func createBuffer() *glh.MeshBuffer {
const N = 128
const f = 0.025
pos := make([]float64, N*2)
clr := make([]float64, N*4)
for i := 0; i < N; i += 1 {
pos[2*i+0] = math.Cos(f * 2 * math.Pi * 2 * float64(i) / N)
pos[2*i+1] = math.Sin(f * 2 * math.Pi * 2 * float64(i) / N)
clr[4*i+0] = 0.2
clr[4*i+1] = 0.75
clr[4*i+2] = 0.9
clr[4*i+3] = 0.5 * (1 - float64(i)/float64(N-1))
}
// Create a mesh buffer with the given attributes.
mb := glh.NewMeshBuffer(
glh.RenderArrays,
glh.NewPositionAttr(2, gl.DOUBLE, gl.STATIC_DRAW),
glh.NewColorAttr(4, gl.DOUBLE, gl.STATIC_DRAW),
)
// Add the mesh to the buffer.
mb.Add(pos, clr)
return mb
}
func createMeshBuffer() *glh.MeshBuffer {
mb := glh.NewMeshBuffer(
glh.RenderBuffered,
glh.NewIndexAttr(1, gl.UNSIGNED_SHORT, gl.STATIC_DRAW),
// 2 INTEGER values should be enough, but
// just to keep things simpler
// let's work with 3d vertex instead of 2d
// it's easier to find help that way
glh.NewPositionAttr(3, gl.FLOAT, gl.STATIC_DRAW),
// At this moment, let's use colors instead of textures
glh.NewColorAttr(3, gl.UNSIGNED_BYTE, gl.DYNAMIC_DRAW))
return mb
}
// createBuffer creates a mesh buffer and fills it with data.
func createBuffer() *glh.MeshBuffer {
// Create a mesh buffer with the given attributes.
mb := glh.NewMeshBuffer(
glh.RenderBuffered,
// 1 index per vertex.
glh.NewIndexAttr(1, gl.UNSIGNED_SHORT, gl.STATIC_DRAW),
// Vertex positions have 2 components (x, y).
// These will never be changing, so mark them as static.
glh.NewPositionAttr(2, gl.INT, gl.STATIC_DRAW),
// Colors have 3 components (r, g, b).
// These will be changing, so make them dynamic.
glh.NewColorAttr(3, gl.UNSIGNED_BYTE, gl.DYNAMIC_DRAW),
)
// Define components for a simple, coloured quad.
idx := []uint16{0, 1, 2, 3}
pos := []int32{0, 0, 0, 0, 0, 0, 0, 0}
clr := []uint8{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}
for y := 0; y < Rows; y++ {
py := int32(CellHeight * y)
pos[1] = py + 1
pos[3] = py + 1
pos[5] = py + CellHeight
pos[7] = py + CellHeight
for x := 0; x < Cols; x++ {
px := int32(CellWidth * x)
pos[0] = px + 1
pos[2] = px + CellWidth
pos[4] = px + CellWidth
pos[6] = px + 1
palette := colors[rng.Int31n(6)]
setColor(clr, palette[0], palette[1], palette[2])
mb.Add(idx, pos, clr)
}
}
return mb
}
func createBuffer() *glh.MeshBuffer {
// We create as few vertices as possible.
// Manually building a cube would require 24 vertices. Many of which
// are duplicates. All we have to define here, is the 8 unique ones
// necessary to construct each face of the cube.
pos := []float32{
1, 1, -1, -1, 1, -1, -1, 1, 1, 1, 1, 1,
1, -1, 1, -1, -1, 1, -1, -1, -1, 1, -1, -1,
}
a := float32(0.02)
// Each vertex comes with its own colour.
clr := []float32{
1, 0, 0, a, 0, 1, 0, a, 0, 0, 1, a, 1, 0, 1, a,
1, 1, 0, a, 0, 1, 1, a, 1, 1, 1, a, 0, 0, 0, a,
}
// These are the indices into the position and color lists.
