Esempio n. 1
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func ExampleRebase() {
	parent1 := NewTransformStack()

	scale := mgl32.Scale3D(2, 2, 2)
	rot := mgl32.HomogRotate3DY(mgl32.DegToRad(90))
	trans := mgl32.Translate3D(5, 5, 5)

	parent1.Push(trans)
	parent1.Push(rot)
	parent1.Push(scale)

	parent2 := parent1.Copy()

	trans2 := mgl32.Translate3D(1, 1, 1)
	rot2 := mgl32.HomogRotate3DX(mgl32.DegToRad(45))
	parent1.Push(trans2)
	parent1.Push(rot2)

	// Replay the pushes the changes from parent1 after the copy onto parent2, as if
	// they had been done on parent2 instead
	parent2, err := Rebase(parent1, 4, parent2)

	if err != nil {
		panic(err)
	}

	// Now parent2 and parent 1 should be the same!
	fmt.Println(parent2.Peek().ApproxEqualThreshold(parent1.Peek(), 1e-4))
	// Output: true
}
func init() {
	uvRotations = make(map[int]*mgl32.Mat4)
	for i := 0; i < 4; i++ {
		matrix := mgl32.Translate3D(0.5, 0.5, 0.0).
			Mul4(mgl32.HomogRotate3DZ(float32(math.Pi * float32(i) / 2.0))).
			Mul4(mgl32.Translate3D(-0.5, -0.5, 0.0))
		uvRotations[i] = &matrix
	}
}
Esempio n. 3
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func (k PianoKey) GetMtx() mgl32.Mat4 {
	axis := mgl32.Vec3{1, 0, 0}
	keyLen := float32(2.0)
	if !k.white {
		keyLen = 1.0
	}
	modelMtx := mgl32.Ident4()
	modelMtx = modelMtx.Mul4(mgl32.Translate3D(k.Pos[0], k.Pos[1], k.Pos[2]-2))
	modelMtx = modelMtx.Mul4(mgl32.HomogRotate3D(k.Angle, axis))
	modelMtx = modelMtx.Mul4(mgl32.Translate3D(0, 0, keyLen))
	modelMtx = modelMtx.Mul4(mgl32.Scale3D(0.5, 0.5, keyLen))

	return modelMtx
}
Esempio n. 4
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func (b *blockBreakComponent) Update() {
	if b.model != nil {
		b.model.Free()
	}
	bounds := chunkMap.Block(b.Location.X, b.Location.Y, b.Location.Z).CollisionBounds()
	tex := render.GetTexture(fmt.Sprintf("blocks/destroy_stage_%d", b.stage))

	var verts []*render.StaticVertex
	for _, bo := range bounds {
		// Slightly bigger than the block to prevent clipping
		bo = bo.Grow(0.01, 0.01, 0.01)
		verts = appendBox(verts,
			bo.Min.X(), bo.Min.Y(), bo.Min.Z(),
			bo.Max.X()-bo.Min.X(), bo.Max.Y()-bo.Min.Y(), bo.Max.Z()-bo.Min.Z(),
			[6]render.TextureInfo{
				tex, tex, tex, tex, tex, tex,
			})
	}
	b.model = render.NewStaticModel([][]*render.StaticVertex{verts})

	b.model.Matrix[0] = mgl32.Translate3D(
		float32(b.Location.X),
		-float32(b.Location.Y),
		float32(b.Location.Z),
	)
}
Esempio n. 5
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func TestStackMultiPush(t *testing.T) {
	stack := NewTransformStack()

	scale := mgl32.Scale3D(2, 2, 2)
	rot := mgl32.HomogRotate3DY(mgl32.DegToRad(90))
	trans := mgl32.Translate3D(4, 5, 6)

	stack.Push(trans)
	stack.Push(rot)

	if !stack.Peek().ApproxEqualThreshold(trans.Mul4(rot), 1e-4) {
		t.Errorf("Stack does not multiply first two pushes correctly")
	}

	stack.Push(scale)

	if !stack.Peek().ApproxEqualThreshold(trans.Mul4(rot).Mul4(scale), 1e-4) {
		t.Errorf("Stack does not multiple third push correctly")
	}

	stack.Unwind(2)
	stack.Push(scale)

	if !stack.Peek().ApproxEqualThreshold(trans.Mul4(scale), 1e-4) {
		t.Errorf("Unwinding and multiplying does not work correctly")
	}
}
Esempio n. 6
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func onPaint(glctx gl.Context, sz size.Event) {

	glctx.Viewport(0, 0, sz.WidthPx, sz.HeightPx)
	glctx.ClearColor(0.5, 0.5, 0.5, 1)
	glctx.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)

