mirror of
https://git.sr.ht/~eliasnaur/gio
synced 2026-07-01 07:35:40 +00:00
89ab5ebf4f
Rename all resource release methods to "Release", and release all resources with a slice and loop. Signed-off-by: Elias Naur <mail@eliasnaur.com>
1432 lines
38 KiB
Go
1432 lines
38 KiB
Go
// SPDX-License-Identifier: Unlicense OR MIT
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/*
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Package gpu implements the rendering of Gio drawing operations. It
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is used by package app and package app/headless and is otherwise not
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useful except for integrating with external window implementations.
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*/
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package gpu
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import (
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"encoding/binary"
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"errors"
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"fmt"
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"image"
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"image/color"
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"math"
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"os"
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"reflect"
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"time"
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"unsafe"
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"gioui.org/f32"
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"gioui.org/gpu/internal/driver"
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"gioui.org/internal/byteslice"
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"gioui.org/internal/f32color"
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"gioui.org/internal/opconst"
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"gioui.org/internal/ops"
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"gioui.org/internal/scene"
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"gioui.org/internal/stroke"
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"gioui.org/layout"
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"gioui.org/op"
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"gioui.org/op/clip"
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// Register backends.
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_ "gioui.org/gpu/internal/d3d11"
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_ "gioui.org/gpu/internal/opengl"
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)
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type GPU interface {
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// Release non-Go resources. The GPU is no longer valid after Release.
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Release()
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// Clear sets the clear color for the next Frame.
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Clear(color color.NRGBA)
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// Collect the graphics operations from frame, given the viewport.
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Collect(viewport image.Point, frame *op.Ops)
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// Frame clears the color buffer and draws the collected operations.
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Frame() error
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// Profile returns the last available profiling information. Profiling
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// information is requested when Collect sees a ProfileOp, and the result
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// is available through Profile at some later time.
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Profile() string
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}
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type gpu struct {
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cache *resourceCache
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profile string
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timers *timers
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frameStart time.Time
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zopsTimer, stencilTimer, coverTimer, cleanupTimer *timer
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drawOps drawOps
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ctx driver.Device
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renderer *renderer
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}
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type renderer struct {
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ctx driver.Device
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blitter *blitter
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pather *pather
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packer packer
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intersections packer
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}
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type drawOps struct {
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profile bool
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reader ops.Reader
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states []drawState
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cache *resourceCache
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vertCache []byte
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viewport image.Point
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clear bool
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clearColor f32color.RGBA
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imageOps []imageOp
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// zimageOps are the rectangle clipped opaque images
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// that can use fast front-to-back rendering with z-test
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// and no blending.
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zimageOps []imageOp
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pathOps []*pathOp
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pathOpCache []pathOp
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qs quadSplitter
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pathCache *opCache
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}
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type drawState struct {
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clip f32.Rectangle
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t f32.Affine2D
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cpath *pathOp
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rect bool
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matType materialType
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// Current paint.ImageOp
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image imageOpData
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// Current paint.ColorOp, if any.
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color color.NRGBA
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// Current paint.LinearGradientOp.
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stop1 f32.Point
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stop2 f32.Point
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color1 color.NRGBA
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color2 color.NRGBA
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}
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type pathOp struct {
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off f32.Point
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// clip is the union of all
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// later clip rectangles.
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clip image.Rectangle
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bounds f32.Rectangle
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pathKey opKey
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path bool
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pathVerts []byte
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parent *pathOp
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place placement
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}
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type imageOp struct {
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z float32
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path *pathOp
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clip image.Rectangle
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material material
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clipType clipType
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place placement
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}
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func decodeStrokeOp(data []byte) clip.StrokeStyle {
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_ = data[4]
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if opconst.OpType(data[0]) != opconst.TypeStroke {
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panic("invalid op")
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}
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bo := binary.LittleEndian
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return clip.StrokeStyle{
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Width: math.Float32frombits(bo.Uint32(data[1:])),
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}
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}
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type quadsOp struct {
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key opKey
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aux []byte
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}
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type opKey struct {
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sx, hx, sy, hy float32
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ops.Key
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}
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type material struct {
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material materialType
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opaque bool
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// For materialTypeColor.
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color f32color.RGBA
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// For materialTypeLinearGradient.
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color1 f32color.RGBA
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color2 f32color.RGBA
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// For materialTypeTexture.
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data imageOpData
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uvTrans f32.Affine2D
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}
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// clipOp is the shadow of clip.Op.
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type clipOp struct {
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// TODO: Use image.Rectangle?
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bounds f32.Rectangle
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outline bool
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}
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// imageOpData is the shadow of paint.ImageOp.
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type imageOpData struct {
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src *image.RGBA
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handle interface{}
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}
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type linearGradientOpData struct {
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stop1 f32.Point
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color1 color.NRGBA
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stop2 f32.Point
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color2 color.NRGBA
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}
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func (op *clipOp) decode(data []byte) {
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if opconst.OpType(data[0]) != opconst.TypeClip {
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panic("invalid op")
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}
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bo := binary.LittleEndian
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r := image.Rectangle{
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Min: image.Point{
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X: int(int32(bo.Uint32(data[1:]))),
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Y: int(int32(bo.Uint32(data[5:]))),
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},
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Max: image.Point{
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X: int(int32(bo.Uint32(data[9:]))),
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Y: int(int32(bo.Uint32(data[13:]))),
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},
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}
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*op = clipOp{
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bounds: layout.FRect(r),
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outline: data[17] == 1,
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}
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}
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func decodeImageOp(data []byte, refs []interface{}) imageOpData {
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if opconst.OpType(data[0]) != opconst.TypeImage {
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panic("invalid op")
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}
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handle := refs[1]
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if handle == nil {
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return imageOpData{}
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}
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return imageOpData{
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src: refs[0].(*image.RGBA),
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handle: handle,
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}
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}
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func decodeColorOp(data []byte) color.NRGBA {
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if opconst.OpType(data[0]) != opconst.TypeColor {
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panic("invalid op")
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}
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return color.NRGBA{
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R: data[1],
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G: data[2],
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B: data[3],
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A: data[4],
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}
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}
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func decodeLinearGradientOp(data []byte) linearGradientOpData {
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if opconst.OpType(data[0]) != opconst.TypeLinearGradient {
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panic("invalid op")
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}
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bo := binary.LittleEndian
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return linearGradientOpData{
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stop1: f32.Point{
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X: math.Float32frombits(bo.Uint32(data[1:])),
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Y: math.Float32frombits(bo.Uint32(data[5:])),
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},
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stop2: f32.Point{
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X: math.Float32frombits(bo.Uint32(data[9:])),
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Y: math.Float32frombits(bo.Uint32(data[13:])),
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},
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color1: color.NRGBA{
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R: data[17+0],
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G: data[17+1],
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B: data[17+2],
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A: data[17+3],
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},
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color2: color.NRGBA{
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R: data[21+0],
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G: data[21+1],
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B: data[21+2],
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A: data[21+3],
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},
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}
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}
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type clipType uint8
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type resource interface {
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release()
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}
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type texture struct {
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src *image.RGBA
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tex driver.Texture
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}
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type blitter struct {
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ctx driver.Device
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viewport image.Point
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prog [3]*program
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layout driver.InputLayout
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colUniforms *blitColUniforms
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texUniforms *blitTexUniforms
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linearGradientUniforms *blitLinearGradientUniforms
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quadVerts driver.Buffer
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}
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type blitColUniforms struct {
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vert struct {
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blitUniforms
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_ [12]byte // Padding to a multiple of 16.
