = a.(*image.YCbCr).SubImage(sub)
b = b.(*image.YCbCr).SubImage(sub)
case *image.Gray:
a = a.(*image.Gray).SubImage(sub)
b = b.(*image.Gray).SubImage(sub)
}
}
psnrs, err := Psnr(a, b)
expect(t, err, nil)
for i, v := range psnrs {
if v < min[i] {
t.Fatalf("invalid psnr %v < %v\n", v, min[i])
}
}
}
func (a *area) Repaint(r image.Rectangle) {
r = image.Rect(0, 0, a.width, a.height).Intersect(r)
if r.Empty() {
return
}
C.gtk_widget_queue_draw_area(a.widget, C.gint(r.Min.X), C.gint(r.Min.Y), C.gint(r.Dx()), C.gint(r.Dy()))
}
// SubImage returns an image representing the portion of the image p visible
// through r. The returned value shares pixels with the original image.
func (p *Image) SubImage(r image.Rectangle) image.Image {
// TODO: share code with image.NewYCbCr when this type moves into the
// standard image package.
r = r.Intersect(p.Rect)
// If r1 and r2 are Rectangles, r1.Intersect(r2) is not guaranteed to be inside
// either r1 or r2 if the intersection is empty. Without explicitly checking for
// this, the Pix[i:] expression below can panic.
if r.Empty() {
return &Image{
YCbCr: image.YCbCr{
SubsampleRatio: p.SubsampleRatio,
},
}
}
yi := p.YOffset(r.Min.X, r.Min.Y)
ci := p.COffset(r.Min.X, r.Min.Y)
ai := p.AOffset(r.Min.X, r.Min.Y)
return &Image{
YCbCr: image.YCbCr{
Y: p.Y[yi:],
Cb: p.Cb[ci:],
Cr: p.Cr[ci:],
SubsampleRatio: p.SubsampleRatio,
YStride: p.YStride,
CStride: p.CStride,
Rect: r,
},
A: p.A[ai:],
AStride: p.AStride,
}
}
func (floydSteinberg) Draw(dst Image, r image.Rectangle, src image.Image, sp image.Point) {
clip(dst, &r, src, &sp, nil, nil)
if r.Empty() {
return
}
drawPaletted(dst, r, src, sp, true)
}
//MapImage returns an image surface that is the most efficient mechanism
//for modifying the backing store of this surface.
//
//If r is Empty, the entire surface is mapped, otherwise, just the region
//described by r is mapped.
//
//Note that r is an image.Rectangle and not a cairo.Rectangle.
//
//It is the callers responsibility to all Close on the returned surface
//in order to upload the content of the mapped image to this surface and
//destroys the image surface.
//
//The returned surface is an ImageSurface with a special Close method.
//
//Warning
//
//Using this surface as a target or source while mapped is undefined.
//
//The result of mapping a surface multiple times is undefined.
//
//Changing the device transform of either surface before the image surface
//is unmapped is undefined.
//
//Originally cairo_surface_map_to_image.
func (e *XtensionSurface) MapImage(r image.Rectangle) (MappedImageSurface, error) {
var rect C.cairo_rectangle_int_t
rect.x, rect.y = C.int(r.Min.X), C.int(r.Min.Y)
rect.width, rect.height = C.int(r.Dx()), C.int(r.Dy())
rp := &rect
if r.Empty() {
//use entire image
rp = nil
}
return newMappedImageSurface(C.cairo_surface_map_to_image(e.s, rp), e.s)
}
func (p *RGB) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(p.Rect)
if r.Empty() {
return &RGB{}
}
i := p.PixOffset(r.Min.X, r.Min.Y)
return &RGB{
Pix: p.Pix[i:],
Stride: p.Stride,
Rect: r,
}
}
// FillRect sets each Cell in the Frame within the rectangle r to Cell c.
func (f *Frame) FillRect(r image.Rectangle, c Cell) {
r = f.Bounds.Intersect(r)
if r.Empty() {
return
}
for y := r.Min.Y; y < r.Max.Y; y++ {
for x := r.Min.X; x < r.Max.X; x++ {
f.Set(x, y, c)
}
}
}
// A portion of p specified by r that shares underlying pixels.
func (p *Image64) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(p.Rect)
if r.Empty() {
return &Image64{}
}
i := (r.Min.Y-p.Rect.Min.Y)*p.Stride + (r.Min.X - p.Rect.Min.X)
return &Image64{
Pix: p.Pix[i:],
Stride: p.Stride,
Rect: r,
}
}
// SubFrame returns a Frame bounded by the rectangle r, sharing the data with
// the receiver.
