func main() {
// Initialize GLFW for window management
glfw.SetErrorCallback(glfwErrorCallback)
if !glfw.Init() {
panic("failed to initialize glfw")
}
defer glfw.Terminate()
glfw.WindowHint(glfw.Resizable, glfw.False)
glfw.WindowHint(glfw.ContextVersionMajor, 3)
glfw.WindowHint(glfw.ContextVersionMinor, 3)
glfw.WindowHint(glfw.OpenglForwardCompatible, glfw.True) // Necessary for OS X
glfw.WindowHint(glfw.OpenglProfile, glfw.OpenglCoreProfile) // Necessary for OS X
glfw.WindowHint(glfw.OpenglDebugContext, glfw.True)
window, err := glfw.CreateWindow(WindowWidth, WindowHeight, "Cube", nil, nil)
if err != nil {
panic(err)
}
window.MakeContextCurrent()
// Initialize Glow
if err := gl.Init(); err != nil {
panic(err)
}
// Note that it is possible to use GL functions spanning multiple versions
if err := gl4.Init(); err != nil {
fmt.Printf("Could not initialize GL 4.4 (non-fatal)")
}
if gl.ARB_debug_output {
gl.Enable(gl.DEBUG_OUTPUT_SYNCHRONOUS_ARB)
gl.DebugMessageCallbackARB(gl.DebugProc(glDebugCallback), gl.Ptr(nil))
// Trigger an error to demonstrate debug output
gl.Enable(gl.CONTEXT_FLAGS)
}
version := gl.GoStr(gl.GetString(gl.VERSION))
fmt.Println("OpenGL version", version)
// Configure the vertex and fragment shaders
program, err := newProgram(vertexShader, fragmentShader)
if err != nil {
panic(err)
}
gl.UseProgram(program)
projection := mgl32.Perspective(70.0, float32(WindowWidth)/WindowHeight, 0.1, 10.0)
projectionUniform := gl.GetUniformLocation(program, gl.Str("projection\x00"))
gl.UniformMatrix4fv(projectionUniform, 1, false, &projection[0])
camera := mgl32.LookAtV(mgl32.Vec3{3, 3, 3}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
model := mgl32.Ident4()
modelUniform := gl.GetUniformLocation(program, gl.Str("model\x00"))
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
textureUniform := gl.GetUniformLocation(program, gl.Str("tex\x00"))
gl.Uniform1i(textureUniform, 0)
gl.BindFragDataLocation(program, 0, gl.Str("outputColor\x00"))
// Load the texture
texture, err := newTexture("square.png")
if err != nil {
panic(err)
}
// Configure the vertex data
var vao uint32
gl.GenVertexArrays(1, &vao)
gl.BindVertexArray(vao)
var vbo uint32
gl.GenBuffers(1, &vbo)
gl.BindBuffer(gl.ARRAY_BUFFER, vbo)
gl.BufferData(gl.ARRAY_BUFFER, len(cubeVertices)*4, gl.Ptr(cubeVertices), gl.STATIC_DRAW)
vertAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, 5*4, gl.PtrOffset(0))
texCoordAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vertTexCoord\x00")))
gl.EnableVertexAttribArray(texCoordAttrib)
gl.VertexAttribPointer(texCoordAttrib, 2, gl.FLOAT, false, 5*4, gl.PtrOffset(3*4))
// Configure global settings
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(1.0, 1.0, 1.0, 1.0)
angle := 0.0
previousTime := glfw.GetTime()
for !window.ShouldClose() {
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
// Update
time := glfw.GetTime()
elapsed := time - previousTime
previousTime = time
angle += elapsed
model = mgl32.HomogRotate3D(float32(angle), mgl32.Vec3{0, 1, 0})
// Render
gl.UseProgram(program)
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
gl.BindVertexArray(vao)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, texture)
gl.DrawArrays(gl.TRIANGLES, 0, 6*2*3)
// Maintenance
window.SwapBuffers()
glfw.PollEvents()
}
}
func onStart(glctx gl.Context, sz size.Event) {
log.Printf("creating GL program")
var err error
keystate = map[touch.Sequence]int{}
program, err = glutil.CreateProgram(glctx, vertexShader, fragmentShader)
if err != nil {
log.Printf("error creating GL program: %v", err)
return
}
glctx.Enable(gl.DEPTH_TEST)
position = glctx.GetAttribLocation(program, "position")
texCordIn = glctx.GetAttribLocation(program, "texCordIn")
color = glctx.GetUniformLocation(program, "color")
drawi = glctx.GetUniformLocation(program, "drawi")
projection = glctx.GetUniformLocation(program, "projection")
camera = glctx.GetUniformLocation(program, "camera")
loadTexture(glctx)
glctx.UseProgram(program)
projectionMat := mgl32.Perspective(mgl32.DegToRad(75.0), float32(1), 0.5, 40.0)
glctx.UniformMatrix4fv(projection, projectionMat[:])
cameraMat := mgl32.LookAtV(mgl32.Vec3{0.5, 0, 1.5}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
glctx.UniformMatrix4fv(camera, cameraMat[:])
board = NewBoard(glctx, float32(0.05), 10)
numKeys := len(board.bigKeys) + len(board.smallKeys)
InitializeSound(numKeys)
}
//
// Draw Loop Function
// This function gets called on every update.
