Exemplo n.º 1
0
 def on_initialize(self, event):
     # Note: read as bytes, then decode; py2.6 compat
     with open(op.join(this_dir, 'vertex_vispy.glsl'), 'rb') as fid:
         vert = fid.read().decode('ASCII')
     with open(op.join(this_dir, 'fragment_seed.glsl'), 'rb') as f:
         frag_seed = f.read().decode('ASCII')
     with open(op.join(this_dir, 'fragment_flood.glsl'), 'rb') as f:
         frag_flood = f.read().decode('ASCII')
     with open(op.join(this_dir, 'fragment_display.glsl'), 'rb') as f:
         frag_display = f.read().decode('ASCII')
     self.programs = [
         Program(vert, frag_seed),
         Program(vert, frag_flood),
         Program(vert, frag_display)
     ]
     # Initialize variables
     # using two FBs slightly faster than switching on one
     self.fbo_to = [FrameBuffer(), FrameBuffer()]
     self._setup_textures('shape1.tga')
     vtype = np.dtype([('position', 'f4', 2), ('texcoord', 'f4', 2)])
     vertices = np.zeros(4, dtype=vtype)
     vertices['position'] = [[-1., -1.], [-1., 1.], [1., -1.], [1., 1.]]
     vertices['texcoord'] = [[0., 0.], [0., 1.], [1., 0.], [1., 1.]]
     vertices = VertexBuffer(vertices)
     for program in self.programs:
         program.bind(vertices)
Exemplo n.º 2
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    def __init__(self):
        self.use_shaders = True
        app.Canvas.__init__(self, size=(512, 512), keys='interactive')
        # Note: read as bytes, then decode; py2.6 compat
        with open(op.join(this_dir, 'vertex_vispy.glsl'), 'rb') as fid:
            vert = fid.read().decode('ASCII')
        with open(op.join(this_dir, 'fragment_seed.glsl'), 'rb') as f:
            frag_seed = f.read().decode('ASCII')
        with open(op.join(this_dir, 'fragment_flood.glsl'), 'rb') as f:
            frag_flood = f.read().decode('ASCII')
        with open(op.join(this_dir, 'fragment_display.glsl'), 'rb') as f:
            frag_display = f.read().decode('ASCII')
        self.programs = [
            Program(vert, frag_seed),
            Program(vert, frag_flood),
            Program(vert, frag_display)
        ]
        # Initialize variables
        # using two FBs slightly faster than switching on one
        self.fbo_to = [FrameBuffer(), FrameBuffer()]
        self._setup_textures('shape1.tga')
        vtype = np.dtype([('position', 'f4', 2), ('texcoord', 'f4', 2)])
        vertices = np.zeros(4, dtype=vtype)
        vertices['position'] = [[-1., -1.], [-1., 1.], [1., -1.], [1., 1.]]
        vertices['texcoord'] = [[0., 0.], [0., 1.], [1., 0.], [1., 1.]]
        vertices = VertexBuffer(vertices)
        for program in self.programs:
            program.bind(vertices)
        self._timer = app.Timer('auto', self.update, start=True)