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}
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frag struct {
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colorUniforms
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}
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}
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type blitTexUniforms struct {
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vert struct {
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blitUniforms
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_ [12]byte // Padding to a multiple of 16.
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}
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}
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type blitLinearGradientUniforms struct {
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vert struct {
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blitUniforms
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_ [12]byte // Padding to a multiple of 16.
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}
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frag struct {
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gradientUniforms
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}
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}
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type uniformBuffer struct {
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buf driver.Buffer
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ptr []byte
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}
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type program struct {
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prog driver.Program
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vertUniforms *uniformBuffer
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fragUniforms *uniformBuffer
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}
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type blitUniforms struct {
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transform [4]float32
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uvTransformR1 [4]float32
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uvTransformR2 [4]float32
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z float32
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}
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type colorUniforms struct {
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color f32color.RGBA
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}
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type gradientUniforms struct {
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color1 f32color.RGBA
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color2 f32color.RGBA
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}
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type materialType uint8
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const (
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clipTypeNone clipType = iota
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clipTypePath
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clipTypeIntersection
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)
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const (
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materialColor materialType = iota
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materialLinearGradient
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materialTexture
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)
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func New(api API) (GPU, error) {
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d, err := driver.NewDevice(api)
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if err != nil {
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return nil, err
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}
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d.BeginFrame(false, image.Point{})
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defer d.EndFrame()
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forceCompute := os.Getenv("GIORENDERER") == "forcecompute"
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feats := d.Caps().Features
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switch {
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case !forceCompute && feats.Has(driver.FeatureFloatRenderTargets):
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return newGPU(d)
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case feats.Has(driver.FeatureCompute):
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return newCompute(d)
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default:
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return nil, errors.New("gpu: no support for float render targets nor compute")
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}
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}
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func newGPU(ctx driver.Device) (*gpu, error) {
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g := &gpu{
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cache: newResourceCache(),
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}
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g.drawOps.pathCache = newOpCache()
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if err := g.init(ctx); err != nil {
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return nil, err
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}
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return g, nil
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}
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func (g *gpu) init(ctx driver.Device) error {
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g.ctx = ctx
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g.renderer = newRenderer(ctx)
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return nil
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}
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func (g *gpu) Clear(col color.NRGBA) {
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g.drawOps.clear = true
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g.drawOps.clearColor = f32color.LinearFromSRGB(col)
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}
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func (g *gpu) Release() {
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g.renderer.release()
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g.drawOps.pathCache.release()
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g.cache.release()
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if g.timers != nil {
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g.timers.Release()
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}
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g.ctx.Release()
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}
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func (g *gpu) Collect(viewport image.Point, frameOps *op.Ops) {
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g.renderer.blitter.viewport = viewport
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g.renderer.pather.viewport = viewport
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g.drawOps.reset(g.cache, viewport)
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g.drawOps.collect(g.ctx, g.cache, frameOps, viewport)
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g.frameStart = time.Now()
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if g.drawOps.profile && g.timers == nil && g.ctx.Caps().Features.Has(driver.FeatureTimers) {
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g.timers = newTimers(g.ctx)
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g.zopsTimer = g.timers.newTimer()
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g.stencilTimer = g.timers.newTimer()
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g.coverTimer = g.timers.newTimer()
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g.cleanupTimer = g.timers.newTimer()
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}
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}
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func (g *gpu) Frame() error {
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viewport := g.renderer.blitter.viewport
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defFBO := g.ctx.BeginFrame(g.drawOps.clear, viewport)
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defer g.ctx.EndFrame()
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for _, img := range g.drawOps.imageOps {
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expandPathOp(img.path, img.clip)
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}
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if g.drawOps.profile {
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g.zopsTimer.begin()
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}
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g.ctx.BindFramebuffer(defFBO)
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g.ctx.DepthFunc(driver.DepthFuncGreater)
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// Note that Clear must be before ClearDepth if nothing else is rendered
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// (len(zimageOps) == 0). If not, the Fairphone 2 will corrupt the depth buffer.
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if g.drawOps.clear {
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g.drawOps.clear = false
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g.ctx.Clear(g.drawOps.clearColor.Float32())
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}
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g.ctx.ClearDepth(0.0)
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g.ctx.Viewport(0, 0, viewport.X, viewport.Y)
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g.renderer.drawZOps(g.cache, g.drawOps.zimageOps)
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g.zopsTimer.end()
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g.stencilTimer.begin()
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g.ctx.SetBlend(true)
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g.renderer.packStencils(&g.drawOps.pathOps)
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g.renderer.stencilClips(g.drawOps.pathCache, g.drawOps.pathOps)
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g.renderer.packIntersections(g.drawOps.imageOps)
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g.renderer.intersect(g.drawOps.imageOps)
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g.stencilTimer.end()
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g.coverTimer.begin()
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g.ctx.BindFramebuffer(defFBO)
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g.ctx.Viewport(0, 0, viewport.X, viewport.Y)
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g.renderer.drawOps(g.cache, g.drawOps.imageOps)
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g.ctx.SetBlend(false)
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g.renderer.pather.stenciler.invalidateFBO()
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g.coverTimer.end()
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g.ctx.BindFramebuffer(defFBO)
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g.cleanupTimer.begin()
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g.cache.frame()
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g.drawOps.pathCache.frame()
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g.cleanupTimer.end()
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if g.drawOps.profile && g.timers.ready() {
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zt, st, covt, cleant := g.zopsTimer.Elapsed, g.stencilTimer.Elapsed, g.coverTimer.Elapsed, g.cleanupTimer.Elapsed
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ft := zt + st + covt + cleant
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q := 100 * time.Microsecond
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zt, st, covt = zt.Round(q), st.Round(q), covt.Round(q)
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frameDur := time.Since(g.frameStart).Round(q)
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ft = ft.Round(q)
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g.profile = fmt.Sprintf("draw:%7s gpu:%7s zt:%7s st:%7s cov:%7s", frameDur, ft, zt, st, covt)
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}
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return nil
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}
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func (g *gpu) Profile() string {
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return g.profile
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}
|
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func (r *renderer) texHandle(cache *resourceCache, data imageOpData) driver.Texture {
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var tex *texture
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t, exists := cache.get(data.handle)
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if !exists {
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t = &texture{
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src: data.src,
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}
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cache.put(data.handle, t)
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}
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tex = t.(*texture)
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if tex.tex != nil {
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return tex.tex
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}
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handle, err := r.ctx.NewTexture(driver.TextureFormatSRGB, data.src.Bounds().Dx(), data.src.Bounds().Dy(), driver.FilterLinear, driver.FilterLinear, driver.BufferBindingTexture)
|
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if err != nil {
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panic(err)
|
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}
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driver.UploadImage(handle, image.Pt(0, 0), data.src)
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tex.tex = handle
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return tex.tex
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}
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|
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func (t *texture) release() {
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if t.tex != nil {
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t.tex.Release()
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}
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}
|
|
|
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func newRenderer(ctx driver.Device) *renderer {
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r := &renderer{
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ctx: ctx,
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blitter: newBlitter(ctx),
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pather: newPather(ctx),
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}
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|
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maxDim := ctx.Caps().MaxTextureSize
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// Large atlas textures cause artifacts due to precision loss in
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// shaders.
