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vertex.go
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vertex.go
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package glhf
import (
"fmt"
"runtime"
"github.com/go-gl/gl/v3.3-core/gl"
"github.com/magiccap/MagicCap/mainthread"
"github.com/pkg/errors"
)
// VertexSlice points to a portion of (or possibly whole) vertex array. It is used as a pointer,
// contrary to Go's builtin slices. This is, so that append can be 'in-place'. That's for the good,
// because Begin/End-ing a VertexSlice would become super confusing, if append returned a new
// VertexSlice.
//
// It also implements all basic slice-like operations: appending, sub-slicing, etc.
//
// Note that you need to Begin a VertexSlice before getting or updating it's elements or drawing it.
// After you're done with it, you need to End it.
type VertexSlice struct {
va *vertexArray
i, j int
}
// MakeVertexSlice allocates a new vertex array with specified capacity and returns a VertexSlice
// that points to it's first len elements.
//
// Note, that a vertex array is specialized for a specific shader and can't be used with another
// shader.
func MakeVertexSlice(shader *Shader, len, cap int) *VertexSlice {
if len > cap {
panic("failed to make vertex slice: len > cap")
}
return &VertexSlice{
va: newVertexArray(shader, cap),
i: 0,
j: len,
}
}
// VertexFormat returns the format of vertex attributes inside the underlying vertex array of this
// VertexSlice.
func (vs *VertexSlice) VertexFormat() AttrFormat {
return vs.va.format
}
// Delete is used to manually delete a texture.
func (vs *VertexSlice) Delete() {
vs.va.checkDeleted()
vs.va.delete()
}
// Stride returns the number of float32 elements occupied by one vertex.
func (vs *VertexSlice) Stride() int {
return vs.va.stride / 4
}
// Len returns the length of the VertexSlice (number of vertices).
func (vs *VertexSlice) Len() int {
return vs.j - vs.i
}
// Cap returns the capacity of an underlying vertex array.
func (vs *VertexSlice) Cap() int {
return vs.va.cap - vs.i
}
// SetLen resizes the VertexSlice to length len.
func (vs *VertexSlice) SetLen(len int) {
vs.End() // vs must have been Begin-ed before calling this method
*vs = vs.grow(len)
vs.Begin()
}
// grow returns supplied vs with length changed to len. Allocates new underlying vertex array if
// necessary. The original content is preserved.
func (vs VertexSlice) grow(len int) VertexSlice {
if len <= vs.Cap() {
// capacity sufficient
return VertexSlice{
va: vs.va,
i: vs.i,
j: vs.i + len,
}
}
// grow the capacity
newCap := vs.Cap()
if newCap < 1024 {
newCap += newCap
} else {
newCap += newCap / 4
}
if newCap < len {
newCap = len
}
newVs := VertexSlice{
va: newVertexArray(vs.va.shader, newCap),
i: 0,
j: len,
}
// preserve the original content
newVs.Begin()
newVs.Slice(0, vs.Len()).SetVertexData(vs.VertexData())
newVs.End()
return newVs
}
// Slice returns a sub-slice of this VertexSlice covering the range [i, j) (relative to this
// VertexSlice).
//
// Note, that the returned VertexSlice shares an underlying vertex array with the original
// VertexSlice. Modifying the contents of one modifies corresponding contents of the other.
func (vs *VertexSlice) Slice(i, j int) *VertexSlice {
if i < 0 || j < i || j > vs.va.cap {
panic("failed to slice vertex slice: index out of range")
}
return &VertexSlice{
va: vs.va,
i: vs.i + i,
j: vs.i + j,
}
}
// SetVertexData sets the contents of the VertexSlice.
//
// The data is a slice of float32's, where each vertex attribute occupies a certain number of
// elements. Namely, Float occupies 1, Vec2 occupies 2, Vec3 occupies 3 and Vec4 occupies 4. The
// attribues in the data slice must be in the same order as in the vertex format of this Vertex
// Slice.
//
// If the length of vertices does not match the length of the VertexSlice, this methdo panics.
func (vs *VertexSlice) SetVertexData(data []float32) {
if len(data)/vs.Stride() != vs.Len() {
fmt.Println(len(data)/vs.Stride(), vs.Len())
panic("set vertex data: wrong length of vertices")
}
vs.va.setVertexData(vs.i, vs.j, data)
}
// VertexData returns the contents of the VertexSlice.