// They tell the GPU which position/color pair to use in order to construct
// the whole cube. As can be seen, all elements are repeated multiple
// times to create the correct layout. For large meshes with many duplicate
// vertices, this can save a sizable amount of storage space.
idx := []byte{
0, 1, 2, 3, 4, 5, 6, 7, 3, 2, 5, 4,
7, 6, 1, 0, 2, 1, 6, 5, 0, 3, 4, 7,
}
// Create a mesh buffer with the given attributes.
mb := glh.NewMeshBuffer(
glh.RenderBuffered,
// Indices.
glh.NewIndexAttr(1, gl.UNSIGNED_BYTE, gl.STATIC_DRAW),
// Vertex positions have 3 components (x, y, z).
glh.NewPositionAttr(3, gl.FLOAT, gl.STATIC_DRAW),
// Colors have 4 components (r, g, b, a).
glh.NewColorAttr(4, gl.FLOAT, gl.STATIC_DRAW),
)
// Add the mesh to the buffer.
mb.Add(idx, pos, clr)
return mb
}
// Create the glh.MeshBufer
func createBuffer() *glh.MeshBuffer {
if len(scene.Mesh[0].Colors) == 0 {
// just add some colors to it.
assimp.RandomColor(scene.Mesh[0])
}
fmesh := assimp.NewFlatMesh(scene.Mesh[0])
println("FMesh vertex count: ", len(fmesh.Vertex))
var idxAttr *glh.Attr
switch sz := len(fmesh.Index); {
case sz < int(assimp.ByteSize):
idxAttr = glh.NewIndexAttr(1, gl.UNSIGNED_BYTE, gl.STATIC_DRAW)
case sz < int(assimp.ShortSize):
idxAttr = glh.NewIndexAttr(1, gl.UNSIGNED_SHORT, gl.STATIC_DRAW)
default:
idxAttr = glh.NewIndexAttr(1, gl.UNSIGNED_INT, gl.STATIC_DRAW)
}
idxAttr = glh.NewIndexAttr(1, gl.UNSIGNED_INT, gl.STATIC_DRAW)
// Create a mesh buffer with the given attributes.
mb := glh.NewMeshBuffer(
glh.RenderBuffered,
// Indices.
idxAttr,
// Vertex positions have 3 components (x, y, z).
glh.NewPositionAttr(3, gl.FLOAT, gl.STATIC_DRAW),
// Colors have 4 components (r, g, b, a).
glh.NewColorAttr(4, gl.FLOAT, gl.STATIC_DRAW),
)
// Add the mesh to the buffer.
mb.Add(fmesh.Index, fmesh.Vertex, fmesh.Color)
return mb
}
func (sg *OpenGLGraphics) Scatter(points []chart.EPoint, plotstyle chart.PlotStyle, style chart.Style) {
//log.Panicf("Unimplemented: %s", whoami())
//chart.GenericScatter(sg, points, plotstyle, style)
// TODO: Implement error bars/symbols
buffer := glh.NewMeshBuffer(glh.RenderArrays,
glh.NewPositionAttr(2, gl.DOUBLE, gl.STATIC_DRAW),
glh.NewColorAttr(3, gl.UNSIGNED_INT, gl.STATIC_DRAW))
// var vertices glh.ColorVertices
positions := make([]float64, len(points)*2)
colors := make([]uint32, len(points)*3)
for _, p := range points {
r, g, b, _ := style.LineColor.RGBA()
colors = append(colors, r, g, b)
positions = append(positions, p.X, p.Y)
// vertices.Add(glh.ColorVertex{
// glh.MkRGBA(style.LineColor),
// glh.Vertex{float32(p.X), float32(p.Y)}})
}
buffer.Add()
if style.LineWidth != 0 {
gl.LineWidth(float32(style.LineWidth))
} else {
gl.LineWidth(1)
}
glh.With(glh.Attrib{gl.ENABLE_BIT | gl.COLOR_BUFFER_BIT}, func() {
gl.Enable(gl.BLEND)
gl.BlendFunc(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA)
buffer.Render(gl.LINE_STRIP)
})
/***********************************************
// First pass: Error bars
ebs := style
ebs.LineColor, ebs.LineWidth, ebs.LineStyle = ebs.FillColor, 1, chart.SolidLine
if ebs.LineColor == "" {
ebs.LineColor = "#404040"
}
if ebs.LineWidth == 0 {
ebs.LineWidth = 1
}
for _, p := range points {