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if cap := 8192; maxDim > cap {
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maxDim = cap
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}
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r.packer.maxDim = maxDim
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r.intersections.maxDim = maxDim
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return r
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}
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|
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func (r *renderer) release() {
|
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r.pather.release()
|
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r.blitter.release()
|
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}
|
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|
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func newBlitter(ctx driver.Device) *blitter {
|
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quadVerts, err := ctx.NewImmutableBuffer(driver.BufferBindingVertices,
|
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byteslice.Slice([]float32{
|
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-1, +1, 0, 0,
|
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+1, +1, 1, 0,
|
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-1, -1, 0, 1,
|
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+1, -1, 1, 1,
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}),
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)
|
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if err != nil {
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panic(err)
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}
|
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b := &blitter{
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ctx: ctx,
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quadVerts: quadVerts,
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}
|
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b.colUniforms = new(blitColUniforms)
|
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b.texUniforms = new(blitTexUniforms)
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b.linearGradientUniforms = new(blitLinearGradientUniforms)
|
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prog, layout, err := createColorPrograms(ctx, shader_blit_vert, shader_blit_frag,
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[3]interface{}{&b.colUniforms.vert, &b.linearGradientUniforms.vert, &b.texUniforms.vert},
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[3]interface{}{&b.colUniforms.frag, &b.linearGradientUniforms.frag, nil},
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)
|
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if err != nil {
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panic(err)
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}
|
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b.prog = prog
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b.layout = layout
|
|
return b
|
|
}
|
|
|
|
func (b *blitter) release() {
|
|
b.quadVerts.Release()
|
|
for _, p := range b.prog {
|
|
p.Release()
|
|
}
|
|
b.layout.Release()
|
|
}
|
|
|
|
func createColorPrograms(b driver.Device, vsSrc driver.ShaderSources, fsSrc [3]driver.ShaderSources, vertUniforms, fragUniforms [3]interface{}) ([3]*program, driver.InputLayout, error) {
|
|
var progs [3]*program
|
|
{
|
|
prog, err := b.NewProgram(vsSrc, fsSrc[materialTexture])
|
|
if err != nil {
|
|
return progs, nil, err
|
|
}
|
|
var vertBuffer, fragBuffer *uniformBuffer
|
|
if u := vertUniforms[materialTexture]; u != nil {
|
|
vertBuffer = newUniformBuffer(b, u)
|
|
prog.SetVertexUniforms(vertBuffer.buf)
|
|
}
|
|
if u := fragUniforms[materialTexture]; u != nil {
|
|
fragBuffer = newUniformBuffer(b, u)
|
|
prog.SetFragmentUniforms(fragBuffer.buf)
|
|
}
|
|
progs[materialTexture] = newProgram(prog, vertBuffer, fragBuffer)
|
|
}
|
|
{
|
|
var vertBuffer, fragBuffer *uniformBuffer
|
|
prog, err := b.NewProgram(vsSrc, fsSrc[materialColor])
|
|
if err != nil {
|
|
progs[materialTexture].Release()
|
|
return progs, nil, err
|
|
}
|
|
if u := vertUniforms[materialColor]; u != nil {
|
|
vertBuffer = newUniformBuffer(b, u)
|
|
prog.SetVertexUniforms(vertBuffer.buf)
|
|
}
|
|
if u := fragUniforms[materialColor]; u != nil {
|
|
fragBuffer = newUniformBuffer(b, u)
|
|
prog.SetFragmentUniforms(fragBuffer.buf)
|
|
}
|
|
progs[materialColor] = newProgram(prog, vertBuffer, fragBuffer)
|
|
}
|
|
{
|
|
var vertBuffer, fragBuffer *uniformBuffer
|
|
prog, err := b.NewProgram(vsSrc, fsSrc[materialLinearGradient])
|
|
if err != nil {
|
|
progs[materialTexture].Release()
|
|
progs[materialColor].Release()
|
|
return progs, nil, err
|
|
}
|
|
if u := vertUniforms[materialLinearGradient]; u != nil {
|
|
vertBuffer = newUniformBuffer(b, u)
|
|
prog.SetVertexUniforms(vertBuffer.buf)
|
|
}
|
|
if u := fragUniforms[materialLinearGradient]; u != nil {
|
|
fragBuffer = newUniformBuffer(b, u)
|
|
prog.SetFragmentUniforms(fragBuffer.buf)
|
|
}
|
|
progs[materialLinearGradient] = newProgram(prog, vertBuffer, fragBuffer)
|
|
}
|
|
layout, err := b.NewInputLayout(vsSrc, []driver.InputDesc{
|
|
{Type: driver.DataTypeFloat, Size: 2, Offset: 0},
|
|
{Type: driver.DataTypeFloat, Size: 2, Offset: 4 * 2},
|
|
})
|
|
if err != nil {
|
|
progs[materialTexture].Release()
|
|
progs[materialColor].Release()
|
|
progs[materialLinearGradient].Release()
|
|
return progs, nil, err
|
|
}
|
|
return progs, layout, nil
|
|
}
|
|
|
|
func (r *renderer) stencilClips(pathCache *opCache, ops []*pathOp) {
|
|
if len(r.packer.sizes) == 0 {
|
|
return
|
|
}
|
|
fbo := -1
|
|
r.pather.begin(r.packer.sizes)
|
|
for _, p := range ops {
|
|
if fbo != p.place.Idx {
|
|
fbo = p.place.Idx
|
|
f := r.pather.stenciler.cover(fbo)
|
|
r.ctx.BindFramebuffer(f.fbo)