        self.show()
Exemplo n.º 3
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def test_use_framebuffer():
    """Test drawing to a framebuffer"""
    shape = (100, 300)  # for some reason Windows wants a tall window...
    data = np.random.rand(*shape).astype(np.float32)
    use_shape = shape + (3, )
    with Canvas(size=shape[::-1]) as c:
        orig_tex = Texture2D(data)
        fbo_tex = Texture2D(use_shape, format='rgb')
        rbo = RenderBuffer(shape, 'color')
        fbo = FrameBuffer(color=fbo_tex)
        c._glir.set_verbose(True)
        assert_equal(c.size, shape[::-1])
        set_viewport((0, 0) + c.size)
        with fbo:
            draw_texture(orig_tex)
        draw_texture(fbo_tex)
        out_tex = _screenshot()[::-1, :, 0].astype(np.float32)
        assert_equal(out_tex.shape, c.size[::-1])
        assert_raises(TypeError, FrameBuffer.color_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.depth_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, fbo, 1.)
        fbo.color_buffer = rbo
        fbo.depth_buffer = RenderBuffer(shape)
        fbo.stencil_buffer = None
        print((fbo.color_buffer, fbo.depth_buffer, fbo.stencil_buffer))
        clear(color='black')
        with fbo:
            clear(color='black')
            draw_texture(orig_tex)
            out_rbo = _screenshot()[:, :, 0].astype(np.float32)
    assert_allclose(data * 255., out_tex, atol=1)
    assert_allclose(data * 255., out_rbo, atol=1)
Exemplo n.º 4
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def test_use_framebuffer():
    """Test drawing to a framebuffer"""
    shape = (100, 300)  # for some reason Windows wants a tall window...
    data = np.random.rand(*shape).astype(np.float32)
    use_shape = shape + (3,)
    with Canvas(size=shape[::-1]) as c:
        orig_tex = Texture2D(data)
        fbo_tex = Texture2D(use_shape, format='rgb')
        rbo = RenderBuffer(shape, 'color')
        fbo = FrameBuffer(color=fbo_tex)
        c.context.glir.set_verbose(True)
        assert_equal(c.size, shape[::-1])
        set_viewport((0, 0) + c.size)
        with fbo:
            draw_texture(orig_tex)
        draw_texture(fbo_tex)
        out_tex = _screenshot()[::-1, :, 0].astype(np.float32)
        assert_equal(out_tex.shape, c.size[::-1])
        assert_raises(TypeError, FrameBuffer.color_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.depth_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, fbo, 1.)
        fbo.color_buffer = rbo
        fbo.depth_buffer = RenderBuffer(shape)
        fbo.stencil_buffer = None
        print((fbo.color_buffer, fbo.depth_buffer, fbo.stencil_buffer))
        clear(color='black')
        with fbo:
            clear(color='black')
            draw_texture(orig_tex)
            out_rbo = _screenshot()[:, :, 0].astype(np.float32)
    assert_allclose(data * 255., out_tex, atol=1)
    assert_allclose(data * 255., out_rbo, atol=1)
Exemplo n.º 5
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def test_use_framebuffer():
    """Test drawing to a framebuffer"""
    shape = (100, 100)
    data = np.random.rand(*shape).astype(np.float32)
    orig_tex = Texture2D(data)
    use_shape = shape + (3,)
    fbo_tex = Texture2D(shape=use_shape, dtype=np.ubyte, format='rgb')
    rbo = ColorBuffer(shape=shape)
    fbo = FrameBuffer(color=fbo_tex)
    with Canvas(size=(100, 100)) as c:
        set_viewport((0, 0) + c.size)
        with fbo:
            draw_texture(orig_tex)
        draw_texture(fbo_tex)
        out_tex = _screenshot()[::-1, :, 0].astype(np.float32)
        assert_raises(TypeError, FrameBuffer.color_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.depth_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, fbo, 1.)
        fbo.color_buffer = rbo
        fbo.depth_buffer = DepthBuffer(shape)
        fbo.stencil_buffer = None
        print((fbo.color_buffer, fbo.depth_buffer, fbo.stencil_buffer))
        clear(color='black')
        with fbo:
            clear(color='black')
            draw_texture(orig_tex)
            out_rbo = _screenshot()[:, :, 0].astype(np.float32)
    assert_allclose(data * 255., out_tex, atol=1)
    assert_allclose(data * 255., out_rbo, atol=1)
Exemplo n.º 6
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def test_renderbuffer():

    # Set with no args
    assert_raises(ValueError, RenderBuffer)

    # Set shape only
    R = RenderBuffer((10, 20))
    assert R.shape == (10, 20)
    assert R.format is None

    # Set both shape and format
    gloo.context.get_current_glir_queue().clear()
    R = RenderBuffer((10, 20), 'color')
    assert R.shape == (10, 20)
    assert R.format is 'color'
    #
    glir_cmds = R._glir.clear()
    assert len(glir_cmds) == 2
    assert glir_cmds[0][0] == 'CREATE'
    assert glir_cmds[1][0] == 'SIZE'

    # Orther formats
    assert RenderBuffer((10, 20), 'depth').format == 'depth'
    assert RenderBuffer((10, 20), 'stencil').format == 'stencil'

    # Test reset size and format
    R.resize((9, 9), 'depth')
    assert R.shape == (9, 9)
    assert R.format == 'depth'
    R.resize((8, 8), 'stencil')
    assert R.shape == (8, 8)
    assert R.format == 'stencil'

    # Wrong formats
    assert_raises(ValueError, R.resize, (9, 9), 'no_format')
    assert_raises(ValueError, R.resize, (9, 9), [])