	glctx.UseProgram(program)

	projectionMtx = mgl32.Perspective(45, float32(width)/float32(height), 0.1, 100)

	arcBallMtx := arcball.getMtx()

	glctx.UniformMatrix4fv(projection, projectionMtx[:])

	glctx.UniformMatrix4fv(view, arcBallMtx[:])

	glctx.BindBuffer(gl.ARRAY_BUFFER, triBuf)
	glctx.EnableVertexAttribArray(position)
	glctx.EnableVertexAttribArray(color)
	glctx.EnableVertexAttribArray(normals)

	vertSize := 4 * (coordsPerVertex + colorPerVertex + normalsPerVertex)

	glctx.VertexAttribPointer(position, coordsPerVertex, gl.FLOAT, false, vertSize, 0)
	glctx.VertexAttribPointer(color, colorPerVertex, gl.FLOAT, false, vertSize, 4*coordsPerVertex)
	glctx.VertexAttribPointer(normals, normalsPerVertex, gl.FLOAT, false, vertSize, 4*(coordsPerVertex+colorPerVertex))

	glctx.DepthMask(true)

	glctx.Uniform3fv(lightPos, light.Pos[:])
	glctx.Uniform3fv(lightIntensity, light.Intensities[:])

	for _, k := range piano.Keys {
		glctx.Uniform4fv(tint, k.Color[:])

		mtx := k.GetMtx()
		normMat := mtx.Mat3().Inv().Transpose()
		glctx.UniformMatrix3fv(normalMatrix, normMat[:])
		glctx.UniformMatrix4fv(model, mtx[:])
		glctx.DrawArrays(gl.TRIANGLES, 0, len(triangleData)/vertSize)
	}

	modelMtx := mgl32.Ident4()
	modelMtx = modelMtx.Mul4(mgl32.Translate3D(worldPos.X(), worldPos.Y(), worldPos.Z()))
	modelMtx = modelMtx.Mul4(mgl32.Scale3D(0.5, 0.5, 0.5))

	/*
		glctx.Uniform4fv(tint, red[:])
		// Disable depthmask so we dont get the pixel depth of the cursor cube
		glctx.DepthMask(false)
		glctx.UniformMatrix4fv(model, modelMtx[:])
		glctx.DepthMask(true)
	*/

	glctx.DisableVertexAttribArray(position)
	glctx.DisableVertexAttribArray(color)
	glctx.DisableVertexAttribArray(normals)

	fps.Draw(sz)
}
Esempio n. 7
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func renderCallback(delta float64) {
	gl.Viewport(0, 0, int32(app.Width), int32(app.Height))
	gl.ClearColor(0.196078, 0.6, 0.8, 1.0) // some pov-ray sky blue
	gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT)

	// make the projection and view matrixes
	projection := mgl.Perspective(mgl.DegToRad(60.0), float32(app.Width)/float32(app.Height), 1.0, 200.0)
	view := app.CameraRotation.Mat4()
	view = view.Mul4(mgl.Translate3D(-app.CameraPos[0], -app.CameraPos[1], -app.CameraPos[2]))

	// draw the cube
	cube.Node.Draw(projection, view)

	// draw all of the bullets
	for _, bullet := range bullets {
		bullet.Node.Draw(projection, view)
	}

	// draw the backboard
	backboard.Node.Draw(projection, view)

	// draw the ground
	ground.Draw(projection, view)

	//time.Sleep(10 * time.Millisecond)
}
Esempio n. 8
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/* Update transform matrix and right/up/forward vectors */
func (t *Transform) Update(dt float32) {
	// todo: avoid recalculating unless something has changed

	/* Update transform */
	rad := t.Rotation.Mul(math.Pi / 180.0) // translate rotaiton to radians
	rotation := mgl.AnglesToQuat(rad[0], rad[1], rad[2], mgl.XYZ).Mat4()
	scaling := mgl.Scale3D(t.Scale[0], t.Scale[1], t.Scale[2])
	translation := mgl.Translate3D(t.Position[0], t.Position[1], t.Position[2])

	/* New transform matrix: S * R * T */
	//m := scaling.Mul4(rotation.Mul4(translation))
	m := translation.Mul4(rotation.Mul4(scaling))

	/* Grab axis vectors from transformation matrix */
	t.Right[0] = m[4*0+0] // first column
	t.Right[1] = m[4*1+0]
	t.Right[2] = m[4*2+0]
	t.Up[0] = m[4*0+1] // second column
	t.Up[1] = m[4*1+1]
	t.Up[2] = m[4*2+1]
	t.Forward[0] = -m[4*0+2] // third column
	t.Forward[1] = -m[4*1+2]
	t.Forward[2] = -m[4*2+2]