|
|
r.ctx.Clear(0.0, 0.0, 0.0, 0.0)
|
|
}
|
|
v, _ := pathCache.get(p.pathKey)
|
|
r.pather.stencilPath(p.clip, p.off, p.place.Pos, v.data)
|
|
}
|
|
}
|
|
|
|
func (r *renderer) intersect(ops []imageOp) {
|
|
if len(r.intersections.sizes) == 0 {
|
|
return
|
|
}
|
|
fbo := -1
|
|
r.pather.stenciler.beginIntersect(r.intersections.sizes)
|
|
r.ctx.BindVertexBuffer(r.blitter.quadVerts, 4*4, 0)
|
|
r.ctx.BindInputLayout(r.pather.stenciler.iprog.layout)
|
|
for _, img := range ops {
|
|
if img.clipType != clipTypeIntersection {
|
|
continue
|
|
}
|
|
if fbo != img.place.Idx {
|
|
fbo = img.place.Idx
|
|
f := r.pather.stenciler.intersections.fbos[fbo]
|
|
r.ctx.BindFramebuffer(f.fbo)
|
|
r.ctx.Clear(1.0, 0.0, 0.0, 0.0)
|
|
}
|
|
r.ctx.Viewport(img.place.Pos.X, img.place.Pos.Y, img.clip.Dx(), img.clip.Dy())
|
|
r.intersectPath(img.path, img.clip)
|
|
}
|
|
}
|
|
|
|
func (r *renderer) intersectPath(p *pathOp, clip image.Rectangle) {
|
|
if p.parent != nil {
|
|
r.intersectPath(p.parent, clip)
|
|
}
|
|
if !p.path {
|
|
return
|
|
}
|
|
uv := image.Rectangle{
|
|
Min: p.place.Pos,
|
|
Max: p.place.Pos.Add(p.clip.Size()),
|
|
}
|
|
o := clip.Min.Sub(p.clip.Min)
|
|
sub := image.Rectangle{
|
|
Min: o,
|
|
Max: o.Add(clip.Size()),
|
|
}
|
|
fbo := r.pather.stenciler.cover(p.place.Idx)
|
|
r.ctx.BindTexture(0, fbo.tex)
|
|
coverScale, coverOff := texSpaceTransform(layout.FRect(uv), fbo.size)
|
|
subScale, subOff := texSpaceTransform(layout.FRect(sub), p.clip.Size())
|
|
r.pather.stenciler.iprog.uniforms.vert.uvTransform = [4]float32{coverScale.X, coverScale.Y, coverOff.X, coverOff.Y}
|
|
r.pather.stenciler.iprog.uniforms.vert.subUVTransform = [4]float32{subScale.X, subScale.Y, subOff.X, subOff.Y}
|
|
r.pather.stenciler.iprog.prog.UploadUniforms()
|
|
r.ctx.DrawArrays(driver.DrawModeTriangleStrip, 0, 4)
|
|
}
|
|
|
|
func (r *renderer) packIntersections(ops []imageOp) {
|
|
r.intersections.clear()
|
|
for i, img := range ops {
|
|
var npaths int
|
|
var onePath *pathOp
|
|
for p := img.path; p != nil; p = p.parent {
|
|
if p.path {
|
|
onePath = p
|
|
npaths++
|
|
}
|
|
}
|
|
switch npaths {
|
|
case 0:
|
|
case 1:
|
|
place := onePath.place
|
|
place.Pos = place.Pos.Sub(onePath.clip.Min).Add(img.clip.Min)
|
|
ops[i].place = place
|
|
ops[i].clipType = clipTypePath
|
|
default:
|
|
sz := image.Point{X: img.clip.Dx(), Y: img.clip.Dy()}
|
|
place, ok := r.intersections.add(sz)
|
|
if !ok {
|
|
panic("internal error: if the intersection fit, the intersection should fit as well")
|
|
}
|
|
ops[i].clipType = clipTypeIntersection
|
|
ops[i].place = place
|
|
}
|
|
}
|
|
}
|
|
|
|
func (r *renderer) packStencils(pops *[]*pathOp) {
|
|
r.packer.clear()
|
|
ops := *pops
|
|
// Allocate atlas space for cover textures.
|
|
var i int
|
|
for i < len(ops) {
|
|
p := ops[i]
|
|
if p.clip.Empty() {
|
|
ops[i] = ops[len(ops)-1]
|
|
ops = ops[:len(ops)-1]
|
|
continue
|
|
}
|
|
sz := image.Point{X: p.clip.Dx(), Y: p.clip.Dy()}
|
|
place, ok := r.packer.add(sz)
|
|
if !ok {
|
|
// The clip area is at most the entire screen. Hopefully no
|
|
// screen is larger than GL_MAX_TEXTURE_SIZE.
|
|
panic(fmt.Errorf("clip area %v is larger than maximum texture size %dx%d", p.clip, r.packer.maxDim, r.packer.maxDim))
|
|
}
|
|
p.place = place
|
|
i++
|
|
}
|
|
*pops = ops
|
|
}
|
|
|
|
// boundRectF returns a bounding image.Rectangle for a f32.Rectangle.
|
|
func boundRectF(r f32.Rectangle) image.Rectangle {
|
|
return image.Rectangle{
|
|
Min: image.Point{
|
|
X: int(floor(r.Min.X)),
|
|
Y: int(floor(r.Min.Y)),
|
|
},
|
|
Max: image.Point{
|
|
X: int(ceil(r.Max.X)),
|
|
Y: int(ceil(r.Max.Y)),
|
|
},
|
|
}
|
|
}
|
|
|
|
func ceil(v float32) int {
|
|
return int(math.Ceil(float64(v)))
|
|
}
|
|
|
|
func floor(v float32) int {
|
|
return int(math.Floor(float64(v)))
|
|
}
|
|
|
|
func (d *drawOps) reset(cache *resourceCache, viewport image.Point) {
|
|
d.profile = false
|
|
d.cache = cache
|
|
d.viewport = viewport
|
|
d.imageOps = d.imageOps[:0]
|
|
d.zimageOps = d.zimageOps[:0]
|
|
d.pathOps = d.pathOps[:0]
|
|
d.pathOpCache = d.pathOpCache[:0]
|
|
d.vertCache = d.vertCache[:0]
|
|
}
|
|
|
|
func (d *drawOps) collect(ctx driver.Device, cache *resourceCache, root *op.Ops, viewport image.Point) {
|
|
clip := f32.Rectangle{
|
|
Max: f32.Point{X: float32(viewport.X), Y: float32(viewport.Y)},
|
|
}
|
|
d.reader.Reset(root)
|
|
state := drawState{
|
|
clip: clip,
|
|
rect: true,
|
|
color: color.NRGBA{A: 0xff},
|
|
}
|
|
d.collectOps(&d.reader, state)
|
|
for _, p := range d.pathOps {
|
|
if v, exists := d.pathCache.get(p.pathKey); !exists || v.data.data == nil {
|
|
data := buildPath(ctx, p.pathVerts)
|
|
d.pathCache.put(p.pathKey, opCacheValue{
|
|
data: data,
|
|
bounds: p.bounds,
|
|
})
|
|
}
|
|
p.pathVerts = nil
|
|
}
|
|
}
|
|
|
|
func (d *drawOps) newPathOp() *pathOp {
|
|
d.pathOpCache = append(d.pathOpCache, pathOp{})
|
|
return &d.pathOpCache[len(d.pathOpCache)-1]
|
|
}
|
|
|
|
func (d *drawOps) addClipPath(state *drawState, aux []byte, auxKey opKey, bounds f32.Rectangle, off f32.Point) {
|
|
npath := d.newPathOp()
|
|
*npath = pathOp{
|
|
parent: state.cpath,
|
|
bounds: bounds,
|
|
off: off,
|
|
}
|
|
state.cpath = npath
|
|
if len(aux) > 0 {
|
|
state.rect = false
|
|
state.cpath.pathKey = auxKey
|
|
state.cpath.path = true
|
|
state.cpath.pathVerts = aux
|
|
d.pathOps = append(d.pathOps, state.cpath)
|
|
}
|
|
}
|
|
|
|
// split a transform into two parts, one which is pure offset and the
|
|
// other representing the scaling, shearing and rotation part
|
|
func splitTransform(t f32.Affine2D) (srs f32.Affine2D, offset f32.Point) {
|
|
sx, hx, ox, hy, sy, oy := t.Elems()
|
|
offset = f32.Point{X: ox, Y: oy}
|
|
srs = f32.NewAffine2D(sx, hx, 0, hy, sy, 0)
|
|
return
|
|
}
|
|
|
|
func (d *drawOps) save(id int, state drawState) {
|
|
if extra := id - len(d.states) + 1; extra > 0 {
|
|
d.states = append(d.states, make([]drawState, extra)...)
