func (e *engine) render(n *sprite.Node, t clock.Time) {
if n.EngineFields.Index == 0 {
panic("portable: sprite.Node not registered")
}
if n.Arranger != nil {
n.Arranger.Arrange(e, n, t)
}
// Push absTransforms.
// TODO: cache absolute transforms and use EngineFields.Dirty?
rel := &e.nodes[n.EngineFields.Index].relTransform
m := f32.Affine{}
m.Mul(&e.absTransforms[len(e.absTransforms)-1], rel)
e.absTransforms = append(e.absTransforms, m)
if x := n.EngineFields.SubTex; x.T != nil {
// Affine transforms work in geom.Pt, which is entirely
// independent of the number of pixels in a texture. A texture
// of any image.Rectangle bounds rendered with
//
// Affine{{1, 0, 0}, {0, 1, 0}}
//
// should have the dimensions (1pt, 1pt). To do this we divide
// by the pixel width and height, reducing the texture to
// (1px, 1px) of the destination image. Multiplying by
// sz.PixelsPerPt, done in Render above, makes it (1pt, 1pt).
dx, dy := x.R.Dx(), x.R.Dy()
if dx > 0 && dy > 0 {
m.Scale(&m, 1/float32(dx), 1/float32(dy))
// TODO(nigeltao): delete the double-inverse: one here and one
// inside func affine.
m.Inverse(&m) // See the documentation on the affine function.
affine(e.dst, x.T.(*texture).m, x.R, nil, &m, draw.Over)
}
}
for c := n.FirstChild; c != nil; c = c.NextSibling {
e.render(c, t)
}
// Pop absTransforms.
e.absTransforms = e.absTransforms[:len(e.absTransforms)-1]
}
func TestAffine(t *testing.T) {
f, err := os.Open("../../../testdata/testpattern.png")
if err != nil {
t.Fatal(err)
}
defer f.Close()
srcOrig, _, err := image.Decode(f)
if err != nil {
t.Fatal(err)
}
src := image.NewRGBA(srcOrig.Bounds())
draw.Draw(src, src.Rect, srcOrig, srcOrig.Bounds().Min, draw.Src)
const (
pixW = 100
pixH = 100
ptW = geom.Pt(50)
ptH = geom.Pt(50)
)
sz := size.Event{
WidthPx: pixW,
HeightPx: pixH,
WidthPt: ptW,
HeightPt: ptH,
PixelsPerPt: float32(pixW) / float32(ptW),
}
got := image.NewRGBA(image.Rect(0, 0, pixW, pixH))
blue := image.NewUniform(color.RGBA{B: 0xff, A: 0xff})
draw.Draw(got, got.Bounds(), blue, image.Point{}, draw.Src)
b := src.Bounds()
b.Min.X += 10
b.Max.Y /= 2
var a f32.Affine
a.Identity()
a.Scale(&a, sz.PixelsPerPt, sz.PixelsPerPt)
a.Translate(&a, 0, 24)
a.Rotate(&a, float32(math.Asin(12./20)))
// See commentary in the render method defined in portable.go.
a.Scale(&a, 40/float32(b.Dx()), 20/float32(b.Dy()))
a.Inverse(&a)
affine(got, src, b, nil, &a, draw.Over)
ptTopLeft := geom.Point{0, 24}
ptBottomRight := geom.Point{12 + 32, 16}
drawCross(got, 0, 0)
drawCross(got, int(ptTopLeft.X.Px(sz.PixelsPerPt)), int(ptTopLeft.Y.Px(sz.PixelsPerPt)))
drawCross(got, int(ptBottomRight.X.Px(sz.PixelsPerPt)), int(ptBottomRight.Y.Px(sz.PixelsPerPt)))
drawCross(got, pixW-1, pixH-1)
const wantPath = "../../../testdata/testpattern-window.png"
f, err = os.Open(wantPath)
if err != nil {
t.Fatal(err)
}
defer f.Close()
wantSrc, _, err := image.Decode(f)
if err != nil {
t.Fatal(err)
}
want, ok := wantSrc.(*image.RGBA)
if !ok {
b := wantSrc.Bounds()
want = image.NewRGBA(b)
draw.Draw(want, b, wantSrc, b.Min, draw.Src)
}
if !imageEq(got, want) {
gotPath, err := writeTempPNG("testpattern-window-got", got)
if err != nil {
t.Fatal(err)
}
t.Errorf("got\n%s\nwant\n%s", gotPath, wantPath)
}
}