xl, yl, xh, yh := p.BoundingBox()
// fmt.Printf("Draw %d: %f %f-%f\n", i, p.DeltaX, xl,xh)
if !math.IsNaN(p.DeltaX) {
sg.Line(int(xl), int(p.Y), int(xh), int(p.Y), ebs)
}
if !math.IsNaN(p.DeltaY) {
sg.Line(int(p.X), int(yl), int(p.X), int(yh), ebs)
}
}
// Second pass: Line
if (plotstyle&chart.PlotStyleLines) != 0 && len(points) > 0 {
path := fmt.Sprintf("M %d,%d", int(points[0].X), int(points[0].Y))
for i := 1; i < len(points); i++ {
path += fmt.Sprintf("L %d,%d", int(points[i].X), int(points[i].Y))
}
st := linestyle(style)
sg.svg.Path(path, st)
}
// Third pass: symbols
if (plotstyle&chart.PlotStylePoints) != 0 && len(points) != 0 {
for _, p := range points {
sg.Symbol(int(p.X), int(p.Y), style)
}
}
****************************************************/
}
func (block *Block) GenerateVertices() *glh.MeshBuffer {
width := uint64(len(block.display_active_pages)+1) * *PAGE_SIZE
vc := glh.NewMeshBuffer(
glh.RenderArrays,
glh.NewPositionAttr(2, gl.FLOAT, gl.STATIC_DRAW),
glh.NewColorAttr(3, gl.UNSIGNED_BYTE, gl.STATIC_DRAW),
)
var stack_depth int = len(block.context_records)
vertex := []float32{0, 0}
colour := []uint8{0, 0, 0}
x, y := &vertex[0], &vertex[1]
r, g, b := &colour[0], &colour[1], &colour[2]
vertices := make([]float32, 0, block.nrecords*2)
colours := make([]uint8, 0, block.nrecords*3)
for pos := int64(0); pos < int64(block.nrecords); pos++ {
if pos < 0 {
continue
}
rec := &block.records[pos]
if rec.Type == MEMA_ACCESS {
// take it
} else if rec.Type == MEMA_FUNC_ENTER {
stack_depth++
*x = 2 + float32(stack_depth)/80.
*y = float32(pos) //int64(len(*vc)))
*r, *g, *b = 64, 64, 255
vertices = append(vertices, *x, *y)
colours = append(colours, *r, *g, *b)
//vc.Add(vertex, colour)
//c := color.RGBA{64, 64, 255, 255}
//vc.Add(glh.ColorVertex{c, glh.Vertex{, y}})
continue
} else if rec.Type == MEMA_FUNC_EXIT {
*x = 2 + float32(stack_depth)/80.
*y = float32(pos) //int64(len(*vc)))
*r, *g, *b = 255, 64, 64
vertices = append(vertices, *x, *y)
colours = append(colours, *r, *g, *b)
//vc.Add(vertex, colour)
//y := float32(int64(len(*vc)))
//c := color.RGBA{255, 64, 64, 255}
//vc.Add(glh.ColorVertex{c, glh.Vertex{2 + float32(stack_depth)/80., y}})
stack_depth--
continue
} else {
log.Panic("Unexpected record type: ", rec.Type)
}
a := rec.MemAccess()
page := a.Addr / *PAGE_SIZE
if _, present := block.quiet_pages[page]; present {
continue
}
*x = float32((a.Addr - block.n_inactive_to_left[page]*(*PAGE_SIZE))) / float32(width)
*x = (*x - 0.5) * 4
if *x > 4 || *x < -4 {
log.Panic("x has unexpected value: ", x)
}
*y = float32(pos) //len(*vc))
*r, *g, *b = uint8(a.IsWrite)*255, uint8(1-a.IsWrite)*255, 0
vertices = append(vertices, *x, *y)
colours = append(colours, *r, *g, *b)
//vc.Add(vertex, colour)
//c := color.RGBA{uint8(a.IsWrite) * 255, uint8(1-a.IsWrite) * 255, 0, 255}
//vc.Add(glh.ColorVertex{c, glh.Vertex{x, y}})
/*
TODO: Reintroduce 'recently hit memory locations'
if pos > (start + N) - N / 20 {
vc.Add(ColorVertex{c, Vertex{x, 2 + 0.1}})
vc.Add(ColorVertex{c, Vertex{x, 2}})
}
*/
}
vc.Add(vertices, colours)
// Don't need the record data anymore
block.records = Records{}
runtime.GC()
return vc
}
// Init creates gl related resources: textures, fonts, buffers, etc.