	/* Update transformation matrix */
	t.Matrix = m
}
Esempio n. 9
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func (c SpritesheetFrameConfig) ToSpritesheetFrame() *SpritesheetFrame {
	var (
		texX = c.textureX / c.textureOriginalW
		texY = c.textureY / c.textureOriginalH
		texW = c.textureW / c.textureOriginalW
		texH = c.textureH / c.textureOriginalH
	)
	var (
		texMove   = mgl32.Translate3D(texX, -texH-texY, 0.0)
		texScale  = mgl32.Scale3D(texW, texH, 1.0)
		texRotate = mgl32.HomogRotate3DZ(mgl32.DegToRad(0))
		texAdj    = texMove.Mul4(texScale).Mul4(texRotate).Transpose()
	)
	var (
		ptScale = mgl32.Scale3D(c.sourceW/c.pxPerUnit, c.sourceH/c.pxPerUnit, 1.0)
		ptAdj   = ptScale.Transpose()
	)
	return &SpritesheetFrame{
		Frame: FrameConfig{
			PointAdjustment:   ptAdj,
			TextureAdjustment: texAdj,
		},
		Width:  c.sourceW / c.pxPerUnit,
		Height: c.sourceH / c.pxPerUnit,
	}
}
Esempio n. 10
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// GetTransformMat4 creates a transform matrix: scale * transform
func (r *Renderable) GetTransformMat4() mgl.Mat4 {
	scaleMat := mgl.Scale3D(r.Scale[0], r.Scale[1], r.Scale[2])
	transMat := mgl.Translate3D(r.Location[0], r.Location[1], r.Location[2])
	localRotMat := r.LocalRotation.Mat4()
	rotMat := r.Rotation.Mat4()
	modelTransform := rotMat.Mul4(transMat).Mul4(localRotMat).Mul4(scaleMat)
	return modelTransform
}
Esempio n. 11
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func (this *TextRenderer) TextTransform(vertex mathgl.Vec4) mathgl.Vec4 {
	// apply font transforms
	scale := float32(this.size) / 100.0
	t := mathgl.Translate3D(curTotWidth, 0, 0).Mul4x1(vertex)

	t = mathgl.Scale3D(scale, scale, 1).Mul4x1(t)

	return t
}
Esempio n. 12
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func tickClouds(delta float64) {
	if Client != nil && Client.WorldType != wtOverworld {
		render.DrawClouds = false
		if sunModel != nil {
			sunModel.Free()
			moonModel.Free()
			sunModel = nil
			moonModel = nil
		}
		return
	}
	render.DrawClouds = true
	if Client == nil && Client.entity != nil {
		return
	}
	if sunModel == nil {
		genSunModel()
	}

	phase := int((Client.WorldAge / 24000) % 8)
	if phase != moonPhase {
		moonPhase = phase
		genSunModel()
	}

	x, y, z := Client.entity.Position()

	time := Client.WorldTime / 12000
	ox := math.Cos(time*math.Pi) * 300
	oy := math.Sin(time*math.Pi) * 300

	sunModel.Matrix[0] = mgl32.Translate3D(
		float32(x+ox),
		-float32(y+oy),
		float32(z),
	).Mul4(mgl32.Rotate3DZ(-float32(time * math.Pi)).Mat4())

	moonModel.Matrix[0] = mgl32.Translate3D(
		float32(x-ox),
		-float32(y-oy),
		float32(z),
	).Mul4(mgl32.Rotate3DZ(math.Pi - float32(time*math.Pi)).Mat4())
}
Esempio n. 13
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func (t *Transform2D) Update(dt float32) {
	/* Update transform */
	rad := t.Rotation * math.Pi / 180.0
	rotation := mgl.AnglesToQuat(0, 0, rad, mgl.XYZ).Mat4()
	scaling := mgl.Scale3D(t.Scale[0], t.Scale[1], 1)
	translation := mgl.Translate3D(t.Position[0], t.Position[1], t.Position[2])