//
func drawLoop(glw *wrapper.Glw) {
// Sets the Clear Color (Background Color)
gl.ClearColor(0.0, 0.0, 0.0, 1.0)
// Clears the Window
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
// Enables Depth
gl.Enable(gl.DEPTH_TEST)
// Sets the Shader program to Use
gl.UseProgram(shaderProgram)
// Define the model transformations for the cube
cube.ResetModel()
cube.Translate(x+0.5, y, z)
cube.Scale(scale, scale, scale) //scale equally in all axis
cube.Rotate(-angle_x, mgl32.Vec3{1, 0, 0}) //rotating in clockwise direction around x-axis
cube.Rotate(-angle_y, mgl32.Vec3{0, 1, 0}) //rotating in clockwise direction around y-axis
cube.Rotate(-angle_z, mgl32.Vec3{0, 0, 1}) //rotating in clockwise direction around z-axis
// Define the model transformations for our sphere
sphere.ResetModel()
sphere.Translate(-x-0.5, 0, 0)
sphere.Scale(scale/3.0, scale/3.0, scale/3.0) //scale equally in all axis
sphere.Rotate(-angle_x, mgl32.Vec3{1, 0, 0}) //rotating in clockwise direction around x-axis
sphere.Rotate(-angle_y, mgl32.Vec3{0, 1, 0}) //rotating in clockwise direction around y-axis
sphere.Rotate(-angle_z, mgl32.Vec3{0, 0, 1}) //rotating in clockwise direction around z-axis
// Projection matrix : 45° Field of View, 4:3 ratio, display range : 0.1 unit <-> 100 units
var Projection mgl32.Mat4 = mgl32.Perspective(30.0, aspect_ratio, 0.1, 100.0)
// Camera matrix
var View mgl32.Mat4 = mgl32.LookAtV(
mgl32.Vec3{0, 0, 4}, // Camera is at (0,0,4), in World Space
mgl32.Vec3{0, 0, 0}, // and looks at the origin
mgl32.Vec3{0, 1, 0}, // Head is up (set to 0,-1,0 to look upside-down)
)
// Send our uniforms variables to the currently bound shader,
gl.Uniform1ui(colourmodeUniform, uint32(colourmode))
gl.UniformMatrix4fv(viewUniform, 1, false, &View[0])
gl.UniformMatrix4fv(projectionUniform, 1, false, &Projection[0])
// Draws the Cube
gl.UniformMatrix4fv(modelUniform, 1, false, &cube.Model[0])
cube.Draw()
// Draw our sphere
gl.UniformMatrix4fv(modelUniform, 1, false, &sphere.Model[0])
sphere.DrawSphere()
gl.DisableVertexAttribArray(0)
gl.UseProgram(0)
/* Modify our animation variables */
angle_x += angle_inc_x
angle_y += angle_inc_y
angle_z += angle_inc_z
}
func (c *Camera) Draw(program uint32) {
//c.UpdateCamera()
camera := mgl32.LookAtV(c.position, c.position.Add(c.direction), c.up)
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
}
func Start(windowName string) error {
err := llgl.InitDisplay(windowName)
if err != nil {
return err
}
err = llgl.InitGL()
if err != nil {
return err
}
glstate.program, err = loadShaders("cube.vert", "cube.frag")
if err != nil {
return err
}
glstate.program.Use()
glstate.projectionUL = glstate.program.Uniform("projection")
glstate.cameraUL = glstate.program.Uniform("camera")
glstate.modelUL = glstate.program.Uniform("model")
glstate.texUL = glstate.program.Uniform("tex")
state.camera = mgl.LookAtV(mgl.Vec3{3, 3, 3}, mgl.Vec3{0, 0, 0}, mgl.Vec3{0, 1, 0})
state.model = mgl.Ident4()
glstate.cameraUL.SetMat4(state.camera)
glstate.modelUL.SetMat4(state.model)
glstate.texUL.SetTextureSlot(0)
glstate.program.BindFragDataLocation(0, "outputColor")
texturePath, err := assets.Locate("code.png")
if err != nil {
return err
}
texture, err := llgl.MakeTexture(0, texturePath)
if err != nil {
return err
}
texture.Bind(0)
// Configure the vertex data
vao := llgl.NewVertexArray()
vao.Bind()
glstate.vbo = llgl.NewVertexBuffer()
glstate.vbo.Bind()
val := glstate.program.VertexAttrib("vert")
val.Enable()
val.PointerFloat32(3, 5, 0)
valTC := glstate.program.VertexAttrib("vertTexCoord")
valTC.Enable()
valTC.PointerFloat32(2, 5, 3)
fpsCounter = NewFpsCounter()
return nil
}
// Load loads and sets up the model
func (m *Model) Load(fileName string) {
m.loadFile(fileName)
shader := sm.Shader{VertSrcFile: m.data.VertShaderFile, FragSrcFile: m.data.FragShaderFile, Name: fmt.Sprintf("%s:%s", m.data.VertShaderFile, m.data.FragShaderFile)}
program, err := m.shaders.LoadProgram(shader, false)
if err != nil {
return
}
m.currentProgram = program
gl.UseProgram(m.currentProgram)
m.projection = mgl32.Perspective(mgl32.DegToRad(45.0), float32(windowWidth)/windowHeight, 0.1, 10.0)
m.projectionUniform = gl.GetUniformLocation(m.currentProgram, gl.Str("projection\x00"))
gl.UniformMatrix4fv(m.projectionUniform, 1, false, &m.projection[0])
m.camera = mgl32.LookAtV(mgl32.Vec3{3, 3, 3}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
m.cameraUniform = gl.GetUniformLocation(m.currentProgram, gl.Str("camera\x00"))
gl.UniformMatrix4fv(m.cameraUniform, 1, false, &m.camera[0])
m.modelUniform = gl.GetUniformLocation(m.currentProgram, gl.Str("model\x00"))
gl.UniformMatrix4fv(m.modelUniform, 1, false, &m.model[0])
m.textureUniform = gl.GetUniformLocation(m.currentProgram, gl.Str("tex\x00"))
gl.Uniform1i(m.textureUniform, 0)
gl.BindFragDataLocation(m.currentProgram, 0, gl.Str("outputColor\x00"))
// Load the texture
m.textures.LoadTexture(m.data.TextureFile, m.data.TextureFile)
// Configure the vertex data
gl.GenVertexArrays(1, &m.vao)
gl.BindVertexArray(m.vao)
var vbo uint32
gl.GenBuffers(1, &vbo)
gl.BindBuffer(gl.ARRAY_BUFFER, vbo)
gl.BufferData(gl.ARRAY_BUFFER, len(m.data.Verts)*4, gl.Ptr(m.data.Verts), gl.STATIC_DRAW)
vertAttrib := uint32(gl.GetAttribLocation(m.currentProgram, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, m.data.VertSize*4, gl.PtrOffset(0)) // 4:number of bytes in a float32
texCoordAttrib := uint32(gl.GetAttribLocation(m.currentProgram, gl.Str("vertTexCoord\x00")))
gl.EnableVertexAttribArray(texCoordAttrib)
gl.VertexAttribPointer(texCoordAttrib, 2, gl.FLOAT, true, m.data.VertSize*4, gl.PtrOffset(3*4)) // 4:number of bytes in a float32
if m.data.Indexed {
var indices uint32
gl.GenBuffers(1, &indices)
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, indices)
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, len(m.data.Indices)*4, gl.Ptr(m.data.Indices), gl.STATIC_DRAW)
}
gl.BindVertexArray(0)
}
// LookAt changes the transformation of the 3D object
// to face the target's position. The model matrix
// will be updated accordingly.