func (f *Frame) SubFrame(r image.Rectangle) *Frame {
r = r.Intersect(f.Bounds)
if r.Empty() {
return new(Frame)
}
return &Frame{
Data: f.Data[f.CellOffset(r.Min.X, r.Min.Y):],
Bounds: r,
Stride: f.Stride,
}
}
func (a *area) Repaint(r image.Rectangle) {
var s C.struct_xrect
r = image.Rect(0, 0, a.width, a.height).Intersect(r)
if r.Empty() {
return
}
s.x = C.intptr_t(r.Min.X)
s.y = C.intptr_t(r.Min.Y)
s.width = C.intptr_t(r.Dx())
s.height = C.intptr_t(r.Dy())
C.areaRepaint(a.id, s)
}
// SubImage returns an image representing the portion of the image p visible
// through r. The returned value shares pixels with the original image.
func (p *ycc) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(p.Rect)
if r.Empty() {
return &ycc{SubsampleRatio: p.SubsampleRatio}
}
i := p.PixOffset(r.Min.X, r.Min.Y)
return &ycc{
Pix: p.Pix[i:],
Stride: p.Stride,
Rect: r,
SubsampleRatio: p.SubsampleRatio,
}
}
// SubImage returns an image representing the portion of the image p visible
// through r. The returned value shares pixels with the original image.
func (p *RGBImage) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(p.XRect)
// If r1 and r2 are Rectangles, r1.Intersect(r2) is not guaranteed to be inside
// either r1 or r2 if the intersection is empty. Without explicitly checking for
// this, the Pix[i:] expression below can panic.
if r.Empty() {
return &RGBImage{}
}
i := p.PixOffset(r.Min.X, r.Min.Y)
return &RGBImage{
XPix: p.XPix[i:],
XStride: p.XStride,
XRect: r,
}
}
// SubImage returns an image representing the portion of the image p visible
// through r. The returned value shares pixels with the original image.
func (p *RGBM64) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(p.Rect)
// If r1 and r2 are Rectangles, r1.Intersect(r2) is not guaranteed to
// be inside either r1 or r2 if the intersection is empty. Without
// explicitly checking for this, the Pix[i:] expression below can
// panic.
if r.Empty() {
return &RGBM64{}
}
i := p.PixOffset(r.Min.X, r.Min.Y)
return &RGBM64{
Pix: p.Pix[i:],
Stride: p.Stride,
Rect: r,
}
}
func (a *area) Repaint(r image.Rectangle) {
var hscroll, vscroll C.int
var rect C.RECT
C.SendMessageW(a.hwnd, C.msgAreaGetScroll, C.WPARAM(uintptr(unsafe.Pointer(&hscroll))), C.LPARAM(uintptr(unsafe.Pointer(&vscroll))))
r = r.Add(image.Pt(int(hscroll), int(vscroll))) // adjust by scroll position
r = image.Rect(0, 0, a.width, a.height).Intersect(r)
if r.Empty() {
return
}
rect.left = C.LONG(r.Min.X)
rect.top = C.LONG(r.Min.Y)
rect.right = C.LONG(r.Max.X)
rect.bottom = C.LONG(r.Max.Y)
C.SendMessageW(a.hwnd, C.msgAreaRepaint, 0, C.LPARAM(uintptr(unsafe.Pointer(&rect))))
}
// SubImage provides a sub image of Image without copying image data.
// N.B. The standard library defines a similar function, but returns an
// image.Image. Here, we return xgraphics.Image so that we can use the extra
// methods defined by xgraphics on it.
//
// This method is cheap to call. It should be used to update only specific
// regions of an X pixmap to avoid sending an entire image to the X server when
// only a piece of it is updated.
//
// Note that if the intersection of `r` and `im` is empty, `nil` is returned.
func (im *Image) SubImage(r image.Rectangle) image.Image {
r = r.Intersect(im.Rect)
if r.Empty() {
return nil
}
i := im.PixOffset(r.Min.X, r.Min.Y)
return &Image{
X: im.X,
Pixmap: im.Pixmap,
Pix: im.Pix[i:],
Stride: im.Stride,
Rect: r,
Subimg: true,
}
}
// SubImage creates a *FloatImg for a region within the original image
// this image is backed by the data in the original image which thus can
// be manipulated by manipulating the sub image
func (p *FloatImg) SubImage(r image.Rectangle) *FloatImg {
r = r.Intersect(p.Rect)
// If r1 and r2 are Rectangles, r1.Intersect(r2) is not guaranteed to be inside
// either r1 or r2 if the intersection is empty. Without explicitly checking for
// this, the Pix[i:] expression below can panic.
if r.Empty() {
return NewFloatImg(r, 0)
}
i := p.PixOffset(r.Min.X, r.Min.Y)
return &FloatImg{
Pix: p.Pix[i:],
Stride: p.Stride,
Rect: r,
Chancnt: p.Chancnt,
ColorFunc: p.ColorFunc,
ColorModelFunc: p.ColorModelFunc}
}
// SubImage returns an image representing the portion of the image p visible through r.