	/* New transform matrix: S * R * T */
	t.Matrix = scaling.Mul4(rotation.Mul4(translation))
}
Esempio n. 14
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func TestReseed(t *testing.T) {
	stack := NewTransformStack()

	scale := mgl32.Scale3D(2, 2, 2)
	rot := mgl32.HomogRotate3DY(mgl32.DegToRad(90))
	trans := mgl32.Translate3D(4, 5, 6)

	stack.Push(trans)
	stack.Push(rot)
	stack.Push(scale)

	trans2 := mgl32.Translate3D(1, 2, 3)
	err := stack.Reseed(1, trans2)

	if err != nil {
		t.Fatalf("Rebase returned error when it should not %v", err)
	}

	if !stack.Peek().ApproxEqualThreshold(trans2.Mul4(rot).Mul4(scale), 1e-4) {
		t.Fatalf("Rebase does not remultiply correctly. Got\n %v expected\n %v. (Previous state:\n %v)", stack.Peek(), trans2.Mul4(rot).Mul4(scale), trans.Mul4(rot).Mul4(scale))
	}
}
Esempio n. 15
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func TestRebase(t *testing.T) {
	stack := NewTransformStack()
	stack2 := NewTransformStack()

	scale := mgl32.Scale3D(2, 2, 2)
	rot := mgl32.HomogRotate3DY(mgl32.DegToRad(90))
	trans := mgl32.Translate3D(4, 5, 6)
	trans2 := mgl32.Translate3D(1, 2, 3)

	stack.Push(trans)
	stack.Push(rot)

	stack2.Push(trans2)
	stack2.Push(scale)

	out, _ := Rebase(stack2, 1, stack)

	if !out.Peek().ApproxEqualThreshold(trans.Mul4(rot).Mul4(trans2).Mul4(scale), 1e-4) {
		t.Log("\n", out)
		t.Errorf("Rebase unsuccessful. Got\n %v, expected\n %v", out.Peek(), trans.Mul4(rot).Mul4(trans2).Mul4(scale))
	}
}
Esempio n. 16
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func (r *BatchRenderer) Draw(batch *Batch, x, y, rot float32) error {
	batch.Texture.Bind()
	gl.BindBuffer(gl.ARRAY_BUFFER, batch.Buffer)
	gl.EnableVertexAttribArray(r.PositionLoc)
	gl.VertexAttribPointer(r.PositionLoc, 3, gl.FLOAT, false, 5*4, gl.PtrOffset(0))
	gl.EnableVertexAttribArray(r.TextureLoc)
	gl.VertexAttribPointer(r.TextureLoc, 2, gl.FLOAT, false, 5*4, gl.PtrOffset(3*4))
	m := mgl32.Translate3D(x, y, 0.0).Mul4(mgl32.HomogRotate3DZ(rot))
	gl.UniformMatrix4fv(r.ModelViewLoc, 1, false, &m[0])
	gl.Uniform2f(r.TexOffsetLoc, batch.textureOffset.X(), batch.textureOffset.Y())
	gl.DrawArrays(gl.TRIANGLES, 0, int32(batch.Count))
	gl.BindBuffer(gl.ARRAY_BUFFER, 0)
	return nil
}
Esempio n. 17
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func (c Context) DrawRectangle(x, y, w, h float32, color Color) {

	gl.UseProgram(c.program)
	model := mgl32.Translate3D(x, y, 0).Mul4(mgl32.Scale3D(w, h, 0))
	modelUniform := gl.GetUniformLocation(c.program, gl.Str("model\x00"))
	gl.UniformMatrix4fv(modelUniform, 1, false, &model[0])

	colorArray := []float32{color.B, color.G, color.R}

	colorUniform := gl.GetUniformLocation(c.program, gl.Str("color\x00"))
	gl.Uniform4fv(colorUniform, 1, &colorArray[0])

	gl.DrawArrays(gl.TRIANGLES, 0, 6)
}
Esempio n. 18
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func ExampleReseed() {
	stack := NewTransformStack()

	scale := mgl32.Scale3D(2, 2, 2)
	rot := mgl32.HomogRotate3DY(mgl32.DegToRad(90))
	trans := mgl32.Translate3D(4, 5, 6)

	stack.Push(trans)
	stack.Push(rot)
	stack.Push(scale)

	fmt.Println("Initial state:\n", stack.Peek())

	trans2 := mgl32.Translate3D(1, 2, 3)

	err := stack.Reseed(1, trans2)
	if err == nil {
		panic("Rebase failed")
	}

	fmt.Println("After rebase:\n", stack.Peek())
	fmt.Println("Should be:\n", trans2.Mul4(rot).Mul4(scale))
}
// Render renders the bitmap with the center at given position
func (renderable *SimpleBitmapRenderable) Render(context *RenderContext, icons []PlacedIcon) {
	gl := renderable.gl

	renderable.withShader(func() {
		renderable.setMatrix(renderable.viewMatrixUniform, context.ViewMatrix())
		renderable.setMatrix(renderable.projectionMatrixUniform, context.ProjectionMatrix())