//
// Note: This transformation makes use of the up vector.
func (t *Transform) LookAt(x, y, z float32) {
target := mgl32.Vec3{x, y, z}
t.matrix = mgl32.LookAtV(
t.position,
target,
t.Up,
).Inv()
}
func (e *Engine) Draw(c size.Event) {
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0.2, 0.2, 0.2, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
m := mgl32.Perspective(0.785, float32(c.WidthPt/c.HeightPt), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projection, m[:])
eye := mgl32.Vec3{0, 0, 8}
center := mgl32.Vec3{0, 0, 0}
up := mgl32.Vec3{0, 1, 0}
m = mgl32.LookAtV(eye, center, up)
gl.UniformMatrix4fv(e.shader.view, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLoc.X/c.WidthPt-0.5)*3.14*2, mgl32.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.modelx, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLoc.Y/c.HeightPt-0.5)*3.14, mgl32.Vec3{1, 0, 0})
gl.UniformMatrix4fv(e.shader.modely, m[:])
coordsPerVertex := 3
for _, obj := range e.shape.Objs {
gl.BindBuffer(gl.ARRAY_BUFFER, obj.coord)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, coordsPerVertex, gl.FLOAT, false, 12, 0)
if obj.useuv == true {
gl.Uniform1i(e.shader.useuv, 1)
texCoordsPerVertex := 2
gl.BindBuffer(gl.ARRAY_BUFFER, obj.uvcoord)
gl.EnableVertexAttribArray(e.shader.vertTexCoord)
gl.VertexAttribPointer(e.shader.vertTexCoord, texCoordsPerVertex, gl.FLOAT, false, 8, 0)
gl.BindTexture(gl.TEXTURE_2D, obj.tex)
} else {
gl.Uniform1i(e.shader.useuv, 0)
gl.Uniform4f(e.shader.color, obj.color[0], obj.color[1], obj.color[2], obj.color[3])
}
gl.DrawArrays(gl.TRIANGLES, 0, obj.vcount)
if obj.useuv {
gl.DisableVertexAttribArray(e.shader.vertTexCoord)
}
gl.DisableVertexAttribArray(e.shader.vertCoord)
}
debug.DrawFPS(c)
}
func (e *Engine) Draw(c size.Event) {
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0.5, 0.8, 0.8, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
gl.Uniform3fv(e.shader.lightdir, []float32{0.5, 0.6, 0.7})
m := mgl32.Perspective(1.3, float32(c.WidthPt/c.HeightPt), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projectionmatrix, m[:])
eye := mgl32.Vec3{0, 0, 0.2}
center := mgl32.Vec3{0, 0, 0}
up := mgl32.Vec3{0, 1, 0}
m = mgl32.LookAtV(eye, center, up)
gl.UniformMatrix4fv(e.shader.viewmatrix, m[:])
m = mgl32.HomogRotate3D((e.touchx/float32(c.WidthPt)-0.5)*6.28, mgl32.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.modelmatrix, m[:])
m = mgl32.HomogRotate3D((e.touchx/float32(c.WidthPt)-0.5)*6.28, mgl32.Vec3{0, -1, 0})
gl.UniformMatrix4fv(e.shader.lightmatrix, m[:])
coordsPerVertex := 3
for _, obj := range e.shape.Objs {
gl.BindBuffer(gl.ARRAY_BUFFER, obj.coord)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, coordsPerVertex, gl.FLOAT, false, 12, 0)
texCoordsPerVertex := 2
gl.BindBuffer(gl.ARRAY_BUFFER, obj.uvcoord)
gl.EnableVertexAttribArray(e.shader.texcoord)
gl.VertexAttribPointer(e.shader.texcoord, texCoordsPerVertex, gl.FLOAT, false, 8, 0)
gl.BindBuffer(gl.ARRAY_BUFFER, obj.normal)
gl.EnableVertexAttribArray(e.shader.normal)
gl.VertexAttribPointer(e.shader.normal, 3, gl.FLOAT, false, 12, 0)
gl.BindTexture(gl.TEXTURE_2D, obj.tex)
gl.DrawArrays(gl.TRIANGLES, 0, obj.vcount)
gl.DisableVertexAttribArray(e.shader.texcoord)
gl.DisableVertexAttribArray(e.shader.normal)
gl.DisableVertexAttribArray(e.shader.vertCoord)
}
debug.DrawFPS(c)
}
func (me *test) Display(c *Core) {
me.o1.Draw(c)
me.o2.Draw(c)
projection := mgl32.Perspective(mgl32.DegToRad(Fov), float32(WindowWidth)/WindowHeight, Near, Far)
view := mgl32.LookAtV(mgl32.Vec3{3, 3, 3}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
model := mgl32.Ident4()
MVP := projection.Mul4(view).Mul4(model)
gl.UniformMatrix4fv(mvpLoc, 1, false, &MVP[0])
gl.Uniform1i(TexLoc, 0)
}
func (c *Camera) GetMouseVector(windowSize mgl32.Vec2, mouse mgl32.Vec2) mgl32.Vec3 {
v, err := mgl32.UnProject(
mgl32.Vec3{mouse.X(), windowSize.Y() - mouse.Y(), 0.5},
mgl32.LookAtV(c.Translation, c.Lookat, c.Up),
mgl32.Perspective(mgl32.DegToRad(c.Angle), windowSize.X()/windowSize.Y(), c.Near, c.Far),
0, 0, int(windowSize.X()), int(windowSize.Y()),
)
if err == nil {
return v.Sub(c.Translation).Normalize()
} else {
log.Println("Error converting camera vector: ", err)
}
return c.Lookat
}
func (e *Engine) Draw(c size.Event) {
since := time.Now().Sub(e.started)
//gl.Enable()
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0, 0, 0, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
m := mgl32.Perspective(0.785, float32(c.WidthPt/c.HeightPt), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projection, m[:])
eye := mgl32.Vec3{3, 3, 3}
center := mgl32.Vec3{0, 0, 0}
up := mgl32.Vec3{0, 1, 0}
m = mgl32.LookAtV(eye, center, up)
gl.UniformMatrix4fv(e.shader.view, m[:])
m = mgl32.HomogRotate3D(float32(since.Seconds()), mgl32.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.model, m[:])
gl.BindBuffer(gl.ARRAY_BUFFER, e.shape.buf)
coordsPerVertex := 3
texCoordsPerVertex := 2
vertexCount := len(cubeData) / (coordsPerVertex + texCoordsPerVertex)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, coordsPerVertex, gl.FLOAT, false, 20, 0) // 4 bytes in float, 5 values per vertex
gl.EnableVertexAttribArray(e.shader.vertTexCoord)
gl.VertexAttribPointer(e.shader.vertTexCoord, texCoordsPerVertex, gl.FLOAT, false, 20, 12)
gl.BindTexture(gl.TEXTURE_2D, e.shape.texture)
gl.DrawArrays(gl.TRIANGLES, 0, vertexCount)
gl.DisableVertexAttribArray(e.shader.vertCoord)
debug.DrawFPS(c)
}
func (e *Engine) Draw(c event.Config) {
since := time.Now().Sub(e.started)
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0, 0, 0, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
// Setup MVP
var m mgl.Mat4
m = mgl.Perspective(0.785, float32(c.Width/c.Height), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projection, m[:])
m = mgl.LookAtV(
mgl.Vec3{3, 3, 3}, // eye
mgl.Vec3{0, 0, 0}, // center
mgl.Vec3{0, 1, 0}, // up
)
gl.UniformMatrix4fv(e.shader.view, m[:])
m = mgl.HomogRotate3D(float32(since.Seconds()), mgl.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.model, m[:])
// Draw our shape
