ebiten/internal/graphicsdriver/opengl/program.go

342 lines
8.9 KiB
Go

// Copyright 2014 Hajime Hoshi
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package opengl
import (
"fmt"
"runtime"
"github.com/hajimehoshi/ebiten/v2/internal/graphics"
"github.com/hajimehoshi/ebiten/v2/internal/graphicsdriver"
"github.com/hajimehoshi/ebiten/v2/internal/shaderir"
)
const floatSizeInBytes = 4
// arrayBufferLayoutPart is a part of an array buffer layout.
type arrayBufferLayoutPart struct {
// TODO: This struct should belong to a program and know it.
name string
num int
}
// arrayBufferLayout is an array buffer layout.
//
// An array buffer in OpenGL is a buffer representing vertices and
// is passed to a vertex shader.
type arrayBufferLayout struct {
parts []arrayBufferLayoutPart
total int
}
func (a *arrayBufferLayout) names() []string {
ns := make([]string, len(a.parts))
for i, p := range a.parts {
ns[i] = p.name
}
return ns
}
// totalBytes returns the size in bytes for one element of the array buffer.
func (a *arrayBufferLayout) totalBytes() int {
if a.total != 0 {
return a.total
}
t := 0
for _, p := range a.parts {
t += floatSizeInBytes * p.num
}
a.total = t
return a.total
}
// newArrayBuffer creates OpenGL's buffer object for the array buffer.
func (a *arrayBufferLayout) newArrayBuffer(context *context) buffer {
return context.newArrayBuffer(a.totalBytes() * graphics.IndicesNum)
}
// enable starts using the array buffer.
func (a *arrayBufferLayout) enable(context *context) {
for i := range a.parts {
context.enableVertexAttribArray(i)
}
total := a.totalBytes()
offset := 0
for i, p := range a.parts {
context.vertexAttribPointer(i, p.num, total, offset)
offset += floatSizeInBytes * p.num
}
}
// disable stops using the array buffer.
func (a *arrayBufferLayout) disable(context *context) {
// TODO: Disabling should be done in reversed order?
for i := range a.parts {
context.disableVertexAttribArray(i)
}
}
// theArrayBufferLayout is the array buffer layout for Ebiten.
var theArrayBufferLayout = arrayBufferLayout{
// Note that GL_MAX_VERTEX_ATTRIBS is at least 16.
parts: []arrayBufferLayoutPart{
{
name: "A0",
num: 2,
},
{
name: "A1",
num: 2,
},
{
name: "A2",
num: 4,
},
},
}
func init() {
vertexFloatNum := theArrayBufferLayout.totalBytes() / floatSizeInBytes
if graphics.VertexFloatNum != vertexFloatNum {
panic(fmt.Sprintf("vertex float num must be %d but %d", graphics.VertexFloatNum, vertexFloatNum))
}
}
type programKey struct {
useColorM bool
filter graphicsdriver.Filter
address graphicsdriver.Address
}
// openGLState is a state for
type openGLState struct {
// arrayBuffer is OpenGL's array buffer (vertices data).
arrayBuffer buffer
// elementArrayBuffer is OpenGL's element array buffer (indices data).
elementArrayBuffer buffer
// programs is OpenGL's program for rendering a texture.
programs map[programKey]program
lastProgram program
lastUniforms map[string][]float32
lastActiveTexture int
}
var (
zeroBuffer buffer
zeroProgram program
)
// reset resets or initializes the OpenGL state.
func (s *openGLState) reset(context *context) error {
if err := context.reset(); err != nil {
return err
}
s.lastProgram = zeroProgram
context.useProgram(zeroProgram)
for key := range s.lastUniforms {
delete(s.lastUniforms, key)
}
// When context lost happens, deleting programs or buffers is not necessary.
// However, it is not assumed that reset is called only when context lost happens.
// Let's delete them explicitly.
if s.programs == nil {
s.programs = map[programKey]program{}
} else {
for k, p := range s.programs {
context.deleteProgram(p)
delete(s.programs, k)
}
}
// On browsers (at least Chrome), buffers are already detached from the context
// and must not be deleted by DeleteBuffer.