		gl.EnableVertexAttribArray(uint32(renderable.vertexPositionAttrib))
		gl.BindBuffer(opengl.ARRAY_BUFFER, renderable.vertexPositionBuffer)
		gl.VertexAttribOffset(uint32(renderable.vertexPositionAttrib), 3, opengl.FLOAT, false, 0, 0)
		gl.EnableVertexAttribArray(uint32(renderable.uvPositionAttrib))
		gl.BindBuffer(opengl.ARRAY_BUFFER, renderable.uvPositionBuffer)
		gl.VertexAttribOffset(uint32(renderable.uvPositionAttrib), 3, opengl.FLOAT, false, 0, 0)

		textureUnit := int32(0)
		gl.ActiveTexture(opengl.TEXTURE0 + uint32(textureUnit))
		gl.BindTexture(opengl.TEXTURE_2D, renderable.paletteTexture.Handle())
		gl.Uniform1i(renderable.paletteUniform, textureUnit)

		textureUnit = 1
		gl.ActiveTexture(opengl.TEXTURE0 + uint32(textureUnit))
		gl.Uniform1i(renderable.bitmapUniform, textureUnit)
		for _, icon := range icons {
			x, y := icon.Center()
			u, v := icon.Icon().UV()
			width, height := renderable.limitedSize(icon)
			modelMatrix := mgl.Ident4().
				Mul4(mgl.Translate3D(x, y, 0.0)).
				Mul4(mgl.Scale3D(width, height, 1.0))

			renderable.setMatrix(renderable.modelMatrixUniform, &modelMatrix)

			var uv = []float32{
				0.0, 0.0, 0.0,
				u, 0.0, 0.0,
				u, v, 0.0,

				u, v, 0.0,
				0.0, v, 0.0,
				0.0, 0.0, 0.0}
			gl.BindBuffer(opengl.ARRAY_BUFFER, renderable.uvPositionBuffer)
			gl.BufferData(opengl.ARRAY_BUFFER, len(uv)*4, uv, opengl.STATIC_DRAW)

			gl.BindTexture(opengl.TEXTURE_2D, icon.Icon().Handle())
			gl.DrawArrays(opengl.TRIANGLES, 0, 6)
		}
		gl.BindTexture(opengl.TEXTURE_2D, 0)
	})
}
// NewTextureRenderable returns a new instance of a texture renderable
func NewTextureRenderable(gl opengl.OpenGl, positionX, positionY float32, displaySize float32,
	paletteTexture graphics.Texture, bitmapTexture graphics.Texture) *TextureRenderable {
	vertexShader, err1 := opengl.CompileNewShader(gl, opengl.VERTEX_SHADER, textureVertexShaderSource)
	defer gl.DeleteShader(vertexShader)
	fragmentShader, err2 := opengl.CompileNewShader(gl, opengl.FRAGMENT_SHADER, textureFragmentShaderSource)
	defer gl.DeleteShader(fragmentShader)
	program, _ := opengl.LinkNewProgram(gl, vertexShader, fragmentShader)

	if err1 != nil {
		fmt.Fprintf(os.Stderr, "Failed to compile shader 1:\n", err1)
	}
	if err2 != nil {
		fmt.Fprintf(os.Stderr, "Failed to compile shader 2:\n", err2)
	}

	renderable := &TextureRenderable{
		gl:      gl,
		program: program,
		modelMatrix: mgl.Ident4().
			Mul4(mgl.Translate3D(positionX, positionY, 0.0)).
			Mul4(mgl.Scale3D(displaySize, displaySize, 1.0)),

		vertexArrayObject:       gl.GenVertexArrays(1)[0],
		vertexPositionBuffer:    gl.GenBuffers(1)[0],
		vertexPositionAttrib:    gl.GetAttribLocation(program, "vertexPosition"),
		modelMatrixUniform:      gl.GetUniformLocation(program, "modelMatrix"),
		viewMatrixUniform:       gl.GetUniformLocation(program, "viewMatrix"),
		projectionMatrixUniform: gl.GetUniformLocation(program, "projectionMatrix"),
		paletteTexture:          paletteTexture,
		paletteUniform:          gl.GetUniformLocation(program, "palette"),
		bitmapTexture:           bitmapTexture,
		bitmapUniform:           gl.GetUniformLocation(program, "bitmap")}

	renderable.withShader(func() {
		gl.BindBuffer(opengl.ARRAY_BUFFER, renderable.vertexPositionBuffer)
		limit := float32(1.0)
		var vertices = []float32{
			0.0, 0.0, 0.0,
			limit, 0.0, 0.0,
			limit, limit, 0.0,