gl.BindBuffer(gl.ARRAY_BUFFER, e.shape.buf)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, e.shape.coordsPerVertex, gl.FLOAT, false, 20, 0) // 4 bytes in float, 5 values per vertex
gl.EnableVertexAttribArray(e.shader.vertTexCoord)
gl.VertexAttribPointer(e.shader.vertTexCoord, e.shape.texCoordsPerVertex, gl.FLOAT, false, 20, 12)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, e.shape.texture)
gl.DrawArrays(gl.TRIANGLES, 0, e.shape.vertexCount)
gl.DisableVertexAttribArray(e.shader.vertCoord)
//debug.DrawFPS(c)
}
func (e *Engine) Draw(c size.Event) {
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0, 0, 0, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
m := mgl32.Perspective(0.785, float32(c.WidthPt/c.HeightPt), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projection, m[:])
eye := mgl32.Vec3{0, 3, 3}
center := mgl32.Vec3{0, 0, 0}
up := mgl32.Vec3{0, 1, 0}
m = mgl32.LookAtV(eye, center, up)
gl.UniformMatrix4fv(e.shader.view, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLocX*5/c.WidthPt), mgl32.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.modelx, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLocY*5/c.HeightPt), mgl32.Vec3{1, 0, 0})
gl.UniformMatrix4fv(e.shader.modely, m[:])
gl.BindBuffer(gl.ARRAY_BUFFER, e.shape.buf)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, coordsPerVertex, gl.FLOAT, false, 0, 0)
gl.BindBuffer(gl.ARRAY_BUFFER, e.shape.colorbuf)
gl.EnableVertexAttribArray(e.shader.color)
gl.VertexAttribPointer(e.shader.color, colorsPerVertex, gl.FLOAT, false, 0, 0) //更新color值
gl.DrawArrays(gl.TRIANGLES, 0, vertexCount)
gl.DisableVertexAttribArray(e.shader.vertCoord)
gl.DisableVertexAttribArray(e.shader.color)
debug.DrawFPS(c)
}
func (e *Engine) Draw(c size.Event) {
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0.2, 0.2, 0.2, 1)
gl.Clear(gl.COLOR_BUFFER_BIT)
gl.Clear(gl.DEPTH_BUFFER_BIT)
gl.UseProgram(e.shader.program)
m := mgl32.Perspective(0.785, float32(c.WidthPt/c.HeightPt), 0.1, 10.0)
gl.UniformMatrix4fv(e.shader.projection, m[:])
eye := mgl32.Vec3{0, 0, 5}
center := mgl32.Vec3{0, 0, 0}
up := mgl32.Vec3{0, 1, 0}
m = mgl32.LookAtV(eye, center, up)
gl.UniformMatrix4fv(e.shader.view, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLoc.X*10/c.WidthPt), mgl32.Vec3{0, 1, 0})
gl.UniformMatrix4fv(e.shader.modelx, m[:])
m = mgl32.HomogRotate3D(float32(e.touchLoc.Y*10/c.HeightPt), mgl32.Vec3{1, 0, 0})
gl.UniformMatrix4fv(e.shader.modely, m[:])
coordsPerVertex := 3
for _, buf := range e.shape.bufs {
gl.BindBuffer(gl.ARRAY_BUFFER, buf.coord)
gl.EnableVertexAttribArray(e.shader.vertCoord)
gl.VertexAttribPointer(e.shader.vertCoord, coordsPerVertex, gl.FLOAT, false, 0, 0)
gl.Uniform4f(e.shader.color, buf.color[0], buf.color[1], buf.color[2], buf.color[3])
gl.DrawArrays(gl.TRIANGLES, 0, buf.vcount)
gl.DisableVertexAttribArray(e.shader.vertCoord)
}
debug.DrawFPS(c)
}
func main() {
// init glfw
if err := glfw.Init(); err != nil {
panic(err)
}
defer glfw.Terminate()
glfw.WindowHint(glfw.Resizable, glfw.False)
glfw.WindowHint(glfw.ContextVersionMajor, 4)
glfw.WindowHint(glfw.ContextVersionMinor, 1)
glfw.WindowHint(glfw.OpenGLProfile, glfw.OpenGLCoreProfile)
glfw.WindowHint(glfw.OpenGLForwardCompatible, glfw.True)
// make an application window
window, err := glfw.CreateWindow(windowWidth, windowHeight, "Transform", nil, nil)
if err != nil {
panic(err)
}
window.MakeContextCurrent()
// init gl
if err := gl.Init(); err != nil {
panic(err)
}
fmt.Println("OpenGL version", gl.GoStr(gl.GetString(gl.VERSION)))
// create vertex & fragment shader
program, err := newProgram(vertexShader, fragmentShader)
if err != nil {
panic(err)
}
gl.UseProgram(program)
projection := mgl32.Perspective(mgl32.DegToRad(45.0), float32(windowWidth)/windowHeight, 0.1, 10.0)
projectionUniform := gl.GetUniformLocation(program, gl.Str("projection\x00"))
gl.UniformMatrix4fv(projectionUniform, 1, false, &projection[0])
camera := mgl32.LookAtV(
mgl32.Vec3{3, 3, 3},
mgl32.Vec3{0, 0, 0},
mgl32.Vec3{0, 1, 0},
)
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
model := mgl32.Ident4()
modelUniform := gl.GetUniformLocation(program, gl.Str("model\x00"))
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
gl.BindFragDataLocation(program, 0, gl.Str("vert\x00"))
points := []float32{
-0.9, -0.9, -0.9,
0.9, -0.9, -0.9,
0.9, -0.9, 0.9,
-0.9, -0.9, 0.9,
-0.9, 0.9, -0.9,
0.9, 0.9, -0.9,
0.9, 0.9, 0.9,
-0.9, 0.9, 0.9,
}
vertices := []uint32{
0, 1,
1, 2,
2, 3,
3, 0,
0, 4,
1, 5,
2, 6,
3, 7,
4, 5,
5, 6,
6, 7,
7, 4,
}
// configure the vertex data
var vao uint32
gl.GenVertexArrays(1, &vao)
gl.BindVertexArray(vao)
defer gl.BindVertexArray(0)
var vbo uint32
gl.GenBuffers(1, &vbo)
gl.BindBuffer(gl.ARRAY_BUFFER, vbo)
gl.BufferData(gl.ARRAY_BUFFER, len(points)*4, gl.Ptr(points), gl.STATIC_DRAW)
var ibo uint32
gl.GenBuffers(1, &ibo)
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, ibo)
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, len(vertices)*4, gl.Ptr(vertices), gl.STATIC_DRAW)
vertAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, 3*4, gl.PtrOffset(0))
// global settings
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(0.0, 0.0, 0.0, 1.0)
angleX := 0.0
angleY := 0.0
angleZ := 0.0
previousTime := glfw.GetTime()
for !window.ShouldClose() {
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
time := glfw.GetTime()
elapsed := time - previousTime
previousTime = time
angleX += math.Sin((elapsed / period) * math.Pi * 2.0)
angleY += math.Sin((elapsed / period) / 6.0 * math.Pi * 2.0)
angleZ += math.Sin((elapsed / period) / 3.0 * math.Pi * 2.0)
model = mgl32.HomogRotate3DY(float32(angleY)).Mul4(mgl32.HomogRotate3DX(float32(angleX))).Mul4(mgl32.HomogRotate3DZ(float32(angleZ)))
gl.UseProgram(program)
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
gl.BindVertexArray(vao)
gl.DrawElements(gl.LINES, int32(len(vertices)), gl.UNSIGNED_INT, gl.PtrOffset(0))
window.SwapBuffers()
glfw.PollEvents()
}
}
func (glRenderer *OpenglRenderer) DrawGeometry(geometry *renderer.Geometry, transform mgl32.Mat4) {
glRenderer.enableShader()
glRenderer.enableMaterial()
glRenderer.enableCubeMap()
if glRenderer.activeShader == nil {
panic("ERROR: No shader is configured.")