// The returned value shares pixels with the original image.
func (p *Grid) SubGrid(r image.Rectangle) *Grid {
r = r.Intersect(p.Rect)
// If r1 and r2 are image.Rectangles, r1.Intersect(r2) is not guaranteed to be inside
// either r1 or r2 if the intersection is empty. Without explicitly checking for
// this, the Cells[i:] expression below can panic.
if r.Empty() {
return &Grid{}
}
i := p.CellsOffset(r.Min.X, r.Min.Y)
return &Grid{
Tile: p.Tile[i:],
Rot: p.Rot[i:],
Stride: p.Stride,
Rect: r,
CellSize: p.CellSize,
}
}
func (hw *HostWindow) Init(bounds image.Rectangle) {
host_window_class := fmt.Sprintf("www.ustc.edu.cn/gwk/host_window/%p", hw)
var wc WNDCLASSEX
wc.Size = uint32(unsafe.Sizeof(wc))
wc.Style = CS_HREDRAW | CS_VREDRAW
wc.FnWndProc = syscall.NewCallback(host_window_wnd_proc)
wc.ClassExtra = 0
wc.WindowExtra = 0
wc.HInstance = NULL
wc.HIcon, _ = LoadIcon(NULL, MAKEINTRESOURCE(IDI_APPLICATION))
wc.HCursor, _ = LoadCursor(NULL, MAKEINTRESOURCE(IDC_ARROW))
wc.HbrBackground = COLOR_WINDOWFRAME
wc.MenuName = nil
wc.ClassName = syscall.StringToUTF16Ptr(host_window_class)
if _, err := RegisterClassEx(&wc); err != nil {
log.Panicf("RegisterClassEx Failed %v", err)
}
var x, y, width, height int
if bounds.Empty() {
x, y = CW_USEDEFAULT, CW_USEDEFAULT
width, height = CW_USEDEFAULT, CW_USEDEFAULT
} else {
x, y = bounds.Min.X, bounds.Min.Y
width, height = bounds.Dx(), bounds.Dy()
}
hwnd, err := CreateWindowEx(WS_OVERLAPPED,
syscall.StringToUTF16Ptr(host_window_class),
nil,
WS_OVERLAPPEDWINDOW,
x, y, width, height,
NULL, NULL, 0,
uintptr(unsafe.Pointer(hw)))
if err != nil {
log.Panicf("CreateWindowEx Failed: %v", err)
}
hw.hwnd = hwnd
hw.bounds = bounds
}
func (w *windowImpl) Upload(dp image.Point, src screen.Buffer, sr image.Rectangle) {
originalSRMin := sr.Min
sr = sr.Intersect(src.Bounds())
if sr.Empty() {
return
}
dp = dp.Add(sr.Min.Sub(originalSRMin))
// TODO: keep a texture around for this purpose?
t, err := w.s.NewTexture(sr.Size())
if err != nil {
panic(err)
}
t.Upload(image.Point{}, src, sr)
w.Draw(f64.Aff3{
1, 0, float64(dp.X),
0, 1, float64(dp.Y),
}, t, t.Bounds(), draw.Src, nil)
t.Release()
}
func (r *Renderer) stateScissor(rect image.Rectangle) {
// Only if the (final) scissor rectangle has changed do we need to make the
// OpenGL call.
bounds := r.Bounds()
// If the rectangle is empty use the entire area.
if rect.Empty() {
rect = bounds
} else {
// Intersect the rectangle with the renderer's bounds.
rect = bounds.Intersect(rect)
}
if r.last.scissor != rect {
// Store the new scissor rectangle.
r.last.scissor = rect
x, y, width, height := convertRect(rect, bounds)
r.render.Scissor(x, y, width, height)
}
}
// Parallel dispatches tasks concurrently for a Rectangle.