			limit, limit, 0.0,
			0.0, limit, 0.0,
			0.0, 0.0, 0.0}
		gl.BufferData(opengl.ARRAY_BUFFER, len(vertices)*4, vertices, opengl.STATIC_DRAW)
	})

	return renderable
}
Esempio n. 21
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func (this *Transform) GetUpdatedModel() mathgl.Mat4 {
	Model := this.model
	Model = Model.Mul4(mathgl.Translate3D(float32(this.X), float32(this.Y), float32(this.Z)))
	// Model = Model.Mul4(mathgl.HomogRotate3DZ(float32(s.rot)))
	// Model = Model.Mul4(mathgl.HomogRotate3D(s.Rot, mathgl.Vec3{s.XR, s.YR, s.ZR}))

	// Euler rotation is easy.. no quaternions yet.. what a pain.
	Model = Model.Mul4(mathgl.Rotate3DX(this.XR * this.Rot).Mat4())
	Model = Model.Mul4(mathgl.Rotate3DY(this.YR * this.Rot).Mat4())
	Model = Model.Mul4(mathgl.Rotate3DZ(this.ZR * this.Rot).Mat4())

	Model = Model.Mul4(mathgl.Scale3D(float32(this.XS), float32(this.YS), float32(this.ZS)))

	return Model
}
Esempio n. 22
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// Draw will draw the billvboard in the x,y and z
func (billboard *Billboard) Draw(x float32, y float32, z float32) {

	model := mgl32.Translate3D(x, y, z)

	if shader := shader.GetActive(); shader != nil {
		gl.UniformMatrix4fv(shader.Model, 1, false, &model[0])
	}

	gl.BindVertexArray(billboard.vao)

	gl.ActiveTexture(gl.TEXTURE0)
	gl.BindTexture(gl.TEXTURE_2D, billboard.image)

	gl.DrawArrays(gl.TRIANGLES, 0, 1*2*3)
}
Esempio n. 23
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func (i *Instance) GetModel() mgl32.Mat4 {
	if i.dirty {
		var model mgl32.Mat4
		model = mgl32.Translate3D(
			i.position.X(),
			i.position.Y(),
			i.position.Z(),
		)
		model = model.Mul4(mgl32.HomogRotate3DZ(mgl32.DegToRad(i.rotation)))
		model = model.Mul4(mgl32.Scale3D(i.scale.X(), i.scale.Y(), i.scale.Z()))
		i.model = model
		i.dirty = false
	}
	return i.model
}
Esempio n. 24
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// DrawFrame will draw the sprite in the x,y and z with the specified frame from a spritesheet
func (sprite *Sprite) DrawFrame(x float32, y float32, z float32, scale float32, frame int) {

	model := mgl32.Translate3D(x, y, z)
	model = model.Mul4(mgl32.Scale3D(scale, scale, 1))
	// remember this is in radians!
	// model = model.Mul4(mgl32.HomogRotate3D(mgl32.DegToRad(90), mgl32.Vec3{0, 0, 1}))
	if shader := shader.GetActive(); shader != nil {
		gl.UniformMatrix4fv(shader.Model, 1, false, &model[0])
	}

	gl.BindVertexArray(sprite.vao)

	sprite.image.Bind()

	gl.DrawArrays(gl.TRIANGLES, int32(frame*6), 6)
}
// Render renders
func (renderable *TileSelectionRenderable) Render(context *RenderContext) {
	gl := renderable.gl

	renderable.withShader(func() {
		renderable.setMatrix32(renderable.viewMatrixUniform, context.ViewMatrix())
		renderable.setMatrix32(renderable.projectionMatrixUniform, context.ProjectionMatrix())

		gl.BindBuffer(opengl.ARRAY_BUFFER, renderable.vertexPositionBuffer)
		gl.VertexAttribOffset(uint32(renderable.vertexPositionAttrib), 3, opengl.FLOAT, false, 0, 0)

		renderable.query(func(coord editormodel.TileCoordinate) {
			x, y := coord.XY()
			modelMatrix := mgl.Translate3D(float32(x)*32.0, float32(63-y)*32.0, 0.0)
			renderable.setMatrix32(renderable.modelMatrixUniform, &modelMatrix)
			gl.DrawArrays(opengl.TRIANGLES, 0, 6)
		})
	})
}
// Render renders the highlight.
func (highlighter *BasicHighlighter) Render(context *RenderContext, areas []Area) {
	gl := highlighter.gl

	highlighter.withShader(func() {
		highlighter.setMatrix(highlighter.viewMatrixUniform, context.ViewMatrix())
		highlighter.setMatrix(highlighter.projectionMatrixUniform, context.ProjectionMatrix())