|
|
}
|
|
d.states[id] = state
|
|
}
|
|
|
|
func (k opKey) SetTransform(t f32.Affine2D) opKey {
|
|
sx, hx, _, hy, sy, _ := t.Elems()
|
|
k.sx = sx
|
|
k.hx = hx
|
|
k.hy = hy
|
|
k.sy = sy
|
|
return k
|
|
}
|
|
|
|
func (d *drawOps) collectOps(r *ops.Reader, state drawState) {
|
|
var (
|
|
quads quadsOp
|
|
str clip.StrokeStyle
|
|
z int
|
|
)
|
|
d.save(opconst.InitialStateID, state)
|
|
loop:
|
|
for encOp, ok := r.Decode(); ok; encOp, ok = r.Decode() {
|
|
switch opconst.OpType(encOp.Data[0]) {
|
|
case opconst.TypeProfile:
|
|
d.profile = true
|
|
case opconst.TypeTransform:
|
|
dop := ops.DecodeTransform(encOp.Data)
|
|
state.t = state.t.Mul(dop)
|
|
|
|
case opconst.TypeStroke:
|
|
str = decodeStrokeOp(encOp.Data)
|
|
|
|
case opconst.TypePath:
|
|
encOp, ok = r.Decode()
|
|
if !ok {
|
|
break loop
|
|
}
|
|
quads.aux = encOp.Data[opconst.TypeAuxLen:]
|
|
quads.key = opKey{Key: encOp.Key}
|
|
|
|
case opconst.TypeClip:
|
|
var op clipOp
|
|
op.decode(encOp.Data)
|
|
bounds := op.bounds
|
|
trans, off := splitTransform(state.t)
|
|
if len(quads.aux) > 0 {
|
|
// There is a clipping path, build the gpu data and update the
|
|
// cache key such that it will be equal only if the transform is the
|
|
// same also. Use cached data if we have it.
|
|
quads.key = quads.key.SetTransform(trans)
|
|
if v, ok := d.pathCache.get(quads.key); ok {
|
|
// Since the GPU data exists in the cache aux will not be used.
|
|
// Why is this not used for the offset shapes?
|
|
op.bounds = v.bounds
|
|
} else {
|
|
pathData, bounds := d.buildVerts(
|
|
quads.aux, trans, op.outline, str,
|
|
)
|
|
op.bounds = bounds
|
|
quads.aux = pathData
|
|
// add it to the cache, without GPU data, so the transform can be
|
|
// reused.
|
|
d.pathCache.put(quads.key, opCacheValue{bounds: op.bounds})
|
|
}
|
|
} else {
|
|
quads.aux, op.bounds, _ = d.boundsForTransformedRect(bounds, trans)
|
|
quads.key = opKey{Key: encOp.Key}
|
|
quads.key.SetTransform(trans) // TODO: This call has no effect.
|
|
}
|
|
state.clip = state.clip.Intersect(op.bounds.Add(off))
|
|
d.addClipPath(&state, quads.aux, quads.key, op.bounds, off)
|
|
quads = quadsOp{}
|
|
str = clip.StrokeStyle{}
|
|
|
|
case opconst.TypeColor:
|
|
state.matType = materialColor
|
|
state.color = decodeColorOp(encOp.Data)
|
|
case opconst.TypeLinearGradient:
|
|
state.matType = materialLinearGradient
|
|
op := decodeLinearGradientOp(encOp.Data)
|
|
state.stop1 = op.stop1
|
|
state.stop2 = op.stop2
|
|
state.color1 = op.color1
|
|
state.color2 = op.color2
|
|
case opconst.TypeImage:
|
|
state.matType = materialTexture
|
|
state.image = decodeImageOp(encOp.Data, encOp.Refs)
|
|
case opconst.TypePaint:
|
|
// Transform (if needed) the painting rectangle and if so generate a clip path,
|
|
// for those cases also compute a partialTrans that maps texture coordinates between
|
|
// the new bounding rectangle and the transformed original paint rectangle.
|
|
trans, off := splitTransform(state.t)
|
|
// Fill the clip area, unless the material is a (bounded) image.
|
|
// TODO: Find a tighter bound.
|
|
inf := float32(1e6)
|
|
dst := f32.Rect(-inf, -inf, inf, inf)
|
|
if state.matType == materialTexture {
|
|
dst = layout.FRect(state.image.src.Rect)
|
|
}
|
|
clipData, bnd, partialTrans := d.boundsForTransformedRect(dst, trans)
|
|
cl := state.clip.Intersect(bnd.Add(off))
|
|
if cl.Empty() {
|
|
continue
|
|
}
|
|
|
|
wasrect := state.rect
|
|
if clipData != nil {
|
|
// The paint operation is sheared or rotated, add a clip path representing
|
|
// this transformed rectangle.
|
|
k := opKey{Key: encOp.Key}
|
|
k.SetTransform(trans) // TODO: This call has no effect.
|
|
d.addClipPath(&state, clipData, k, bnd, off)
|
|
}
|
|
|
|
bounds := boundRectF(cl)
|
|
mat := state.materialFor(bnd, off, partialTrans, bounds)
|
|
|
|
if bounds.Min == (image.Point{}) && bounds.Max == d.viewport && state.rect && mat.opaque && (mat.material == materialColor) {
|
|
// The image is a uniform opaque color and takes up the whole screen.
|
|
// Scrap images up to and including this image and set clear color.
|
|
d.zimageOps = d.zimageOps[:0]
|
|
d.imageOps = d.imageOps[:0]
|
|
z = 0
|
|
d.clearColor = mat.color.Opaque()
|
|
d.clear = true
|
|
continue
|
|
}
|
|
z++
|
|
if z != int(uint16(z)) {
|
|
// TODO(eliasnaur) gioui.org/issue/127.
|
|
panic("more than 65k paint objects not supported")
|
|
}
|
|
// Assume 16-bit depth buffer.
|
|
const zdepth = 1 << 16
|
|
// Convert z to window-space, assuming depth range [0;1].