func Parallel(r image.Rectangle, f func(r image.Rectangle)) {
p := runtime.GOMAXPROCS(0)
wg := new(sync.WaitGroup)
h := r.Dy()
for y := 0; y < p; y++ {
r := image.Rect(
r.Min.X,
r.Min.Y+(h*y/p),
r.Max.X,
r.Min.Y+(h*(y+1)/p),
)
if !r.Empty() {
wg.Add(1)
go func(r image.Rectangle) {
f(r)
wg.Done()
}(r)
}
}
wg.Wait()
}
func (q *MedianCutQuantizer) Quantize(dst *image.Paletted, r image.Rectangle, src image.Image, sp image.Point) {
clip(dst, &r, src, &sp)
if r.Empty() {
return
}
points := make([]point, r.Dx()*r.Dy())
colorSet := make(map[uint32]color.Color, q.NumColor)
i := 0
for y := r.Min.Y; y < r.Max.Y; y++ {
for x := r.Min.X; x < r.Max.X; x++ {
c := src.At(x, y)
r, g, b, _ := c.RGBA()
colorSet[(r>>8)<<16|(g>>8)<<8|b>>8] = c
points[i][0] = int(r)
points[i][1] = int(g)
points[i][2] = int(b)
i++
}
}
if len(colorSet) <= q.NumColor {
// No need to quantize since the total number of colors
// fits within the palette.
dst.Palette = make(color.Palette, len(colorSet))
i := 0
for _, c := range colorSet {
dst.Palette[i] = c
i++
}
} else {
dst.Palette = q.medianCut(points)
}
for y := 0; y < r.Dy(); y++ {
for x := 0; x < r.Dx(); x++ {
// TODO: this should be done more efficiently.
dst.Set(sp.X+x, sp.Y+y, src.At(r.Min.X+x, r.Min.Y+y))
}
}
}
func thumbnailRez(imgSrc image.Image, size image.Point, trimmedBounds image.Rectangle) image.Image {
img := ConvertToRGBAIfNecessary(imgSrc)
if !trimmedBounds.Empty() && !trimmedBounds.Eq(img.Bounds()) {
img = img.SubImage(trimmedBounds).(*image.RGBA)
}
b := img.Bounds()
imgSize := image.Point{b.Dx(), b.Dy()}
thumbSize, downscaling := SizePreservingAspect(imgSize, size)
resizedImg := img
if downscaling {
resizedImg = CreateRGBAImageOfSize(thumbSize)
convert(resizedImg, img, false, rez.NewBicubicFilter())
}
dstImg := CreateRGBAImageOfSize(size)
// paint the background
//draw.Draw(dstImg, dstImg.Bounds(), &image.Uniform{bgColor}, image.ZP, draw.Src)
drawCentered(dstImg, resizedImg)
return dstImg
}
func thumbnailNfnt(imgSrc image.Image, size image.Point, trimmedBounds image.Rectangle) image.Image {
img := ConvertToRGBAIfNecessary(imgSrc)
if !trimmedBounds.Empty() && !trimmedBounds.Eq(img.Bounds()) {
img = img.SubImage(trimmedBounds).(*image.RGBA)
}
b := img.Bounds()
imgSize := image.Point{b.Dx(), b.Dy()}
thumbSize, downscaling := SizePreservingAspect(imgSize, size)
var resizedImg image.Image = img
if downscaling {
// resize.Resize returns *image.RGBA64
resizedImg = resize.Resize(uint(thumbSize.X), uint(thumbSize.Y), img, resize.Bilinear)
}
dstImg := CreateRGBAImageOfSize(size)
// paint the background
//draw.Draw(dstImg, dstImg.Bounds(), &image.Uniform{bgColor}, image.ZP, draw.Src)
drawCentered(dstImg, resizedImg)
return dstImg
}
// DrawMask aligns r.Min in dst with sp in src and mp in mask and then replaces the rectangle r
// in dst with the result of a Porter-Duff composition. A nil mask is treated as opaque.
func DrawMask(dst Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, op Op) {
clip(dst, &r, src, &sp, mask, &mp)
if r.Empty() {
return
}
// Fast paths for special cases. If none of them apply, then we fall back to a general but slow implementation.