}
shader := glRenderer.activeShader
program := shader.Program
params := glRenderer.rendererParams
glRenderer.enableDepthTest(params.DepthTest)
glRenderer.enableDepthMask(params.DepthMask)
glRenderer.enableCullFace(params.CullBackface)
glRenderer.enableUnlit(params.Unlit)
glRenderer.setTransparency(params.Transparency)
// set buffers
gl.BindBuffer(gl.ARRAY_BUFFER, geometry.VboId)
gl.BindBuffer(gl.ELEMENT_ARRAY_BUFFER, geometry.IboId)
// update buffers
if geometry.VboDirty && len(geometry.Verticies) > 0 && len(geometry.Indicies) > 0 {
gl.BufferData(gl.ARRAY_BUFFER, len(geometry.Verticies)*4, gl.Ptr(geometry.Verticies), gl.DYNAMIC_DRAW)
gl.BufferData(gl.ELEMENT_ARRAY_BUFFER, len(geometry.Indicies)*4, gl.Ptr(geometry.Indicies), gl.DYNAMIC_DRAW)
geometry.VboDirty = false
}
// set uniforms
modelNormal := transform.Inv().Transpose()
shader.Uniforms["model"] = transform
shader.Uniforms["modelNormal"] = modelNormal
// set camera uniforms
cam := glRenderer.camera
win := glRenderer.WindowDimensions()
shader.Uniforms["cameraTranslation"] = cam.Translation
if cam.Ortho {
shader.Uniforms["projection"] = mgl32.Ortho2D(0, win.X(), win.Y(), 0)
shader.Uniforms["camera"] = mgl32.Ident4()
} else {
shader.Uniforms["projection"] = mgl32.Perspective(mgl32.DegToRad(cam.Angle), win.X()/win.Y(), cam.Near, cam.Far)
shader.Uniforms["camera"] = mgl32.LookAtV(cam.Translation, cam.Lookat, cam.Up)
}
shader.Uniforms["unlit"] = glRenderer.unlit
shader.Uniforms["useTextures"] = glRenderer.useTextures
shader.Uniforms["ambientLightValue"] = glRenderer.ambientLightValue
shader.Uniforms["nbPointLights"] = glRenderer.nbPointLights
shader.Uniforms["pointLightValues"] = glRenderer.pointLightValues
shader.Uniforms["pointLightPositions"] = glRenderer.pointLightPositions
shader.Uniforms["nbDirectionalLights"] = glRenderer.nbDirectionalLights
shader.Uniforms["directionalLightValues"] = glRenderer.directionalLightValues
shader.Uniforms["directionalLightVectors"] = glRenderer.directionalLightVectors
// set custom uniforms
setupUniforms(shader)
// set verticies attribute
vertAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, renderer.VertexStride*4, gl.PtrOffset(0))
// set normals attribute
normAttrib := uint32(gl.GetAttribLocation(program, gl.Str("normal\x00")))
gl.EnableVertexAttribArray(normAttrib)
gl.VertexAttribPointer(normAttrib, 3, gl.FLOAT, false, renderer.VertexStride*4, gl.PtrOffset(3*4))
// set texture coord attribute
texCoordAttrib := uint32(gl.GetAttribLocation(program, gl.Str("texCoord\x00")))
gl.EnableVertexAttribArray(texCoordAttrib)
gl.VertexAttribPointer(texCoordAttrib, 2, gl.FLOAT, false, renderer.VertexStride*4, gl.PtrOffset(6*4))
// vertex color attribute
colorAttrib := uint32(gl.GetAttribLocation(program, gl.Str("color\x00")))
gl.EnableVertexAttribArray(colorAttrib)
gl.VertexAttribPointer(colorAttrib, 4, gl.FLOAT, false, renderer.VertexStride*4, gl.PtrOffset(8*4))
gl.DrawElements(gl.TRIANGLES, (int32)(len(geometry.Indicies)), gl.UNSIGNED_INT, gl.PtrOffset(0))
}
func CreateContext(width, height int) Context {
vertexShader := `
#version 330
uniform mat4 projection;
uniform mat4 camera;
uniform mat4 model;
in vec3 vert;
void main() {
gl_Position = projection * camera * model * vec4(vert, 1);
}
` + "\x00"
fragmentShader := `
#version 330
uniform vec4 color;
out vec4 outputColor;
void main() {
outputColor = color;
}
` + "\x00"
vertices := []float32{
0.0, 0.0, 0.0,
1.0, 0.0, 0.0,
1.0, 1.0, 0.0,
1.0, 1.0, 0.0,
0.0, 1.0, 0.0,
0.0, 0.0, 0.0,
}
if err := glfw.Init(); err != nil {
log.Fatalln("failed to initialize glfw:", err)
}
// defer glfw.Terminate()
glfw.WindowHint(glfw.Resizable, glfw.False)
glfw.WindowHint(glfw.ContextVersionMajor, 3)
glfw.WindowHint(glfw.ContextVersionMinor, 3)
glfw.WindowHint(glfw.OpenGLProfile, glfw.OpenGLCoreProfile)
glfw.WindowHint(glfw.OpenGLForwardCompatible, glfw.True)
window, err := glfw.CreateWindow(width, height, "OpenGL", nil, nil)
if err != nil {
panic(err)
}
window.MakeContextCurrent()
if err := gl.Init(); err != nil {
panic(err)
}
program, err := newProgram(vertexShader, fragmentShader)
if err != nil {
panic(err)
}
gl.UseProgram(program)
projection := mgl32.Ortho2D(0, 800, 0, 600)
projectionUniform := gl.GetUniformLocation(program, gl.Str("projection\x00"))
gl.UniformMatrix4fv(projectionUniform, 1, false, &projection[0])
camera := mgl32.LookAtV(mgl32.Vec3{0, 0, 0.5}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
model := mgl32.Ident4()
modelUniform := gl.GetUniformLocation(program, gl.Str("model\x00"))
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
var vao uint32
gl.GenVertexArrays(1, &vao)
gl.BindVertexArray(vao)
var vbo uint32
gl.GenBuffers(1, &vbo)
gl.BindBuffer(gl.ARRAY_BUFFER, vbo)
gl.BufferData(gl.ARRAY_BUFFER, len(vertices)*4, gl.Ptr(vertices), gl.STATIC_DRAW)
vertAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, 3*4, gl.PtrOffset(0))
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
return Context{Window: window, program: program}
}
func (c *Camera) Update(dt float32) {
/* Handle keyboard input */
move := false
dir := mgl.Vec3{}
if KeyDown(KeyW) && !KeyDown(KeyS) {
dir[2] += 1
move = true
}
if KeyDown(KeyS) && !KeyDown(KeyW) {
dir[2] -= 1
move = true
}
if KeyDown(KeyA) && !KeyDown(KeyD) {
dir[0] -= 1
move = true
}
if KeyDown(KeyD) && !KeyDown(KeyA) {
dir[0] += 1
move = true
}