		gl.BindBuffer(opengl.ARRAY_BUFFER, highlighter.vertexPositionBuffer)
		gl.VertexAttribOffset(uint32(highlighter.vertexPositionAttrib), 3, opengl.FLOAT, false, 0, 0)

		for _, area := range areas {
			x, y := area.Center()
			width, height := area.Size()
			modelMatrix := mgl.Ident4().
				Mul4(mgl.Translate3D(x, y, 0.0)).
				Mul4(mgl.Scale3D(width, height, 1.0))

			highlighter.setMatrix(highlighter.modelMatrixUniform, &modelMatrix)
			gl.DrawArrays(opengl.TRIANGLES, 0, 6)
		}
	})
}
// NewTextRenderable returns a new instance of a text renderable
func NewTextRenderable(gl opengl.OpenGl, positionX, positionY float32, displaySize float32,
	paletteTexture graphics.Texture) *TextRenderable {
	vertexShader, err1 := opengl.CompileNewShader(gl, opengl.VERTEX_SHADER, textVertexShaderSource)
	defer gl.DeleteShader(vertexShader)
	fragmentShader, err2 := opengl.CompileNewShader(gl, opengl.FRAGMENT_SHADER, textFragmentShaderSource)
	defer gl.DeleteShader(fragmentShader)
	program, _ := opengl.LinkNewProgram(gl, vertexShader, fragmentShader)

	if err1 != nil {
		fmt.Fprintf(os.Stderr, "Failed to compile shader 1:\n", err1)
	}
	if err2 != nil {
		fmt.Fprintf(os.Stderr, "Failed to compile shader 2:\n", err2)
	}

	renderable := &TextRenderable{
		gl:      gl,
		program: program,
		modelMatrix: mgl.Ident4().
			Mul4(mgl.Translate3D(positionX, positionY, 0.0)).
			Mul4(mgl.Scale3D(displaySize, displaySize, 1.0)),

		vertexArrayObject:       gl.GenVertexArrays(1)[0],
		vertexPositionBuffer:    gl.GenBuffers(1)[0],
		vertexPositionAttrib:    gl.GetAttribLocation(program, "vertexPosition"),
		uvPositionBuffer:        gl.GenBuffers(1)[0],
		uvPositionAttrib:        gl.GetAttribLocation(program, "uvPosition"),
		modelMatrixUniform:      gl.GetUniformLocation(program, "modelMatrix"),
		viewMatrixUniform:       gl.GetUniformLocation(program, "viewMatrix"),
		projectionMatrixUniform: gl.GetUniformLocation(program, "projectionMatrix"),
		paletteTexture:          paletteTexture,
		paletteUniform:          gl.GetUniformLocation(program, "palette"),
		bitmapUniform:           gl.GetUniformLocation(program, "bitmap"),
		text:                    ""}

	return renderable
}
func (cam *LimitedCamera) updateViewMatrix() {
	scaleFactor := cam.scaleFactor()
	cam.viewMatrix = mgl.Ident4().
		Mul4(mgl.Scale3D(scaleFactor, scaleFactor, 1.0)).
		Mul4(mgl.Translate3D(cam.viewOffsetX, cam.viewOffsetY, 0))
}
Esempio n. 29
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func programLoop(window *win.Window) error {

	// the linked shader program determines how the data will be rendered
	vertShader, err := gfx.NewShaderFromFile("shaders/phong.vert", gl.VERTEX_SHADER)
	if err != nil {
		return err
	}

	fragShader, err := gfx.NewShaderFromFile("shaders/phong.frag", gl.FRAGMENT_SHADER)
	if err != nil {
		return err
	}

	program, err := gfx.NewProgram(vertShader, fragShader)
	if err != nil {
		return err
	}
	defer program.Delete()

	lightFragShader, err := gfx.NewShaderFromFile("shaders/light.frag", gl.FRAGMENT_SHADER)
	if err != nil {
		return err
	}

	// special shader program so that lights themselves are not affected by lighting
	lightProgram, err := gfx.NewProgram(vertShader, lightFragShader)
	if err != nil {
		return err
	}

	VAO := createVAO(cubeVertices, nil)
	lightVAO := createVAO(cubeVertices, nil)

	// ensure that triangles that are "behind" others do not draw over top of them
	gl.Enable(gl.DEPTH_TEST)

	camera := cam.NewFpsCamera(mgl32.Vec3{0, 0, 3}, mgl32.Vec3{0, 1, 0}, -90, 0, window.InputManager())

	for !window.ShouldClose() {

		// swaps in last buffer, polls for window events, and generally sets up for a new render frame
		window.StartFrame()