    # Resizable
    R = RenderBuffer((10, 20), 'color', False)
    assert_raises(RuntimeError, R.resize, (9, 9), 'color')

    # Attaching sets the format
    F = FrameBuffer()
    #
    R = RenderBuffer((9, 9))
    F.color_buffer = R
    assert F.color_buffer is R
    assert R.format == 'color'
    #
    F.depth_buffer = RenderBuffer((9, 9))
    assert F.depth_buffer.format == 'depth'
    #
    F.stencil_buffer = RenderBuffer((9, 9))
    assert F.stencil_buffer.format == 'stencil'
Exemplo n.º 7
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def test_renderbuffer():
    
    # Set with no args
    assert_raises(ValueError, RenderBuffer)
    
    # Set shape only
    R = RenderBuffer((10, 20))
    assert R.shape == (10, 20)
    assert R.format is None
    
    # Set both shape and format
    gloo.get_a_context().glir.clear()
    R = RenderBuffer((10, 20), 'color')
    assert R.shape == (10, 20)
    assert R.format is 'color'
    #
    glir_cmds = R._context.glir.clear()
    assert len(glir_cmds) == 2
    assert glir_cmds[0][0] == 'CREATE'
    assert glir_cmds[1][0] == 'SIZE'
    
    # Orther formats
    assert RenderBuffer((10, 20), 'depth').format == 'depth'
    assert RenderBuffer((10, 20), 'stencil').format == 'stencil'
    
    # Test reset size and format
    R.resize((9, 9), 'depth')
    assert R.shape == (9, 9)
    assert R.format == 'depth'
    R.resize((8, 8), 'stencil')
    assert R.shape == (8, 8)
    assert R.format == 'stencil'
    
    # Wrong formats
    assert_raises(ValueError, R.resize, (9, 9), 'no_format')
    assert_raises(ValueError, R.resize, (9, 9), [])
    
    # Resizable
    R = RenderBuffer((10, 20), 'color', False)
    assert_raises(RuntimeError, R.resize, (9, 9), 'color')
    
    # Attaching sets the format
    F = FrameBuffer()
    #
    R = RenderBuffer((9, 9))
    F.color_buffer = R
    assert F.color_buffer is R
    assert R.format == 'color'
    #
    F.depth_buffer = RenderBuffer((9, 9))
    assert F.depth_buffer.format == 'depth'
    #
    F.stencil_buffer = RenderBuffer((9, 9))
    assert F.stencil_buffer.format == 'stencil'
Exemplo n.º 8
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    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------

        texcoord = [(0, 0), (0, 1), (1, 0), (1, 1)]
        vertices = [(-2, -1, 0), (-2, +1, 0), (+2, -1, 0), (+2, +1, 0)]

        vertices = VertexBuffer(vertices)

        camera_pitch = 0.0  # Degrees
        self.rotate = [camera_pitch, 0, 0]
        self.translate = [0, 0, -3]

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        scale(model, 1, 1, 1)
        self.phi = 0

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube['position'] = vertices
        # 4640 x 2256
        imtex = cv2.imread(os.path.join(img_path, 'stage.jpg'))
        self.cube['texcoord'] = texcoord
        self.cube["texture"] = np.uint8(
            np.clip(imtex + np.random.randint(-60, 20, size=imtex.shape), 0,
                    255)) + 5
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        color = Texture2D((640, 640, 3), interpolation='linear')
        self.framebuffer = FrameBuffer(color, RenderBuffer((640, 640)))

        self.quad = Program(quad_vertex, quad_fragment)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]

        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]

        self.quad['texture'] = color

        self.objects = [self.cube]

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self.pub_timer = app.Timer(0.1, connect=self.send_ros_img, start=True)
        self._set_projection(self.size)
Exemplo n.º 9
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    def on_initialize(self, event):
        self.rho = 0.0
        # Build cube data
        # --------------------------------------
        self.checker = Program(cube_vertex, cube_fragment)
        self.checker['texture'] = checkerboard()
        self.checker['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.checker['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]

        # sheet, indices = make_sheet((960, 1080))
        # sheet_buffer = VertexBuffer(sheet)

        left_eye = Texture2D((960, 1080, 3), interpolation='linear')
        self.left_eye_buffer = FrameBuffer(left_eye, RenderBuffer((960, 1080)))
        # Build program
        # --------------------------------------
        self.view = np.eye(4, dtype=np.float32)
        self.program = Program(vertex, fragment)
        distortion_buffer = VertexBuffer(make_distortion())
        self.program.bind(distortion_buffer)
        self.program['rotation'] = self.view
        self.program['texture'] = left_eye

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self._set_projection(self.size)
Exemplo n.º 10
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def initialize_renderer():
    """Initialize the OpenGL renderer.