|
|
zf := float32(z)*2/zdepth - 1.0
|
|
img := imageOp{
|
|
z: zf,
|
|
path: state.cpath,
|
|
clip: bounds,
|
|
material: mat,
|
|
}
|
|
|
|
if state.rect && img.material.opaque {
|
|
d.zimageOps = append(d.zimageOps, img)
|
|
} else {
|
|
d.imageOps = append(d.imageOps, img)
|
|
}
|
|
if clipData != nil {
|
|
// we added a clip path that should not remain
|
|
state.cpath = state.cpath.parent
|
|
state.rect = wasrect
|
|
}
|
|
case opconst.TypeSave:
|
|
id := ops.DecodeSave(encOp.Data)
|
|
d.save(id, state)
|
|
case opconst.TypeLoad:
|
|
id, mask := ops.DecodeLoad(encOp.Data)
|
|
s := d.states[id]
|
|
if mask&opconst.TransformState != 0 {
|
|
state.t = s.t
|
|
}
|
|
if mask&^opconst.TransformState != 0 {
|
|
state = s
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
func expandPathOp(p *pathOp, clip image.Rectangle) {
|
|
for p != nil {
|
|
pclip := p.clip
|
|
if !pclip.Empty() {
|
|
clip = clip.Union(pclip)
|
|
}
|
|
p.clip = clip
|
|
p = p.parent
|
|
}
|
|
}
|
|
|
|
func (d *drawState) materialFor(rect f32.Rectangle, off f32.Point, partTrans f32.Affine2D, clip image.Rectangle) material {
|
|
var m material
|
|
switch d.matType {
|
|
case materialColor:
|
|
m.material = materialColor
|
|
m.color = f32color.LinearFromSRGB(d.color)
|
|
m.opaque = m.color.A == 1.0
|
|
case materialLinearGradient:
|
|
m.material = materialLinearGradient
|
|
|
|
m.color1 = f32color.LinearFromSRGB(d.color1)
|
|
m.color2 = f32color.LinearFromSRGB(d.color2)
|
|
m.opaque = m.color1.A == 1.0 && m.color2.A == 1.0
|
|
|
|
m.uvTrans = partTrans.Mul(gradientSpaceTransform(clip, off, d.stop1, d.stop2))
|
|
case materialTexture:
|
|
m.material = materialTexture
|
|
dr := boundRectF(rect.Add(off))
|
|
sz := d.image.src.Bounds().Size()
|
|
sr := f32.Rectangle{
|
|
Max: f32.Point{
|
|
X: float32(sz.X),
|
|
Y: float32(sz.Y),
|
|
},
|
|
}
|
|
dx := float32(dr.Dx())
|
|
sdx := sr.Dx()
|
|
sr.Min.X += float32(clip.Min.X-dr.Min.X) * sdx / dx
|
|
sr.Max.X -= float32(dr.Max.X-clip.Max.X) * sdx / dx
|
|
dy := float32(dr.Dy())
|
|
sdy := sr.Dy()
|
|
sr.Min.Y += float32(clip.Min.Y-dr.Min.Y) * sdy / dy
|
|
sr.Max.Y -= float32(dr.Max.Y-clip.Max.Y) * sdy / dy
|
|
uvScale, uvOffset := texSpaceTransform(sr, sz)
|
|
m.uvTrans = partTrans.Mul(f32.Affine2D{}.Scale(f32.Point{}, uvScale).Offset(uvOffset))
|
|
m.data = d.image
|
|
}
|
|
return m
|
|
}
|
|
|
|
func (r *renderer) drawZOps(cache *resourceCache, ops []imageOp) {
|
|
r.ctx.SetDepthTest(true)
|
|
r.ctx.BindVertexBuffer(r.blitter.quadVerts, 4*4, 0)
|
|
r.ctx.BindInputLayout(r.blitter.layout)
|
|
// Render front to back.
|
|
for i := len(ops) - 1; i >= 0; i-- {
|
|
img := ops[i]
|
|
m := img.material
|
|
switch m.material {
|
|
case materialTexture:
|
|
r.ctx.BindTexture(0, r.texHandle(cache, m.data))
|
|
}
|
|
drc := img.clip
|
|
scale, off := clipSpaceTransform(drc, r.blitter.viewport)
|
|
r.blitter.blit(img.z, m.material, m.color, m.color1, m.color2, scale, off, m.uvTrans)
|
|
}
|
|
r.ctx.SetDepthTest(false)
|
|
}
|
|
|
|
func (r *renderer) drawOps(cache *resourceCache, ops []imageOp) {
|
|
r.ctx.SetDepthTest(true)
|
|
r.ctx.DepthMask(false)
|
|
r.ctx.BlendFunc(driver.BlendFactorOne, driver.BlendFactorOneMinusSrcAlpha)
|
|
r.ctx.BindVertexBuffer(r.blitter.quadVerts, 4*4, 0)
|
|
r.ctx.BindInputLayout(r.pather.coverer.layout)
|
|
var coverTex driver.Texture
|
|
for _, img := range ops {
|
|
m := img.material
|
|
switch m.material {
|
|
case materialTexture:
|
|
r.ctx.BindTexture(0, r.texHandle(cache, m.data))
|
|
}
|
|
drc := img.clip
|
|
|
|
scale, off := clipSpaceTransform(drc, r.blitter.viewport)
|
|
var fbo stencilFBO
|
|
switch img.clipType {
|
|
case clipTypeNone:
|
|
r.blitter.blit(img.z, m.material, m.color, m.color1, m.color2, scale, off, m.uvTrans)
|
|
continue
|
|
case clipTypePath:
|
|
fbo = r.pather.stenciler.cover(img.place.Idx)
|
|
case clipTypeIntersection:
|
|
fbo = r.pather.stenciler.intersections.fbos[img.place.Idx]
|
|
}
|
|
if coverTex != fbo.tex {
|
|
coverTex = fbo.tex
|
|
r.ctx.BindTexture(1, coverTex)
|
|
}
|
|
uv := image.Rectangle{
|
|
Min: img.place.Pos,
|
|
Max: img.place.Pos.Add(drc.Size()),
|
|
}
|
|
coverScale, coverOff := texSpaceTransform(layout.FRect(uv), fbo.size)
|
|
r.pather.cover(img.z, m.material, m.color, m.color1, m.color2, scale, off, m.uvTrans, coverScale, coverOff)
|
|
}
|
|
r.ctx.DepthMask(true)
|
|
r.ctx.SetDepthTest(false)
|
|
}
|
|
|
|
func (b *blitter) blit(z float32, mat materialType, col f32color.RGBA, col1, col2 f32color.RGBA, scale, off f32.Point, uvTrans f32.Affine2D) {
|
|
p := b.prog[mat]
|
|
b.ctx.BindProgram(p.prog)
|
|
var uniforms *blitUniforms
|
|
switch mat {
|
|
case materialColor:
|
|
b.colUniforms.frag.color = col
|
|
uniforms = &b.colUniforms.vert.blitUniforms
|
|
case materialTexture:
|
|
t1, t2, t3, t4, t5, t6 := uvTrans.Elems()
|
|
b.texUniforms.vert.blitUniforms.uvTransformR1 = [4]float32{t1, t2, t3, 0}
|
|
b.texUniforms.vert.blitUniforms.uvTransformR2 = [4]float32{t4, t5, t6, 0}
|
|
uniforms = &b.texUniforms.vert.blitUniforms
|
|
case materialLinearGradient:
|
|
b.linearGradientUniforms.frag.color1 = col1
|
|
b.linearGradientUniforms.frag.color2 = col2
|
|
|
|
t1, t2, t3, t4, t5, t6 := uvTrans.Elems()
|
|
b.linearGradientUniforms.vert.blitUniforms.uvTransformR1 = [4]float32{t1, t2, t3, 0}
|
|
b.linearGradientUniforms.vert.blitUniforms.uvTransformR2 = [4]float32{t4, t5, t6, 0}
|
|
uniforms = &b.linearGradientUniforms.vert.blitUniforms
|
|
}
|
|
uniforms.z = z
|
|
uniforms.transform = [4]float32{scale.X, scale.Y, off.X, off.Y}
|
|
p.UploadUniforms()
|
|
b.ctx.DrawArrays(driver.DrawModeTriangleStrip, 0, 4)
|
|
}
|
|
|
|
// newUniformBuffer creates a new GPU uniform buffer backed by the
|
|
// structure uniformBlock points to.