func (d *LEM1802Display) Init() (err error) {
for _, dev := range d.cpu.Devices() {
if dev, ok := dev.(*lem1802.Device); ok {
d.dev = dev
break
}
}
d.createAtlas(
(d.width-d.borderWidth*2)/lem1802.CellsPerRow,
(d.height-d.borderHeight*2)/lem1802.CellsPerCol,
)
var pos [4 * 2]int16
var clr [4 * 3]byte
var tex [4 * 2]float32
// Untextured quads
d.quads_ut = glh.NewMeshBuffer(
glh.RenderBuffered,
glh.NewPositionAttr(2, gl.SHORT, gl.STATIC_DRAW),
glh.NewColorAttr(3, gl.UNSIGNED_BYTE, gl.DYNAMIC_DRAW),
)
// Textured quads
d.quads_t = glh.NewMeshBuffer(
glh.RenderBuffered,
glh.NewPositionAttr(2, gl.SHORT, gl.STATIC_DRAW),
glh.NewColorAttr(3, gl.UNSIGNED_BYTE, gl.DYNAMIC_DRAW),
glh.NewTexCoordAttr(2, gl.FLOAT, gl.DYNAMIC_DRAW),
)
// Screen background/border.
pos[2] = int16(d.width)
pos[4] = int16(d.width)
pos[5] = int16(d.height)
pos[7] = int16(d.height)
d.quads_ut.Add(pos[:], clr[:])
gw := int16((d.width - d.borderWidth*2) / lem1802.CellsPerRow)
gh := int16((d.height - d.borderHeight*2) / lem1802.CellsPerCol)
// Add individual glyphs.
//
// These consist of two equal-sized quads stacked on top of
// each other. The bottom one is an opaque quad with the glyph's
// background color. The top one has the glyph texture with
// its foreground color.
for y := int16(0); y < lem1802.CellsPerCol; y++ {
gy := y*gh + int16(d.borderHeight)
for x := int16(0); x < lem1802.CellsPerRow; x++ {
gx := x*gw + int16(d.borderWidth)
pos[0] = gx
pos[1] = gy
pos[2] = gx + gw
pos[3] = gy
pos[4] = gx + gw
pos[5] = gy + gh
pos[6] = gx
pos[7] = gy + gh
// Glyph background.
d.quads_ut.Add(pos[:], clr[:])
// Glyph.
d.quads_t.Add(pos[:], clr[:], tex[:])
}
}
return
}
func main() {
var err error
if err = glfw.Init(); err != nil {
fmt.Fprintf(os.Stderr, "[e] %v\n", err)
return
}
defer glfw.Terminate()
w, h := 1980, 1080
// w, h := 1280, 768
if err = glfw.OpenWindow(w, h, 8, 8, 8, 16, 0, 32, glfw.Fullscreen); err != nil {
fmt.Fprintf(os.Stderr, "[e] %v\n", err)
return
}
defer glfw.CloseWindow()
glfw.SetSwapInterval(1)
glfw.SetWindowTitle("Debris")
quadric = glu.NewQuadric()
gl.Enable(gl.CULL_FACE)
gl.Enable(gl.DEPTH_TEST)
gl.DepthFunc(gl.LEQUAL)
gl.Enable(gl.NORMALIZE)
gl.Enable(gl.BLEND)
gl.BlendFunc(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA)
gl.ShadeModel(gl.SMOOTH)
gl.Enable(gl.LIGHTING)
var (
ambient = []float32{0.1, 0.3, 0.6, 1}
diffuse = []float32{1, 1, 0.5, 1}
specular = []float32{0.4, 0.4, 0.4, 1}
light_position = []float32{1, 0, 0, 0}
// mat_specular []float32 = []float32{1, 1, 0.5, 1}
mat_specular = []float32{1, 1, 0.75, 1}
mat_shininess = float32(120)
// light_position []float32 = []float32{0.0, 0.0, 1.0, 0.0}
)
const (
fov = 1.1 // degrees
znear = 145
zfar = 155
camera_z_offset = -150
camera_x_rotation = 0 // degrees
// camera_x_rotation = 20 // degrees
starfield_fov = 45
faces = 1000
earth_radius = 1
)
gl.Lightfv(gl.LIGHT1, gl.AMBIENT, ambient)
gl.Lightfv(gl.LIGHT1, gl.DIFFUSE, diffuse)
gl.Lightfv(gl.LIGHT1, gl.SPECULAR, specular)
gl.Lightfv(gl.LIGHT1, gl.POSITION, light_position)
gl.Enable(gl.LIGHT1)
mat_emission := []float32{0, 0, 0.1, 1}