switch dst0 := dst.(type) {
case *image.RGBA:
if op == Over {
if mask == nil {
switch src0 := src.(type) {
case *image.Uniform:
drawFillOver(dst0, r, src0)
return
case *image.RGBA:
drawCopyOver(dst0, r, src0, sp)
return
case *image.NRGBA:
drawNRGBAOver(dst0, r, src0, sp)
return
case *image.YCbCr:
if drawYCbCr(dst0, r, src0, sp) {
return
}
}
} else if mask0, ok := mask.(*image.Alpha); ok {
switch src0 := src.(type) {
case *image.Uniform:
drawGlyphOver(dst0, r, src0, mask0, mp)
return
}
}
} else {
if mask == nil {
switch src0 := src.(type) {
case *image.Uniform:
drawFillSrc(dst0, r, src0)
return
case *image.RGBA:
drawCopySrc(dst0, r, src0, sp)
return
case *image.NRGBA:
drawNRGBASrc(dst0, r, src0, sp)
return
case *image.YCbCr:
if drawYCbCr(dst0, r, src0, sp) {
return
}
}
}
}
drawRGBA(dst0, r, src, sp, mask, mp, op)
return
case *image.Paletted:
if op == Src && mask == nil && !processBackward(dst, r, src, sp) {
drawPaletted(dst0, r, src, sp, false)
}
}
x0, x1, dx := r.Min.X, r.Max.X, 1
y0, y1, dy := r.Min.Y, r.Max.Y, 1
if processBackward(dst, r, src, sp) {
x0, x1, dx = x1-1, x0-1, -1
y0, y1, dy = y1-1, y0-1, -1
}
var out color.RGBA64
sy := sp.Y + y0 - r.Min.Y
my := mp.Y + y0 - r.Min.Y
for y := y0; y != y1; y, sy, my = y+dy, sy+dy, my+dy {
sx := sp.X + x0 - r.Min.X
mx := mp.X + x0 - r.Min.X
for x := x0; x != x1; x, sx, mx = x+dx, sx+dx, mx+dx {
ma := uint32(m)
if mask != nil {
_, _, _, ma = mask.At(mx, my).RGBA()
}
switch {
case ma == 0:
if op == Over {
// No-op.
} else {
dst.Set(x, y, color.Transparent)
}
case ma == m && op == Src:
dst.Set(x, y, src.At(sx, sy))
default:
sr, sg, sb, sa := src.At(sx, sy).RGBA()
if op == Over {
dr, dg, db, da := dst.At(x, y).RGBA()
a := m - (sa * ma / m)
out.R = uint16((dr*a + sr*ma) / m)
out.G = uint16((dg*a + sg*ma) / m)
out.B = uint16((db*a + sb*ma) / m)
out.A = uint16((da*a + sa*ma) / m)
} else {
out.R = uint16(sr * ma / m)
out.G = uint16(sg * ma / m)
out.B = uint16(sb * ma / m)
out.A = uint16(sa * ma / m)
}
// The third argument is &out instead of out (and out is
// declared outside of the inner loop) to avoid the implicit
// conversion to color.Color here allocating memory in the
// inner loop if sizeof(color.RGBA64) > sizeof(uintptr).
dst.Set(x, y, &out)
}
}
}
}
// DrawMask aligns r.Min in dst with sp in src and mp in mask and then replaces the rectangle r
// in dst with the result of a Porter-Duff composition. A nil mask is treated as opaque.
func DrawMask(dst Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, op Op) {
clip(dst, &r, src, &sp, mask, &mp)
if r.Empty() {
return
}
// Fast paths for special cases. If none of them apply, then we fall back to a general but slow implementation.
if dst0, ok := dst.(*image.RGBA); ok {
if op == Over {
if mask == nil {
switch src0 := src.(type) {
case *image.ColorImage:
drawFillOver(dst0, r, src0)
return
case *image.RGBA:
drawCopyOver(dst0, r, src0, sp)
return
case *image.NRGBA:
drawNRGBAOver(dst0, r, src0, sp)
return
case *ycbcr.YCbCr:
drawYCbCr(dst0, r, src0, sp)
return
}
} else if mask0, ok := mask.(*image.Alpha); ok {
switch src0 := src.(type) {
case *image.ColorImage:
drawGlyphOver(dst0, r, src0, mask0, mp)
return
}
}
} else {
if mask == nil {
switch src0 := src.(type) {
case *image.ColorImage:
drawFillSrc(dst0, r, src0)
return
case *image.RGBA:
drawCopySrc(dst0, r, src0, sp)
return
case *image.NRGBA:
drawNRGBASrc(dst0, r, src0, sp)
return
case *ycbcr.YCbCr:
drawYCbCr(dst0, r, src0, sp)
return
}
}
}
drawRGBA(dst0, r, src, sp, mask, mp, op)
return
}
x0, x1, dx := r.Min.X, r.Max.X, 1
y0, y1, dy := r.Min.Y, r.Max.Y, 1
if image.Image(dst) == src && r.Overlaps(r.Add(sp.Sub(r.Min))) {
// Rectangles overlap: process backward?
if sp.Y < r.Min.Y || sp.Y == r.Min.Y && sp.X < r.Min.X {
x0, x1, dx = x1-1, x0-1, -1
y0, y1, dy = y1-1, y0-1, -1
}
}
var out *image.RGBA64Color
sy := sp.Y + y0 - r.Min.Y
my := mp.Y + y0 - r.Min.Y
for y := y0; y != y1; y, sy, my = y+dy, sy+dy, my+dy {
sx := sp.X + x0 - r.Min.X
mx := mp.X + x0 - r.Min.X
for x := x0; x != x1; x, sx, mx = x+dx, sx+dx, mx+dx {
ma := uint32(m)
if mask != nil {
_, _, _, ma = mask.At(mx, my).RGBA()
}
switch {
case ma == 0:
if op == Over {
// No-op.
