Ejemplo n.º 1
0
//	Calculate normals by using cross products along the triangle strips
//	and averaging the normals for each vertex
func (terrain *Terrain) CalculateNormals() {
	var element_pos uint32 = 0
	var AB, AC, cross_product mgl32.Vec3

	// Loop through each triangle strip
	for x := uint32(0); x < terrain.XSize-1; x++ {
		// Loop along the strip
		for tri := uint32(0); tri < terrain.ZSize*2-2; tri++ {
			// Extract the vertex indices from the element array
			v1 := terrain.Indices[element_pos]
			v2 := terrain.Indices[element_pos+1]
			v3 := terrain.Indices[element_pos+2]

			// Define the two vectors for the triangle
			AB = terrain.Vertices[v2].Sub(terrain.Vertices[v1])
			AC = terrain.Vertices[v3].Sub(terrain.Vertices[v1])

			// Calculate the cross product
			cross_product = AB.Cross(AC)

			// Add this normal to the vertex normal for all three vertices in the triangle
			terrain.Normals[v1] = terrain.Normals[v1].Add(cross_product)
			terrain.Normals[v2] = terrain.Normals[v2].Add(cross_product)
			terrain.Normals[v3] = terrain.Normals[v3].Add(cross_product)

			// Move on to the next vertex along the strip
			element_pos++
		}

		// Jump past the lat two element positions to reach the start of the strip
		element_pos += 2
	}

	// Normalise the normals
	for v := uint32(0); v < terrain.XSize*terrain.ZSize; v++ {
		terrain.Normals[v] = terrain.Normals[v].Normalize()
	}
}
Ejemplo n.º 2
0
func (f *Frustum) SetCamera(p, l, u mgl32.Vec3) {
	Z := p.Sub(l)
	Z = safeNormalize(Z)

	X := u.Cross(Z)
	X = safeNormalize(X)

	Y := Z.Cross(X)

	nc := p.Sub(Z.Mul(f.near))
	fc := p.Sub(Z.Mul(f.far))

	ntl := nc.Add(Y.Mul(f.nh)).Sub(X.Mul(f.nw))
	ntr := nc.Add(Y.Mul(f.nh)).Add(X.Mul(f.nw))
	nbl := nc.Sub(Y.Mul(f.nh)).Sub(X.Mul(f.nw))
	nbr := nc.Sub(Y.Mul(f.nh)).Add(X.Mul(f.nw))

	ftl := fc.Add(Y.Mul(f.fh)).Sub(X.Mul(f.fw))
	ftr := fc.Add(Y.Mul(f.fh)).Add(X.Mul(f.fw))
	fbl := fc.Sub(Y.Mul(f.fh)).Sub(X.Mul(f.fw))
	fbr := fc.Sub(Y.Mul(f.fh)).Add(X.Mul(f.fw))

	const (
		top = iota
		bottom
		left
		right
		nearP
		farP
	)
	f.planes[top].setPoints(ntr, ntl, ftl)
	f.planes[bottom].setPoints(nbl, nbr, fbr)
	f.planes[left].setPoints(ntl, nbl, fbl)
	f.planes[right].setPoints(nbr, ntr, fbr)
	f.planes[nearP].setPoints(ntl, ntr, nbr)
	f.planes[farP].setPoints(ftr, ftl, fbl)
}
Ejemplo n.º 3
0
// 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
}