gl.Materialfv(gl.FRONT_AND_BACK, gl.EMISSION, mat_emission)
gl.Materialfv(gl.FRONT_AND_BACK, gl.SPECULAR, mat_specular)
gl.Materialf(gl.FRONT_AND_BACK, gl.SHININESS, mat_shininess)
gl.ClearColor(0.02, 0.02, 0.02, 1)
gl.ClearDepth(1)
gl.ClearStencil(0)
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)
b := createBuffer()
planetoids := []*Planetoid{}
for i := 0; i < 1000; i++ {
p := &Planetoid{
apogee: 1.2 + rand.Float64()*0.7,
perigee: 1.5,
// inclination: 45,
inclination: rand.Float64()*20 - 10,
// inclination: 0,
phase0: rand.Float64() * 360,
rising_node: rand.Float64() * 10,
phase: 0,
// radius: rand.Float32()*0.05 + 0.01, //float32(r),
radius: rand.Float32()*0.0125 + 0.005, //float32(r),
// quadric: glu.NewQuadric(),
circle: b,
}
planetoids = append(planetoids, p)
}
// Initial projection matrix:
var aspect float64
glfw.SetWindowSizeCallback(func(w, h int) {
gl.Viewport(0, 0, w, h)
gl.MatrixMode(gl.PROJECTION)
gl.LoadIdentity()
aspect = float64(w) / float64(h)
glu.Perspective(fov, aspect, znear, zfar)
})
d := float64(0)
wireframe := false
atmosphere := false
polar := false
rotating := false
front := false
earth := true
cone := true
shadowing := true
tilt := false
running := true
glfw.SetKeyCallback(func(key, state int) {
if state != glfw.KeyPress {
// Don't act on key coming up
return
}
switch key {
case 'A':
atmosphere = !atmosphere
case 'C':
cone = !cone
case 'E':
earth = !earth
case 'R':
rotating = !rotating
case 'F':
front = !front
if front {
gl.FrontFace(gl.CW)
} else {
gl.FrontFace(gl.CCW)
}
case 'S':
shadowing = !shadowing
case 'T':
tilt = !tilt
case 'W':
wireframe = !wireframe
method := gl.GLenum(gl.FILL)
if wireframe {
method = gl.LINE
}
gl.PolygonMode(gl.FRONT_AND_BACK, method)
case glfw.KeyF2:
println("Screenshot captured")
// glh.CaptureToPng("screenshot.png")
w, h := glh.GetViewportWH()
im := image.NewRGBA(image.Rect(0, 0, w, h))
glh.ClearAlpha(1)
gl.Flush()
glh.CaptureRGBA(im)
go func() {
fd, err := os.Create("screenshot.png")
if err != nil {
panic("Unable to open file")
}
defer fd.Close()
png.Encode(fd, im)
}()
case 'Q', glfw.KeyEsc:
running = !running
case glfw.KeySpace:
polar = !polar
}
})
_ = rand.Float64
stars := glh.NewMeshBuffer(
glh.RenderArrays,
glh.NewPositionAttr(3, gl.DOUBLE, gl.STATIC_DRAW),
glh.NewColorAttr(3, gl.DOUBLE, gl.STATIC_DRAW))
const Nstars = 50000
points := make([]float64, 3*Nstars)
colors := make([]float64, 3*Nstars)
for i := 0; i < Nstars; i++ {
const R = 1
phi := rand.Float64() * 2 * math.Pi
z := R * (2*rand.Float64() - 1)
theta := math.Asin(z / R)
points[i*3+0] = R * math.Cos(theta) * math.Cos(phi)
points[i*3+1] = R * math.Cos(theta) * math.Sin(phi)
points[i*3+2] = z
const r = 0.8
v := rand.Float64()*r + (1 - r)
colors[i*3+0] = v
colors[i*3+1] = v
colors[i*3+2] = v
}
stars.Add(points, colors)
render_stars := func() {
glh.With(glh.Attrib{gl.DEPTH_BUFFER_BIT | gl.ENABLE_BIT}, func() {
gl.Disable(gl.LIGHTING)
gl.PointSize(1)
gl.Color4f(1, 1, 1, 1)
gl.Disable(gl.DEPTH_TEST)
gl.DepthMask(false)
stars.Render(gl.POINTS)
})
}
render_scene := func() {
// Update light position (sensitive to current modelview matrix)