} else {
dst.Set(x, y, zeroColor)
}
case ma == m && op == Src:
dst.Set(x, y, src.At(sx, sy))
default:
sr, sg, sb, sa := src.At(sx, sy).RGBA()
if out == nil {
out = new(image.RGBA64Color)
}
if op == Over {
dr, dg, db, da := dst.At(x, y).RGBA()
a := m - (sa * ma / m)
out.R = uint16((dr*a + sr*ma) / m)
out.G = uint16((dg*a + sg*ma) / m)
out.B = uint16((db*a + sb*ma) / m)
out.A = uint16((da*a + sa*ma) / m)
} else {
out.R = uint16(sr * ma / m)
out.G = uint16(sg * ma / m)
out.B = uint16(sb * ma / m)
out.A = uint16(sa * ma / m)
}
dst.Set(x, y, out)
}
}
}
}
func drawMask(d drawer, dst draw.Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, protectAlpha bool) {
clip(dst, &r, src, &sp, mask, &mp)
if r.Empty() {
return
}
switch dst0 := dst.(type) {
case *image.RGBA:
if mask == nil {
switch src0 := src.(type) {
case *image.RGBA:
d.drawRGBAToRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
case *image.NRGBA:
d.drawNRGBAToRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
}
} else {
switch mask0 := mask.(type) {
case *image.Uniform:
switch src0 := src.(type) {
case *image.RGBA:
d.drawRGBAToRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
case *image.NRGBA:
d.drawNRGBAToRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
}
}
}
case *image.NRGBA:
if mask == nil {
switch src0 := src.(type) {
case *image.RGBA:
d.drawRGBAToNRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
case *image.NRGBA:
d.drawNRGBAToNRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
}
} else {
switch mask0 := mask.(type) {
case *image.Uniform:
switch src0 := src.(type) {
case *image.RGBA:
d.drawRGBAToNRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
case *image.NRGBA:
d.drawNRGBAToNRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
}
}
}
}
if ad, ok := d.(alphaDrawer); ok {
switch dst0 := dst.(type) {
case *image.RGBA:
if mask == nil {
switch src0 := src.(type) {
case *image.Alpha:
ad.drawAlphaToRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
}
} else {
switch mask0 := mask.(type) {
case *image.Uniform:
switch src0 := src.(type) {
case *image.Alpha:
ad.drawAlphaToRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
}
}
}
case *image.NRGBA:
if mask == nil {
switch src0 := src.(type) {
case *image.Alpha:
ad.drawAlphaToNRGBAUniform(dst0, r, src0, sp, nil, protectAlpha)
return
}
} else {
switch mask0 := mask.(type) {
case *image.Uniform:
switch src0 := src.(type) {
case *image.Alpha:
ad.drawAlphaToNRGBAUniform(dst0, r, src0, sp, mask0, protectAlpha)
return
}
}
}
}
}
d.drawFallback(dst, r, src, sp, mask, mp, protectAlpha)
}
func (m *markedImage) Transform(crop image.Rectangle, width, height uint, dontenlarge bool, format string, resample resize.InterpolationFunction) (Image, error) {
novaFoto, err := m.Copy()
if err != nil {
return nil, e.Forward(err)
}
img, err := novaFoto.Image()
if err != nil {
return nil, e.Forward(err)
}
if width > math.MaxInt32 {
return nil, e.New("width is big")
}
if height > math.MaxInt32 {
return nil, e.New("height is big")
}
bounds, err := m.Bounds()
if err != nil {
return nil, e.Forward(err)
}
w := bounds.Dx()
h := bounds.Dy()
f, err := m.Format()
if err != nil {
return nil, e.Forward(err)
}
if crop.Empty() && ((width == 0 && height == 0) || (int(width) == w && int(height) == h)) && (format == "" || format == f) {
return novaFoto, nil
}
if !crop.Empty() {
sub, ok := img.(SubImager)
if !ok {
return nil, e.New("this image type don't support cropping")
}
img = sub.SubImage(crop)
}
imgResized := img
if !(width == 0 && height == 0) {
rect := img.Bounds()