|
|
func newUniformBuffer(b driver.Device, uniformBlock interface{}) *uniformBuffer {
|
|
ref := reflect.ValueOf(uniformBlock)
|
|
// Determine the size of the uniforms structure, *uniforms.
|
|
size := ref.Elem().Type().Size()
|
|
// Map the uniforms structure as a byte slice.
|
|
ptr := (*[1 << 30]byte)(unsafe.Pointer(ref.Pointer()))[:size:size]
|
|
ubuf, err := b.NewBuffer(driver.BufferBindingUniforms, len(ptr))
|
|
if err != nil {
|
|
panic(err)
|
|
}
|
|
return &uniformBuffer{buf: ubuf, ptr: ptr}
|
|
}
|
|
|
|
func (u *uniformBuffer) Upload() {
|
|
u.buf.Upload(u.ptr)
|
|
}
|
|
|
|
func (u *uniformBuffer) Release() {
|
|
u.buf.Release()
|
|
u.buf = nil
|
|
}
|
|
|
|
func newProgram(prog driver.Program, vertUniforms, fragUniforms *uniformBuffer) *program {
|
|
if vertUniforms != nil {
|
|
prog.SetVertexUniforms(vertUniforms.buf)
|
|
}
|
|
if fragUniforms != nil {
|
|
prog.SetFragmentUniforms(fragUniforms.buf)
|
|
}
|
|
return &program{prog: prog, vertUniforms: vertUniforms, fragUniforms: fragUniforms}
|
|
}
|
|
|
|
func (p *program) UploadUniforms() {
|
|
if p.vertUniforms != nil {
|
|
p.vertUniforms.Upload()
|
|
}
|
|
if p.fragUniforms != nil {
|
|
p.fragUniforms.Upload()
|
|
}
|
|
}
|
|
|
|
func (p *program) Release() {
|
|
p.prog.Release()
|
|
p.prog = nil
|
|
if p.vertUniforms != nil {
|
|
p.vertUniforms.Release()
|
|
p.vertUniforms = nil
|
|
}
|
|
if p.fragUniforms != nil {
|
|
p.fragUniforms.Release()
|
|
p.fragUniforms = nil
|
|
}
|
|
}
|
|
|
|
// texSpaceTransform return the scale and offset that transforms the given subimage
|
|
// into quad texture coordinates.
|
|
func texSpaceTransform(r f32.Rectangle, bounds image.Point) (f32.Point, f32.Point) {
|
|
size := f32.Point{X: float32(bounds.X), Y: float32(bounds.Y)}
|
|
scale := f32.Point{X: r.Dx() / size.X, Y: r.Dy() / size.Y}
|
|
offset := f32.Point{X: r.Min.X / size.X, Y: r.Min.Y / size.Y}
|
|
return scale, offset
|
|
}
|
|
|
|
// gradientSpaceTransform transforms stop1 and stop2 to [(0,0), (1,1)].
|
|
func gradientSpaceTransform(clip image.Rectangle, off f32.Point, stop1, stop2 f32.Point) f32.Affine2D {
|
|
d := stop2.Sub(stop1)
|
|
l := float32(math.Sqrt(float64(d.X*d.X + d.Y*d.Y)))
|
|
a := float32(math.Atan2(float64(-d.Y), float64(d.X)))
|
|
|
|
// TODO: optimize
|
|
zp := f32.Point{}
|
|
return f32.Affine2D{}.
|
|
Scale(zp, layout.FPt(clip.Size())). // scale to pixel space
|
|
Offset(zp.Sub(off).Add(layout.FPt(clip.Min))). // offset to clip space
|
|
Offset(zp.Sub(stop1)). // offset to first stop point
|
|
Rotate(zp, a). // rotate to align gradient
|
|
Scale(zp, f32.Pt(1/l, 1/l)) // scale gradient to right size
|
|
}
|
|
|
|
// clipSpaceTransform returns the scale and offset that transforms the given
|
|
// rectangle from a viewport into OpenGL clip space.
|
|
func clipSpaceTransform(r image.Rectangle, viewport image.Point) (f32.Point, f32.Point) {
|
|
// First, transform UI coordinates to OpenGL coordinates:
|
|
//
|
|
// [(-1, +1) (+1, +1)]
|
|
// [(-1, -1) (+1, -1)]
|
|
//
|
|
x, y := float32(r.Min.X), float32(r.Min.Y)
|
|
w, h := float32(r.Dx()), float32(r.Dy())
|
|
vx, vy := 2/float32(viewport.X), 2/float32(viewport.Y)
|
|
x = x*vx - 1
|
|
y = 1 - y*vy
|
|
w *= vx
|
|
h *= vy
|
|
|
|
// Then, compute the transformation from the fullscreen quad to
|
|
// the rectangle at (x, y) and dimensions (w, h).
|
|
scale := f32.Point{X: w * .5, Y: h * .5}
|
|
offset := f32.Point{X: x + w*.5, Y: y - h*.5}
|
|
|
|
return scale, offset
|
|
}
|
|
|
|
// Fill in maximal Y coordinates of the NW and NE corners.
|
|
func fillMaxY(verts []byte) {
|
|
contour := 0
|
|
bo := binary.LittleEndian
|
|
for len(verts) > 0 {
|
|
maxy := float32(math.Inf(-1))
|
|
i := 0
|
|
for ; i+vertStride*4 <= len(verts); i += vertStride * 4 {
|
|
vert := verts[i : i+vertStride]
|
|
// MaxY contains the integer contour index.
|
|
pathContour := int(bo.Uint32(vert[int(unsafe.Offsetof(((*vertex)(nil)).MaxY)):]))
|
|
if contour != pathContour {
|
|
contour = pathContour
|
|
break
|
|
}
|
|
fromy := math.Float32frombits(bo.Uint32(vert[int(unsafe.Offsetof(((*vertex)(nil)).FromY)):]))
|
|
ctrly := math.Float32frombits(bo.Uint32(vert[int(unsafe.Offsetof(((*vertex)(nil)).CtrlY)):]))
|
|
toy := math.Float32frombits(bo.Uint32(vert[int(unsafe.Offsetof(((*vertex)(nil)).ToY)):]))
|
|
if fromy > maxy {
|
|
maxy = fromy
|
|
}
|
|
if ctrly > maxy {
|
|
maxy = ctrly
|
|
}
|
|
if toy > maxy {
|
|
maxy = toy
|
|
}
|
|
}
|
|
fillContourMaxY(maxy, verts[:i])
|
|
verts = verts[i:]
|
|
}
|
|
}
|
|
|
|
func fillContourMaxY(maxy float32, verts []byte) {
|
|
bo := binary.LittleEndian
|
|
for i := 0; i < len(verts); i += vertStride {
|
|
off := int(unsafe.Offsetof(((*vertex)(nil)).MaxY))
|
|
bo.PutUint32(verts[i+off:], math.Float32bits(maxy))
|
|
}
|
|
}
|
|
|
|
func (d *drawOps) writeVertCache(n int) []byte {
|
|
d.vertCache = append(d.vertCache, make([]byte, n)...)