if KeyDown(KeyE) && !KeyDown(KeyQ) {
dir[1] += 1
move = true
}
if KeyDown(KeyQ) && !KeyDown(KeyE) {
dir[1] -= 1
move = true
}
if move {
/* Calculate normalized movement vector */
dv := 5.0 * dt /* magic number: movement speed */
dir = dir.Normalize().Mul(dv)
right := c.Transform.Right.Mul(dir[0])
up := mgl.Vec3{0, dir[1], 0}
forward := c.Transform.Forward.Mul(dir[2])
/* Translate camera */
c.Transform.Translate(right.Add(up.Add(forward)))
}
/* Mouse look */
if MouseDown(MouseButton1) {
rx := c.Transform.Rotation[0] - Mouse.DY*0.08
ry := c.Transform.Rotation[1] - Mouse.DX*0.09
/* Camera angle limits */
/* -90 < rx < 90 */
rx = float32(math.Max(-90.0, math.Min(90.0, float64(rx))))
/* -180 < ry < 180 */
if ry > 180.0 {
ry -= 360.0
}
if ry < -180.0 {
ry += 360.0
}
c.Transform.Rotation[0] = rx
c.Transform.Rotation[1] = ry
}
/* Update transform with new position & rotation */
c.Transform.Update(dt)
/* Calculate new view matrix based on forward vector */
lookAt := c.Transform.Position.Add(c.Transform.Forward)
c.View = mgl.LookAtV(c.Transform.Position, lookAt, mgl.Vec3{0, 1, 0})
}
func main() {
if err := glfw.Init(); err != nil {
log.Fatalln("failed to initialize glfw:", err)
}
defer glfw.Terminate()
glfw.WindowHint(glfw.Resizable, glfw.False)
glfw.WindowHint(glfw.ContextVersionMajor, 4)
glfw.WindowHint(glfw.ContextVersionMinor, 1)
glfw.WindowHint(glfw.OpenGLProfile, glfw.OpenGLCoreProfile)
glfw.WindowHint(glfw.OpenGLForwardCompatible, glfw.True)
window, err := glfw.CreateWindow(windowWidth, windowHeight, "Cube", nil, nil)
if err != nil {
panic(err)
}
window.MakeContextCurrent()
// Initialize Glow
if err := gl.Init(); err != nil {
panic(err)
}
version := gl.GoStr(gl.GetString(gl.VERSION))
fmt.Println("OpenGL version", version)
// Configure the vertex and fragment shaders
program, err := newProgram(vertexShader, fragmentShader)
if err != nil {
panic(err)
}
gl.UseProgram(program)
projection := mgl32.Perspective(mgl32.DegToRad(45.0), float32(windowWidth)/windowHeight, 0.1, 10.0)
projectionUniform := gl.GetUniformLocation(program, gl.Str("projection\x00"))
gl.UniformMatrix4fv(projectionUniform, 1, false, &projection[0])
camera := mgl32.LookAtV(mgl32.Vec3{3, 3, 3}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
model := mgl32.Ident4()
modelUniform := gl.GetUniformLocation(program, gl.Str("model\x00"))
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
textureUniform := gl.GetUniformLocation(program, gl.Str("tex\x00"))
gl.Uniform1i(textureUniform, 0)
gl.BindFragDataLocation(program, 0, gl.Str("outputColor\x00"))
// Load the texture
texture, err := newTexture("square.png")
if err != nil {
panic(err)
}
// Configure the vertex data
var vao uint32
gl.GenVertexArrays(1, &vao)
gl.BindVertexArray(vao)
var vbo uint32
gl.GenBuffers(1, &vbo)
gl.BindBuffer(gl.ARRAY_BUFFER, vbo)
gl.BufferData(gl.ARRAY_BUFFER, len(cubeVertices)*4, gl.Ptr(cubeVertices), gl.STATIC_DRAW)
vertAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vert\x00")))
gl.EnableVertexAttribArray(vertAttrib)
gl.VertexAttribPointer(vertAttrib, 3, gl.FLOAT, false, 5*4, gl.PtrOffset(0))
texCoordAttrib := uint32(gl.GetAttribLocation(program, gl.Str("vertTexCoord\x00")))
gl.EnableVertexAttribArray(texCoordAttrib)
gl.VertexAttribPointer(texCoordAttrib, 2, gl.FLOAT, false, 5*4, gl.PtrOffset(3*4))
// Configure global settings
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(1.0, 1.0, 1.0, 1.0)
angle := 0.0
previousTime := glfw.GetTime()
for !window.ShouldClose() {
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
// Update
time := glfw.GetTime()
elapsed := time - previousTime
previousTime = time
angle += elapsed
model = mgl32.HomogRotate3D(float32(angle), mgl32.Vec3{0, 1, 0})
// Render
gl.UseProgram(program)
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
gl.BindVertexArray(vao)
gl.ActiveTexture(gl.TEXTURE0)
gl.BindTexture(gl.TEXTURE_2D, texture)
gl.DrawArrays(gl.TRIANGLES, 0, 6*2*3)
// Maintenance
window.SwapBuffers()
glfw.PollEvents()
}
}
func (p *LightPass) DrawPass(scene *Scene) {
/* use light pass shader */
p.Material.Use()
shader := p.Material.Shader
/* compute camera view projection inverse */
vp := scene.Camera.Projection.Mul4(scene.Camera.View)
vp_inv := vp.Inv()
shader.Matrix4f("cameraInverse", &vp_inv[0])
/* clear */
gl.ClearColor(0.9, 0.9, 0.9, 1.0)
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
/* set blending mode to additive */
gl.DepthMask(false)
/* draw lights */
lights := scene.FindLights()
last := len(lights) - 1
for i, light := range lights {
if i == 1 {
/* first light pass we want the shader to restore the depth buffer
* then, disable depth masking so that multiple lights can be drawn */
gl.BlendFunc(gl.ONE, gl.ONE)
}
if i == last {
gl.DepthMask(true)
}
/* draw shadow pass for this light into shadow map */
p.Shadows.DrawPass(scene, &light)
/* use light pass shader */
p.Material.Use()
/* compute world to lightspace (light view projection) matrix */
lp := light.Projection
lv := mgl.LookAtV(light.Position, mgl.Vec3{}, mgl.Vec3{0, 1, 0}) // only for directional light
lvp := lp.Mul4(lv)
shader.Matrix4f("light_vp", &lvp[0])
/* set light uniform attributes */
shader.Vec3("light.Position", &light.Position)
shader.Vec3("light.Color", &light.Color)
shader.Int32("light.Type", int32(light.Type))
shader.Float("light.Range", light.Range)