w := uint(rect.Max.X - rect.Min.X)
h := uint(rect.Max.Y - rect.Min.Y)
imgRatio := img
if width > 0 && height > 0 {
ratio := round.RoundDec32(float32(w)/float32(h), 1)
newRatio := round.RoundDec32(float32(width)/float32(height), 1)
if ratio != newRatio {
//TODO: se imagem tem largura menor que 10px não vai funcionar
imgRatio, err = cutter.Crop(img, cutter.Config{
Width: int(newRatio * 10.0),
Height: 10,
Mode: cutter.Centered,
Options: cutter.Ratio,
})
if err != nil {
return nil, e.Push(err, "can't crop the image")
}
rect = imgRatio.Bounds()
w = uint(rect.Max.X - rect.Min.X)
h = uint(rect.Max.Y - rect.Min.Y)
}
}
imgResized = imgRatio
if (width >= w || height >= h) && !dontenlarge {
imgResized = resize.Resize(width, height, imgRatio, resample)
} else if width < w && height < h {
imgResized = resize.Resize(width, height, imgRatio, resample)
}
}
// rect := imgResized.Bounds()
// novaFoto.Width_ = rect.Max.X - rect.Min.X
// novaFoto.Height_ = rect.Max.Y - rect.Min.Y
b := make([]byte, 0, 1024*1024*5)
buf := bytes.NewBuffer(b)
// if format == "" {
// format = novaFoto.Mime_
// }
switch format {
// case "image/bmp", "image/x-windows-bmp":
// err := bmp.Encode(buf, imgResized)
// if err != nil {
// return nil, e.Forward(err)
// }
// novaFoto.Format_ = "bmp"
// case "image/gif":
// opt := &gif.Options{
// NumColors: 256,
// }
// err := gif.Encode(buf, imgResized, opt)
// if err != nil {
// return nil, e.Forward(err)
// }
// novaFoto.Format_ = "gif"
case "image/jpeg":
opt := &jpeg.Options{
Quality: Quality,
}
err := jpeg.Encode(buf, imgResized, opt)
if err != nil {
return nil, e.Forward(err)
}
//novaFoto.Format_ = "jpeg"
// case "image/png":
// err := png.Encode(buf, imgResized)
// if err != nil {
// return nil, e.Forward(err)
// }
// novaFoto.Format_ = "png"
// case "image/tiff", "image/x-tiff":
// opt := &tiff.Options{
// Compression: tiff.Deflate,
// Predictor: true,
// }
// err := tiff.Encode(buf, imgResized, opt)
// if err != nil {
// return nil, e.Forward(err)
// }
// novaFoto.Format_ = "tiff"
default:
return nil, e.New("image format isn't supported")
}
// novaFoto.Mime_ = format
// novaFoto.FileSize_ = int64(buf.Len())
// novaFoto.Data = buf.Bytes()
return novaFoto, nil
}
func DrawMask(dst draw.Image, r image.Rectangle, src image.Image, sp image.Point, mask image.Image, mp image.Point, op draw.Op) {
clip(dst, &r, src, &sp, mask, &mp)
if r.Empty() {
return
}
if dst0, ok := dst.(*BGRA); ok {
if op == draw.Over {
if mask == nil {
switch src0 := src.(type) {
case *image.Uniform:
drawFillOver(dst0, r, src0)
return
case *image.RGBA:
drawRGBAOver(dst0, r, src0, sp)
return
case *BGRA:
drawCopyOver(dst0, r, src0, sp)
return
}
} else if mask0, ok := mask.(*image.Alpha); ok {
switch src0 := src.(type) {
case *image.Uniform:
drawGlyphOver(dst0, r, src0, mask0, mp)
return
}
}
} else {
if mask == nil {
switch src0 := src.(type) {
case *image.Uniform:
drawFillSrc(dst0, r, src0)
return
case *image.RGBA:
drawRGBASrc(dst0, r, src0, sp)
return
case *BGRA:
drawCopySrc(dst0, r, src0, sp)
return
}
}
}
drawBGRA(dst0, r, src, sp, mask, mp, op)
return
} else if dst0, ok := dst.(*image.RGBA); ok {
if src0, ok := dst.(*BGRA); ok {
if op == draw.Over {
if mask == nil {
drawRGBADstOver(dst0, r, src0, sp)
return
}
} else {
if mask == nil {
drawRGBADst(dst0, r, src0, sp)
return
}
}
}
}
draw.DrawMask(dst, r, src, sp, mask, mp, op)
}
func Paint(w wde.Window, rect image.Rectangle) {
xOffset, yOffset := GetTopLeft()
center := layout.Coord{ViewportWidth/2 - xOffset, ViewportHeight/2 - yOffset}