gl.Lightfv(gl.LIGHT1, gl.POSITION, light_position)
gl.Lightfv(gl.LIGHT2, gl.POSITION, light_position)
if earth {
Sphere(earth_radius, faces)
}
unlit_points := glh.Compound(glh.Disable(gl.LIGHTING), glh.Primitive{gl.POINTS})
glh.With(unlit_points, func() {
gl.Vertex3d(1, 0, 0)
})
for _, p := range planetoids {
const dt = 0.1 // TODO: Frame update
p.Render(dt)
}
glh.With(glh.Disable(gl.LIGHTING), func() {
// Atmosphere
gl.Color4f(0.25, 0.25, 1, 0.1)
if atmosphere && earth {
Sphere(earth_radius*1.025, 100)
}
gl.PointSize(10)
glh.With(glh.Primitive{gl.POINTS}, func() {
gl.Color4f(1.75, 0.75, 0.75, 1)
gl.Vertex3d(-1.04, 0, 0)
})
})
}
render_shadow_volume := func() {
glh.With(glh.Attrib{
gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT | gl.ENABLE_BIT |
gl.POLYGON_BIT | gl.STENCIL_BUFFER_BIT,
}, func() {
gl.Disable(gl.LIGHTING)
if shadowing {
// gl.Disable(gl.DEPTH_TEST)
gl.DepthMask(false)
gl.DepthFunc(gl.LEQUAL)
gl.Enable(gl.STENCIL_TEST)
gl.ColorMask(false, false, false, false)
gl.StencilFunc(gl.ALWAYS, 1, 0xffffffff)
}
shadow_volume := func() {
const sv_length = 2
const sv_granularity = 100
const sv_radius = earth_radius * 1.001
// Shadow cone
glh.With(glh.Matrix{gl.MODELVIEW}, func() {
gl.Rotatef(90, 1, 0, 0)
gl.Rotatef(90, 0, -1, 0)
gl.Color4f(0.5, 0.5, 0.5, 1)
glu.Cylinder(quadric, sv_radius, sv_radius*1.05,
sv_length, sv_granularity, 1)
glu.Disk(quadric, 0, sv_radius, sv_granularity, 1)
glh.With(glh.Matrix{gl.MODELVIEW}, func() {
gl.Translated(0, 0, sv_length)
glu.Disk(quadric, 0, sv_radius*1.05, sv_granularity, 1)
})
})
for _, p := range planetoids {
p.RenderShadowVolume()
}
}
if cone {
gl.FrontFace(gl.CCW)
gl.StencilOp(gl.KEEP, gl.KEEP, gl.INCR)
shadow_volume()
gl.FrontFace(gl.CW)
gl.StencilOp(gl.KEEP, gl.KEEP, gl.DECR)
shadow_volume()
}
if shadowing {
gl.StencilFunc(gl.NOTEQUAL, 0, 0xffffffff)
gl.StencilOp(gl.KEEP, gl.KEEP, gl.KEEP)
gl.ColorMask(true, true, true, true)
// gl.Disable(gl.STENCIL_TEST)
gl.Disable(gl.DEPTH_TEST)
gl.FrontFace(gl.CCW)
// gl.Color4f(1, 0, 0, 0.75)
gl.Color4f(0, 0, 0, 0.75)
// gl.Color4f(1, 1, 1, 0.75)
gl.LoadIdentity()
gl.Translated(0, 0, camera_z_offset)
// TODO: Figure out why this doesn't draw over the whole screen
glh.With(glh.Disable(gl.LIGHTING), func() {
glh.DrawQuadd(-10, -10, 20, 20)
})
// gl.FrontFace(gl.CW)
// gl.Enable(gl.LIGHTING)
// gl.Disable(gl.LIGHT1)
// render_scene()
// gl.Enable(gl.LIGHT1)
}
})
}
_ = render_stars
for running {
running = glfw.WindowParam(glfw.Opened) == 1
glfw.SwapBuffers()
gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT | gl.STENCIL_BUFFER_BIT)
rotation := func() {
if tilt {
gl.Rotated(20, 1, 0, 0)
}
if polar {
gl.Rotated(90, 1, 0, 0)
}
gl.Rotated(d, 0, -1, 0)
}
// Star field
glh.With(glh.Matrix{gl.PROJECTION}, func() {
gl.LoadIdentity()
glu.Perspective(starfield_fov, aspect, 0, 1)
glh.With(glh.Matrix{gl.MODELVIEW}, func() {
gl.LoadIdentity()
rotation()
render_stars()
})
})
gl.MatrixMode(gl.MODELVIEW)
gl.LoadIdentity()
gl.Translated(0, 0, camera_z_offset)
rotation()
if rotating {
d += 0.2
}
_ = render_scene
render_scene()
_ = render_shadow_volume
render_shadow_volume()
}
}