shader.Float("light.attenuation.Constant", light.Attenuation.Constant)
shader.Float("light.attenuation.Linear", light.Attenuation.Linear)
shader.Float("light.attenuation.Quadratic", light.Attenuation.Quadratic)
/* render light */
gl.Viewport(0, 0, int32(scene.Camera.Width), int32(scene.Camera.Height))
p.quad.Draw()
}
/* reset GL state */
gl.BlendFunc(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA)
}
// SetPosition2D will adjust the camera for ortho viewing to specified location
func (cam *Camera) SetPosition2D(x float32, y float32) {
cam.Position = mgl32.Vec3{x, y, cam.zDepth}
cam.loc = mgl32.LookAtV(mgl32.Vec3{x, y, cam.zDepth}, mgl32.Vec3{x, y, 0}, mgl32.Vec3{0, 1, 0})
cam.update()
}
func Main() {
err := glfw.Init()
if err != nil {
panic(err)
}
defer glfw.Terminate()
glfw.WindowHint(glfw.Resizable, glfw.False)
glfw.WindowHint(glfw.ContextVersionMajor, 3)
glfw.WindowHint(glfw.ContextVersionMinor, 2)
glfw.WindowHint(glfw.OpenGLProfile, glfw.OpenGLCoreProfile)
glfw.WindowHint(glfw.OpenGLForwardCompatible, glfw.True)
window, err := glfw.CreateWindow(WindowWidth, WindowHeight, "Cube", nil, nil)
Window = window
if err != nil {
panic(err)
}
window.MakeContextCurrent()
// Initialize Glow
if err := gl.Init(); err != nil {
panic(err)
}
version := gl.GoStr(gl.GetString(gl.VERSION))
fmt.Println("OpenGL version", version)
// Configure the vertex and fragment shaders
program, err := newProgram("SimpleVertexShader.vertexshader", "SimpleFragmentShader.fragmentshader")
if err != nil {
panic(err)
}
gl.UseProgram(program)
projection := mgl32.Perspective(mgl32.DegToRad(45.0), float32(WindowWidth)/WindowHeight, 0.1, 10.0)
projectionUniform := gl.GetUniformLocation(program, gl.Str("projection\x00"))
gl.UniformMatrix4fv(projectionUniform, 1, false, &projection[0])
camera := mgl32.LookAtV(mgl32.Vec3{3, 3, 3}, mgl32.Vec3{0, 0, 0}, mgl32.Vec3{0, 1, 0})
cameraUniform := gl.GetUniformLocation(program, gl.Str("camera\x00"))
gl.UniformMatrix4fv(cameraUniform, 1, false, &camera[0])
model := mgl32.Ident4()
modelUniform := gl.GetUniformLocation(program, gl.Str("model\x00"))
gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
textureUniform := gl.GetUniformLocation(program, gl.Str("tex\x00"))
gl.Uniform1i(textureUniform, 0)
gl.BindFragDataLocation(program, 0, gl.Str("outputColor\x00"))
// Configure global settings
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LESS)
gl.ClearColor(1.0, 1.0, 1.0, 1.0)
angle := 0.0
previousTime := glfw.GetTime()
width, height := window.GetSize()
window.SetCursorPos(float64(width/2), float64(height/2))
window.SetKeyCallback(input.OnKey)
window.SetCursorPosCallback(input.OnCursor)
window.SetMouseButtonCallback(input.OnMouse)
meshes.LoadColladaCube("cube.dae")
for !player.ShouldClose {
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
// Update
time := glfw.GetTime()
elapsed := time - previousTime
previousTime = time
angle += elapsed
model = mgl32.HomogRotate3D(float32(angle), mgl32.Vec3{0, 1, 0})
// Render
gl.UseProgram(program)
// gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])
player.MainPlayer.Draw(program)
for _, element := range game.Universe {
(element).Draw(program)
}
// Maintenance
window.SwapBuffers()
glfw.PollEvents()
}
}
// Since go has multiple return values, I just went ahead and made it return the view and perspective matrices (in that order) rather than messing with getter methods
func (c *Camera) ComputeViewPerspective() (mgl32.Mat4, mgl32.Mat4) {
if mgl64.FloatEqual(-1.0, c.time) {
c.time = glfw.GetTime()
}
currTime := glfw.GetTime()
deltaT := currTime - c.time
xPos, yPos := c.window.GetCursorPosition()
c.window.SetCursorPosition(width/2.0, height/2.0)
c.hAngle += mouseSpeed * ((width / 2.0) - float64(xPos))
c.vAngle += mouseSpeed * ((height / 2.0) - float64(yPos))
dir := mgl32.Vec3{
float32(math.Cos(c.vAngle) * math.Sin(c.hAngle)),
float32(math.Sin(c.vAngle)),
float32(math.Cos(c.vAngle) * math.Cos(c.hAngle))}
right := mgl32.Vec3{
float32(math.Sin(c.hAngle - math.Pi/2.0)),
0.0,
float32(math.Cos(c.hAngle - math.Pi/2.0))}
up := right.Cross(dir)
if c.window.GetKey(glfw.KeyUp) == glfw.Press || c.window.GetKey('W') == glfw.Press {
c.pos = c.pos.Add(dir.Mul(float32(deltaT * speed)))
}
if c.window.GetKey(glfw.KeyDown) == glfw.Press || c.window.GetKey('S') == glfw.Press {
c.pos = c.pos.Sub(dir.Mul(float32(deltaT * speed)))
}
if c.window.GetKey(glfw.KeyRight) == glfw.Press || c.window.GetKey('D') == glfw.Press {
c.pos = c.pos.Add(right.Mul(float32(deltaT * speed)))
}
if c.window.GetKey(glfw.KeyLeft) == glfw.Press || c.window.GetKey('A') == glfw.Press {
c.pos = c.pos.Sub(right.Mul(float32(deltaT * speed)))
}
// Adding to the original tutorial, Space goes up
if c.window.GetKey(glfw.KeySpace) == glfw.Press {
c.pos = c.pos.Add(up.Mul(float32(deltaT * speed)))
}
// Adding to the original tutorial, left control goes down
if c.window.GetKey(glfw.KeyLeftControl) == glfw.Press {
c.pos = c.pos.Sub(up.Mul(float32(deltaT * speed)))
}
fov := initialFOV //- 5.0*float64(glfw.MouseWheel())
proj := mgl32.Perspective(float32(fov), 4.0/3.0, 0.1, 100.0)
view := mgl32.LookAtV(c.pos, c.pos.Add(dir), up)
c.time = currTime
return view, proj
}
// View returns the transform matrix from world space into camera space
func (c *QuatCamera) View() mgl.Mat4 {
// FIXME: Is there a way to get this matrix from the quat+position directly?