|
|
return d.vertCache[len(d.vertCache)-n:]
|
|
}
|
|
|
|
// transform, split paths as needed, calculate maxY, bounds and create GPU vertices.
|
|
func (d *drawOps) buildVerts(pathData []byte, tr f32.Affine2D, outline bool, str clip.StrokeStyle) (verts []byte, bounds f32.Rectangle) {
|
|
inf := float32(math.Inf(+1))
|
|
d.qs.bounds = f32.Rectangle{
|
|
Min: f32.Point{X: inf, Y: inf},
|
|
Max: f32.Point{X: -inf, Y: -inf},
|
|
}
|
|
d.qs.d = d
|
|
startLength := len(d.vertCache)
|
|
|
|
switch {
|
|
case str.Width > 0:
|
|
// Stroke path.
|
|
ss := stroke.StrokeStyle{
|
|
Width: str.Width,
|
|
Miter: str.Miter,
|
|
Cap: stroke.StrokeCap(str.Cap),
|
|
Join: stroke.StrokeJoin(str.Join),
|
|
}
|
|
quads := stroke.StrokePathCommands(ss, stroke.DashOp{}, pathData)
|
|
for _, quad := range quads {
|
|
d.qs.contour = quad.Contour
|
|
quad.Quad = quad.Quad.Transform(tr)
|
|
|
|
d.qs.splitAndEncode(quad.Quad)
|
|
}
|
|
|
|
case outline:
|
|
decodeToOutlineQuads(&d.qs, tr, pathData)
|
|
}
|
|
|
|
fillMaxY(d.vertCache[startLength:])
|
|
return d.vertCache[startLength:], d.qs.bounds
|
|
}
|
|
|
|
// decodeOutlineQuads decodes scene commands, splits them into quadratic béziers
|
|
// as needed and feeds them to the supplied splitter.
|
|
func decodeToOutlineQuads(qs *quadSplitter, tr f32.Affine2D, pathData []byte) {
|
|
for len(pathData) >= scene.CommandSize+4 {
|
|
qs.contour = bo.Uint32(pathData)
|
|
cmd := ops.DecodeCommand(pathData[4:])
|
|
switch cmd.Op() {
|
|
case scene.OpLine:
|
|
var q stroke.QuadSegment
|
|
q.From, q.To = scene.DecodeLine(cmd)
|
|
q.Ctrl = q.From.Add(q.To).Mul(.5)
|
|
q = q.Transform(tr)
|
|
qs.splitAndEncode(q)
|
|
case scene.OpQuad:
|
|
var q stroke.QuadSegment
|
|
q.From, q.Ctrl, q.To = scene.DecodeQuad(cmd)
|
|
q = q.Transform(tr)
|
|
qs.splitAndEncode(q)
|
|
case scene.OpCubic:
|
|
for _, q := range stroke.SplitCubic(scene.DecodeCubic(cmd)) {
|
|
q = q.Transform(tr)
|
|
qs.splitAndEncode(q)
|
|
}
|
|
default:
|
|
panic("unsupported scene command")
|
|
}
|
|
pathData = pathData[scene.CommandSize+4:]
|
|
}
|
|
}
|
|
|
|
// create GPU vertices for transformed r, find the bounds and establish texture transform.
|
|
func (d *drawOps) boundsForTransformedRect(r f32.Rectangle, tr f32.Affine2D) (aux []byte, bnd f32.Rectangle, ptr f32.Affine2D) {
|
|
if isPureOffset(tr) {
|
|
// fast-path to allow blitting of pure rectangles
|
|
_, _, ox, _, _, oy := tr.Elems()
|
|
off := f32.Pt(ox, oy)
|
|
bnd.Min = r.Min.Add(off)
|
|
bnd.Max = r.Max.Add(off)
|
|
return
|
|
}
|
|
|
|
// transform all corners, find new bounds
|
|
corners := [4]f32.Point{
|
|
tr.Transform(r.Min), tr.Transform(f32.Pt(r.Max.X, r.Min.Y)),
|
|
tr.Transform(r.Max), tr.Transform(f32.Pt(r.Min.X, r.Max.Y)),
|
|
}
|
|
bnd.Min = f32.Pt(math.MaxFloat32, math.MaxFloat32)
|
|
bnd.Max = f32.Pt(-math.MaxFloat32, -math.MaxFloat32)
|
|
for _, c := range corners {
|
|
if c.X < bnd.Min.X {
|
|
bnd.Min.X = c.X
|
|
}
|
|
if c.Y < bnd.Min.Y {
|
|
bnd.Min.Y = c.Y
|
|
}
|
|
if c.X > bnd.Max.X {
|
|
bnd.Max.X = c.X
|
|
}
|
|
if c.Y > bnd.Max.Y {
|
|
bnd.Max.Y = c.Y
|
|
}
|
|
}
|
|
|
|
// build the GPU vertices
|
|
l := len(d.vertCache)
|
|
d.vertCache = append(d.vertCache, make([]byte, vertStride*4*4)...)
|
|
aux = d.vertCache[l:]
|
|
encodeQuadTo(aux, 0, corners[0], corners[0].Add(corners[1]).Mul(0.5), corners[1])
|
|
encodeQuadTo(aux[vertStride*4:], 0, corners[1], corners[1].Add(corners[2]).Mul(0.5), corners[2])
|
|
encodeQuadTo(aux[vertStride*4*2:], 0, corners[2], corners[2].Add(corners[3]).Mul(0.5), corners[3])
|
|
encodeQuadTo(aux[vertStride*4*3:], 0, corners[3], corners[3].Add(corners[0]).Mul(0.5), corners[0])
|
|
fillMaxY(aux)
|
|
|
|
// establish the transform mapping from bounds rectangle to transformed corners
|
|
var P1, P2, P3 f32.Point
|
|
P1.X = (corners[1].X - bnd.Min.X) / (bnd.Max.X - bnd.Min.X)
|
|
P1.Y = (corners[1].Y - bnd.Min.Y) / (bnd.Max.Y - bnd.Min.Y)
|
|
P2.X = (corners[2].X - bnd.Min.X) / (bnd.Max.X - bnd.Min.X)
|
|
P2.Y = (corners[2].Y - bnd.Min.Y) / (bnd.Max.Y - bnd.Min.Y)
|
|
P3.X = (corners[3].X - bnd.Min.X) / (bnd.Max.X - bnd.Min.X)
|
|
P3.Y = (corners[3].Y - bnd.Min.Y) / (bnd.Max.Y - bnd.Min.Y)
|
|
sx, sy := P2.X-P3.X, P2.Y-P3.Y
|
|
ptr = f32.NewAffine2D(sx, P2.X-P1.X, P1.X-sx, sy, P2.Y-P1.Y, P1.Y-sy).Invert()
|
|
|
|
return
|
|
}
|
|
|
|
func isPureOffset(t f32.Affine2D) bool {
|
|
a, b, _, d, e, _ := t.Elems()
|
|
return a == 1 && b == 0 && d == 0 && e == 1
|
|
}
|