if runtime.GOOS != "js" {
if !s.arrayBuffer.equal(zeroBuffer) {
context.deleteBuffer(s.arrayBuffer)
}
if !s.elementArrayBuffer.equal(zeroBuffer) {
context.deleteBuffer(s.elementArrayBuffer)
}
}
shaderVertexModelviewNative, err := context.newVertexShader(vertexShaderStr())
if err != nil {
panic(fmt.Sprintf("graphics: shader compiling error:\n%s", err))
}
defer context.deleteShader(shaderVertexModelviewNative)
for _, c := range []bool{false, true} {
for _, a := range []graphicsdriver.Address{
graphicsdriver.AddressClampToZero,
graphicsdriver.AddressRepeat,
graphicsdriver.AddressUnsafe,
} {
for _, f := range []graphicsdriver.Filter{
graphicsdriver.FilterNearest,
graphicsdriver.FilterLinear,
graphicsdriver.FilterScreen,
} {
shaderFragmentColorMatrixNative, err := context.newFragmentShader(fragmentShaderStr(c, f, a))
if err != nil {
panic(fmt.Sprintf("graphics: shader compiling error:\n%s", err))
}
defer context.deleteShader(shaderFragmentColorMatrixNative)
program, err := context.newProgram([]shader{
shaderVertexModelviewNative,
shaderFragmentColorMatrixNative,
}, theArrayBufferLayout.names())
if err != nil {
return err
}
s.programs[programKey{
useColorM: c,
filter: f,
address: a,
}] = program
}
}
}
s.arrayBuffer = theArrayBufferLayout.newArrayBuffer(context)
// Note that the indices passed to NewElementArrayBuffer is not under GC management
// in opengl package due to unsafe-way.
// See NewElementArrayBuffer in context_mobile.go.
s.elementArrayBuffer = context.newElementArrayBuffer(graphics.IndicesNum * 2)
return nil
}
// areSameFloat32Array returns a boolean indicating if a and b are deeply equal.
func areSameFloat32Array(a, b []float32) bool {
if len(a) != len(b) {
return false
}
for i := 0; i < len(a); i++ {
if a[i] != b[i] {
return false
}
}
return true
}
type uniformVariable struct {
name string
value []float32
typ shaderir.Type
}
type textureVariable struct {
valid bool
native textureNative
}
func (g *Graphics) textureVariableName(idx int) string {
if v, ok := g.textureVariableNameCache[idx]; ok {
return v
}
if g.textureVariableNameCache == nil {
g.textureVariableNameCache = map[int]string{}
}
name := fmt.Sprintf("T%d", idx)
g.textureVariableNameCache[idx] = name
return name
}
// useProgram uses the program (programTexture).
func (g *Graphics) useProgram(program program, uniforms []uniformVariable, textures [graphics.ShaderImageNum]textureVariable) error {
if !g.state.lastProgram.equal(program) {
g.context.useProgram(program)
if g.state.lastProgram.equal(zeroProgram) {
theArrayBufferLayout.enable(&g.context)
g.context.bindArrayBuffer(g.state.arrayBuffer)
g.context.bindElementArrayBuffer(g.state.elementArrayBuffer)
}
g.state.lastProgram = program
for k := range g.state.lastUniforms {
delete(g.state.lastUniforms, k)
}
g.state.lastActiveTexture = 0
g.context.activeTexture(0)
}
for _, u := range uniforms {
if got, expected := len(u.value), u.typ.FloatNum(); got != expected {
// Copy a shaderir.Type value once. Do not pass u.typ directly to fmt.Errorf arguments, or
// the value u would be allocated on heap.
typ := u.typ
return fmt.Errorf("opengl: length of a uniform variables %s (%s) doesn't match: expected %d but %d", u.name, typ.String(), expected, got)
}
cached, ok := g.state.lastUniforms[u.name]
if ok && areSameFloat32Array(cached, u.value) {
continue
}
g.context.uniformFloats(program, u.name, u.value, u.typ)
if g.state.lastUniforms == nil {
g.state.lastUniforms = map[string][]float32{}
}
g.state.lastUniforms[u.name] = u.value
}
var idx int
loop:
for i, t := range textures {
if !t.valid {
continue
}
// If the texture is already bound, set the texture variable to point to the texture.
// Rebinding the same texture seems problematic (#1193).
for _, at := range g.activatedTextures {
if t.native.equal(at.textureNative) {
g.context.uniformInt(program, g.textureVariableName(i), at.index)
continue loop
}
}
g.activatedTextures = append(g.activatedTextures, activatedTexture{
textureNative: t.native,
index: idx,
})
g.context.uniformInt(program, g.textureVariableName(i), idx)
if g.state.lastActiveTexture != idx {
g.context.activeTexture(idx)
g.state.lastActiveTexture = idx
}
// Apparently, a texture must be bound every time. The cache is not used here.
g.context.bindTexture(t.native)
idx++
}
for i := range g.activatedTextures {
g.activatedTextures[i] = activatedTexture{}
}
g.activatedTextures = g.activatedTextures[:0]
return nil
}