if center != oldCenter || layout.Version() != oldVersion {
oldCenter = center
oldVersion = layout.Version()
for x := 0; x <= ViewportWidth; x++ {
for y := 0; y <= ViewportHeight; y++ {
if layout.Visible(center, layout.Coord{x - xOffset, y - yOffset}) {
res.Tile(terrain, res.Terrain, uint16(layout.GetSpace(x-xOffset, y-yOffset)), x, y)
draw.Draw(terrain, image.Rect(x<<res.TileSize, y<<res.TileSize, (x+1)<<res.TileSize, (y+1)<<res.TileSize), image.Transparent, image.ZP, draw.Src)
for _, t := range layout.Get(x-xOffset, y-yOffset) {
if !t.NoClient() {
res.Tile(terrain, res.Terrain, uint16(t), x, y)
}
}
} else {
res.Tile(terrain, image.Black, 0, x, y)
}
}
}
switch GetPlayerFlags() & packet.FlagSpriteMask {
case packet.FlagEngineer:
for x := 0; x <= ViewportWidth; x++ {
for y := 0; y <= ViewportHeight; y++ {
dx, dy := x-ViewportWidth/2, y-ViewportHeight/2
dist := dx*dx + dy*dy
if dist <= 3*3 && layout.Visible(center, layout.Coord{x - xOffset, y - yOffset}) {
for _, t := range layout.Get(x-xOffset, y-yOffset) {
if t >= layout.WireW && t <= layout.WireS {
res.Tile(terrain, res.Terrain, uint16(t), x, y)
}
}
}
}
}
}
}
minX, maxX := rect.Min.X>>res.TileSize, (rect.Max.X-1)>>res.TileSize+1
minY, maxY := rect.Min.Y>>res.TileSize, (rect.Max.Y-1)>>res.TileSize+1
draw.Draw(sprites, sprites.Bounds(), image.Transparent, image.ZP, draw.Src)
var pixOffset image.Point
var hasAnimation image.Rectangle
paintLock.Lock()
for _, p := range paintContexts {
if layout.Visible(center, p.To) {
x1, y1 := p.From.X+xOffset, p.From.Y+yOffset
x2, y2 := p.To.X+xOffset, p.To.Y+yOffset
if minX <= x2 && x2 <= maxX && minY <= y2 && y2 <= maxY {
interp := float32(time.Since(p.Changed)*5) / float32(time.Second)
if interp >= 1 {
res.Tile(sprites, res.Actors, p.Sprite, x2, y2)
} else {
toInvalidate := image.Rect(x1, y1, x1+1, y1+1).Union(image.Rect(x2, y2, x2+1, y2+1))
if hasAnimation.Empty() {
hasAnimation = toInvalidate
} else {
hasAnimation = hasAnimation.Union(toInvalidate)
}
if p == thePlayer.paint {
pixOffset.X = int(float32((x1-x2)<<res.TileSize) * (1 - interp))
pixOffset.Y = int(float32((y1-y2)<<res.TileSize) * (1 - interp))
hasAnimation = viewport.Bounds()
}
res.TileFloat(sprites, res.Actors, p.Sprite, x1, y1, x2, y2, interp)
}
}
}
}
paintLock.Unlock()
draw.Draw(viewport, rect, terrain, rect.Min.Add(pixOffset), draw.Src)
draw.Draw(viewport, rect, sprites, rect.Min.Add(pixOffset), draw.Over)
draw.DrawMask(viewport, rect, image.Black, image.ZP, light.Image(-xOffset, -yOffset), rect.Min.Add(light.Origin(-xOffset, -yOffset)).Add(pixOffset), draw.Over)
if image.Rect(0, 0, 1, 1).Overlaps(rect) {
mouseTileLock.Lock()
res.DrawString(viewport, mouseTileString, color.White, res.FontSmall, 1, 1)
mouseTileLock.Unlock()
}
if !hasAnimation.Empty() {
Invalidate(image.Rectangle{hasAnimation.Min.Mul(1 << res.TileSize), hasAnimation.Max.Mul(1 << res.TileSize)})
}
paints++
/* // For debugging paints
res.DrawString(viewport, strconv.FormatUint(paints, 10), color.White, res.FontSmall, 300, 1)
draw.Draw(viewport, image.Rectangle{rect.Min, image.Pt(rect.Max.X+1, rect.Min.Y+1)}, image.White, image.ZP, draw.Src)
draw.Draw(viewport, image.Rectangle{image.Pt(rect.Min.X-1, rect.Max.Y-1), rect.Max}, image.White, image.ZP, draw.Src)
draw.Draw(viewport, image.Rectangle{rect.Min, image.Pt(rect.Min.X+1, rect.Max.Y+1)}, image.White, image.ZP, draw.Src)
draw.Draw(viewport, image.Rectangle{image.Pt(rect.Max.X-1, rect.Min.Y-1), rect.Max}, image.White, image.ZP, draw.Src)
//*/
w.Screen().CopyRGBA(viewport, viewport.Bounds())
w.FlushImage(rect)
}