//
// The data is in the same format as with SetVertexData.
func (vs *VertexSlice) VertexData() []float32 {
return vs.va.vertexData(vs.i, vs.j)
}
// Draw draws the content of the VertexSlice.
func (vs *VertexSlice) Draw() {
vs.va.draw(vs.i, vs.j)
}
// Begin binds the underlying vertex array. Calling this method is necessary before using the VertexSlice.
func (vs *VertexSlice) Begin() {
vs.va.begin()
}
// End unbinds the underlying vertex array. Call this method when you're done with VertexSlice.
func (vs *VertexSlice) End() {
vs.va.end()
}
type vertexArray struct {
vao, vbo binder
cap int
format AttrFormat
stride int
offset []int
shader *Shader
deleted bool
}
const vertexArrayMinCap = 4
func newVertexArray(shader *Shader, cap int) *vertexArray {
if cap < vertexArrayMinCap {
cap = vertexArrayMinCap
}
va := &vertexArray{
vao: binder{
restoreLoc: gl.VERTEX_ARRAY_BINDING,
bindFunc: func(obj uint32) {
gl.BindVertexArray(obj)
},
},
vbo: binder{
restoreLoc: gl.ARRAY_BUFFER_BINDING,
bindFunc: func(obj uint32) {
gl.BindBuffer(gl.ARRAY_BUFFER, obj)
},
},
cap: cap,
format: shader.VertexFormat(),
stride: shader.VertexFormat().Size(),
offset: make([]int, len(shader.VertexFormat())),
shader: shader,
}
offset := 0
for i, attr := range va.format {
switch attr.Type {
case Float, Vec2, Vec3, Vec4:
default:
panic(errors.New("failed to create vertex array: invalid attribute type"))
}
va.offset[i] = offset
offset += attr.Type.Size()
}
gl.GenVertexArrays(1, &va.vao.obj)
va.vao.bind()
gl.GenBuffers(1, &va.vbo.obj)
defer va.vbo.bind().restore()
emptyData := make([]byte, cap*va.stride)
gl.BufferData(gl.ARRAY_BUFFER, len(emptyData), gl.Ptr(emptyData), gl.DYNAMIC_DRAW)
for i, attr := range va.format {
loc := gl.GetAttribLocation(shader.program.obj, gl.Str(attr.Name+"\x00"))
var size int32
switch attr.Type {
case Float:
size = 1
case Vec2:
size = 2
case Vec3:
size = 3
case Vec4:
size = 4
}
gl.VertexAttribPointer(
uint32(loc),
size,
gl.FLOAT,
false,
int32(va.stride),
gl.PtrOffset(va.offset[i]),
)
gl.EnableVertexAttribArray(uint32(loc))
}
va.vao.restore()
runtime.SetFinalizer(va, (*vertexArray).delete)
return va
}
func (va *vertexArray) checkDeleted() {
if va.deleted {
panic("vertex array was already deleted")
}
}
func (va *vertexArray) delete() {
if !va.deleted {
go mainthread.ExecMainThread(func() {
gl.DeleteVertexArrays(1, &va.vao.obj)
gl.DeleteBuffers(1, &va.vbo.obj)
})
va.deleted = true
}
}
func (va *vertexArray) begin() {
va.checkDeleted()
va.vao.bind()
va.vbo.bind()
}
func (va *vertexArray) end() {
va.checkDeleted()
va.vbo.restore()
va.vao.restore()
}
func (va *vertexArray) draw(i, j int) {
va.checkDeleted()
gl.DrawArrays(gl.TRIANGLES, int32(i), int32(j-i))
}
func (va *vertexArray) setVertexData(i, j int, data []float32) {
va.checkDeleted()
if j-i == 0 {
// avoid setting 0 bytes of buffer data
return
}
gl.BufferSubData(gl.ARRAY_BUFFER, i*va.stride, len(data)*4, gl.Ptr(data))
}
func (va *vertexArray) vertexData(i, j int) []float32 {
va.checkDeleted()
if j-i == 0 {
// avoid getting 0 bytes of buffer data
return nil
}
data := make([]float32, (j-i)*va.stride/4)
gl.GetBufferSubData(gl.ARRAY_BUFFER, i*va.stride, len(data)*4, gl.Ptr(data))
return data
}