return mgl.LookAtV(c.position, c.position.Add(c.Center()), c.Up())
}
// Draw draws a single frame
func Draw(width, height int, delta float64) {
tickAnimatedTextures(delta)
frameID++
sync:
for {
select {
case f := <-syncChan:
f()
default:
break sync
}
}
// Only update the viewport if the window was resized
if lastHeight != height || lastWidth != width || lastFOV != FOV.Value() {
lastWidth = width
lastHeight = height
lastFOV = FOV.Value()
perspectiveMatrix = mgl32.Perspective(
(math.Pi/180)*float32(lastFOV),
float32(width)/float32(height),
0.1,
500.0,
)
gl.Viewport(0, 0, width, height)
frustum.SetPerspective(
(math.Pi/180)*float32(lastFOV),
float32(width)/float32(height),
0.1,
500.0,
)
initTrans()
}
mainFramebuffer.Bind()
gl.Enable(gl.Multisample)
gl.ActiveTexture(0)
glTexture.Bind(gl.Texture2DArray)
gl.ClearColor(ClearColour.R, ClearColour.G, ClearColour.B, 1.0)
gl.Clear(gl.ColorBufferBit | gl.DepthBufferBit)
chunkProgram.Use()
viewVector = mgl32.Vec3{
float32(math.Cos(Camera.Yaw-math.Pi/2) * -math.Cos(Camera.Pitch)),
float32(-math.Sin(Camera.Pitch)),
float32(-math.Sin(Camera.Yaw-math.Pi/2) * -math.Cos(Camera.Pitch)),
}
cam := mgl32.Vec3{-float32(Camera.X), -float32(Camera.Y), float32(Camera.Z)}
cameraMatrix = mgl32.LookAtV(
cam,
cam.Add(mgl32.Vec3{-viewVector.X(), -viewVector.Y(), viewVector.Z()}),
mgl32.Vec3{0, -1, 0},
)
cameraMatrix = cameraMatrix.Mul4(mgl32.Scale3D(-1.0, 1.0, 1.0))
frustum.SetCamera(
cam,
cam.Add(mgl32.Vec3{-viewVector.X(), -viewVector.Y(), viewVector.Z()}),
mgl32.Vec3{0, -1, 0},
)
shaderChunk.PerspectiveMatrix.Matrix4(&perspectiveMatrix)
shaderChunk.CameraMatrix.Matrix4(&cameraMatrix)
shaderChunk.Texture.Int(0)
shaderChunk.LightLevel.Float(LightLevel)
shaderChunk.SkyOffset.Float(SkyOffset)
chunkPos := position{
X: int(Camera.X) >> 4,
Y: int(Camera.Y) >> 4,
Z: int(Camera.Z) >> 4,
}
nearestBuffer = buffers[chunkPos]
for _, dir := range direction.Values {
validDirs[dir] = viewVector.Dot(dir.AsVec()) > -0.8
}
renderOrder = renderOrder[:0]
renderBuffer(nearestBuffer, chunkPos, direction.Invalid, delta)
drawLines()
drawModels()
clouds.tick(delta)
chunkProgramT.Use()
shaderChunkT.PerspectiveMatrix.Matrix4(&perspectiveMatrix)
shaderChunkT.CameraMatrix.Matrix4(&cameraMatrix)
shaderChunkT.Texture.Int(0)
shaderChunkT.LightLevel.Float(LightLevel)
shaderChunkT.SkyOffset.Float(SkyOffset)
// Copy the depth buffer
mainFramebuffer.BindRead()
transFramebuffer.BindDraw()
gl.BlitFramebuffer(
0, 0, lastWidth, lastHeight,
0, 0, lastWidth, lastHeight,
gl.DepthBufferBit, gl.Nearest,
)
gl.Enable(gl.Blend)
gl.DepthMask(false)
transFramebuffer.Bind()
gl.ClearColor(0, 0, 0, 1)
gl.Clear(gl.ColorBufferBit)
gl.ClearBuffer(gl.Color, 0, []float32{0, 0, 0, 1})
gl.ClearBuffer(gl.Color, 1, []float32{0, 0, 0, 0})
gl.BlendFuncSeparate(gl.OneFactor, gl.OneFactor, gl.ZeroFactor, gl.OneMinusSrcAlpha)
for _, chunk := range renderOrder {
if chunk.countT > 0 && chunk.bufferT.IsValid() {
shaderChunkT.Offset.Int3(chunk.X, chunk.Y*4096-chunk.Y*int(4096*(1-chunk.progress)), chunk.Z)
chunk.arrayT.Bind()
gl.DrawElements(gl.Triangles, chunk.countT, elementBufferType, 0)
}
}
gl.UnbindFramebuffer()
gl.Disable(gl.DepthTest)
gl.Clear(gl.ColorBufferBit)
gl.Disable(gl.Blend)
transDraw()
gl.Enable(gl.DepthTest)
gl.DepthMask(true)
gl.BlendFunc(gl.SrcAlpha, gl.OneMinusSrcAlpha)
gl.Disable(gl.Multisample)
drawUI()
if debugFramebuffers.Value() {
gl.Enable(gl.Multisample)
blitBuffers()
gl.Disable(gl.Multisample)
}
}
// View returns the transform matrix from world space into camera space
func (c *EulerCamera) View() mgl.Mat4 {
return mgl.LookAtV(c.eye, c.eye.Add(c.center), c.up)
}