		// update camera position and direction from input evevnts
		camera.Update(window.SinceLastFrame())

		// background color
		gl.ClearColor(0, 0, 0, 1.0)
		gl.Clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT) // depth buffer needed for DEPTH_TEST

		// cube rotation matrices
		rotateX := (mgl32.Rotate3DX(mgl32.DegToRad(-45 * float32(glfw.GetTime()))))
		rotateY := (mgl32.Rotate3DY(mgl32.DegToRad(-45 * float32(glfw.GetTime()))))
		rotateZ := (mgl32.Rotate3DZ(mgl32.DegToRad(-45 * float32(glfw.GetTime()))))

		// creates perspective
		fov := float32(60.0)
		projectTransform := mgl32.Perspective(mgl32.DegToRad(fov),
			float32(window.Width())/float32(window.Height()),
			0.1,
			100.0)

		camTransform := camera.GetTransform()
		lightPos := mgl32.Vec3{0.6, 1, 0.1}
		lightTransform := mgl32.Translate3D(lightPos.X(), lightPos.Y(), lightPos.Z()).Mul4(
			mgl32.Scale3D(0.2, 0.2, 0.2))

		program.Use()
		gl.UniformMatrix4fv(program.GetUniformLocation("view"), 1, false, &camTransform[0])
		gl.UniformMatrix4fv(program.GetUniformLocation("project"), 1, false,
			&projectTransform[0])

		gl.BindVertexArray(VAO)

		// draw each cube after all coordinate system transforms are bound

		// obj is colored, light is white
		gl.Uniform3f(program.GetUniformLocation("material.ambient"), 1.0, 0.5, 0.31)
		gl.Uniform3f(program.GetUniformLocation("material.diffuse"), 1.0, 0.5, 0.31)
		gl.Uniform3f(program.GetUniformLocation("material.specular"), 0.5, 0.5, 0.5)
		gl.Uniform1f(program.GetUniformLocation("material.shininess"), 32.0)

		lightColor := mgl32.Vec3{
			float32(math.Sin(glfw.GetTime() * 1)),
			float32(math.Sin(glfw.GetTime() * 0.35)),
			float32(math.Sin(glfw.GetTime() * 0.65)),
		}

		diffuseColor := mgl32.Vec3{
			0.5 * lightColor[0],
			0.5 * lightColor[1],
			0.5 * lightColor[2],
		}
		ambientColor := mgl32.Vec3{
			0.2 * lightColor[0],
			0.2 * lightColor[1],
			0.2 * lightColor[2],
		}

		gl.Uniform3f(program.GetUniformLocation("light.ambient"),
			ambientColor[0], ambientColor[1], ambientColor[2])
		gl.Uniform3f(program.GetUniformLocation("light.diffuse"),
			diffuseColor[0], diffuseColor[1], diffuseColor[2])
		gl.Uniform3f(program.GetUniformLocation("light.specular"), 1.0, 1.0, 1.0)
		gl.Uniform3f(program.GetUniformLocation("light.position"), lightPos.X(), lightPos.Y(), lightPos.Z())

		for _, pos := range cubePositions {

			// turn the cubes into rectangular prisms for more fun
			worldTranslate := mgl32.Translate3D(pos[0], pos[1], pos[2])
			worldTransform := worldTranslate.Mul4(
				rotateX.Mul3(rotateY).Mul3(rotateZ).Mat4(),
			)

			gl.UniformMatrix4fv(program.GetUniformLocation("model"), 1, false,
				&worldTransform[0])

			gl.DrawArrays(gl.TRIANGLES, 0, 36)
		}
		gl.BindVertexArray(0)

		// Draw the light obj after the other boxes using its separate shader program
		// this means that we must re-bind any uniforms
		lightProgram.Use()
		gl.BindVertexArray(lightVAO)
		gl.UniformMatrix4fv(lightProgram.GetUniformLocation("model"), 1, false, &lightTransform[0])
		gl.UniformMatrix4fv(lightProgram.GetUniformLocation("view"), 1, false, &camTransform[0])
		gl.UniformMatrix4fv(lightProgram.GetUniformLocation("project"), 1, false, &projectTransform[0])
		gl.DrawArrays(gl.TRIANGLES, 0, 36)

		gl.BindVertexArray(0)

		// end of draw loop
	}

	return nil
}
Esempio n. 30
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func (cube *Cube) Translate(Tx, Ty, Tz float32) {
	cube.Model = cube.Model.Mul4(mgl32.Translate3D(Tx, Ty, Tz))
}