    For an OpenGL based renderer this sets up the viewport and creates
    the shader programs.

    """
    global fbuffer
    global fbuffer_prog
    global default_prog

    fbuffer = FrameBuffer()

    vertices = np.array(
        [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]], np.float32)
    texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                         dtype=np.float32)

    fbuf_vertices = VertexBuffer(data=vertices)
    fbuf_texcoords = VertexBuffer(data=texcoords)

    fbuffer_prog = Program(src_fbuffer.vert, src_fbuffer.frag)
    fbuffer_prog['texcoord'] = fbuf_texcoords
    fbuffer_prog['position'] = fbuf_vertices

    default_prog = Program(src_default.vert, src_default.frag)

    reset_view()
Exemplo n.º 11
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    def __init__(self):
        app.Canvas.__init__(self, title='Grayscott Reaction-Diffusion',
                            size=(512, 512), keys='interactive')

        self.scale = 4
        self.comp_size = (256, 256)
        comp_w, comp_h = self.comp_size
        dt = 1.0
        dd = 1.5
        species = {
            # name : [r_u, r_v, f, k]
            'Bacteria 1': [0.16, 0.08, 0.035, 0.065],
            'Bacteria 2': [0.14, 0.06, 0.035, 0.065],
            'Coral': [0.16, 0.08, 0.060, 0.062],
            'Fingerprint': [0.19, 0.05, 0.060, 0.062],
            'Spirals': [0.10, 0.10, 0.018, 0.050],
            'Spirals Dense': [0.12, 0.08, 0.020, 0.050],
            'Spirals Fast': [0.10, 0.16, 0.020, 0.050],
            'Unstable': [0.16, 0.08, 0.020, 0.055],
            'Worms 1': [0.16, 0.08, 0.050, 0.065],
            'Worms 2': [0.16, 0.08, 0.054, 0.063],
            'Zebrafish': [0.16, 0.08, 0.035, 0.060]
        }
        P = np.zeros((comp_h, comp_w, 4), dtype=np.float32)
        P[:, :] = species['Unstable']

        UV = np.zeros((comp_h, comp_w, 4), dtype=np.float32)
        UV[:, :, 0] = 1.0
        r = 32
        UV[comp_h / 2 - r:comp_h / 2 + r,
           comp_w / 2 - r:comp_w / 2 + r, 0] = 0.50
        UV[comp_h / 2 - r:comp_h / 2 + r,
           comp_w / 2 - r:comp_w / 2 + r, 1] = 0.25
        UV += np.random.uniform(0.0, 0.01, (comp_h, comp_w, 4))
        UV[:, :, 2] = UV[:, :, 0]
        UV[:, :, 3] = UV[:, :, 1]

        self.pingpong = 1
        self.compute = Program(compute_vertex, compute_fragment, 4)
        self.compute["params"] = P
        self.compute["texture"] = UV
        self.compute["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.compute["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.compute['dt'] = dt
        self.compute['dx'] = 1.0 / comp_w
        self.compute['dy'] = 1.0 / comp_h
        self.compute['dd'] = dd
        self.compute['pingpong'] = self.pingpong

        self.render = Program(render_vertex, render_fragment, 4)
        self.render["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.render["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.render["texture"] = self.compute["texture"]
        self.render['pingpong'] = self.pingpong

        self.fbo = FrameBuffer(self.compute["texture"],
                               RenderBuffer(self.comp_size))
        set_state(depth_test=False, clear_color='black')

        self._timer = app.Timer('auto', connect=self.update, start=True)
Exemplo n.º 12
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    def initialize_renderer(self):
        self.fbuffer = FrameBuffer()

        vertices = np.array(
            [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]],
            np.float32)
        texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                             dtype=np.float32)

        self.fbuf_vertices = VertexBuffer(data=vertices)
        self.fbuf_texcoords = VertexBuffer(data=texcoords)

        self.fbuffer_prog['texcoord'] = self.fbuf_texcoords
        self.fbuffer_prog['position'] = self.fbuf_vertices

        self.vertex_buffer = VertexBuffer()
        self.index_buffer = IndexBuffer()
Exemplo n.º 13
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    def on_initialize(self, event):
        self.scale = 4
        self.comp_size = (256, 256)
        comp_w, comp_h = self.comp_size
        dt = 1.0
        dd = 1.5
        species = {
            # name : [r_u, r_v, f, k]
            'Bacteria 1': [0.16, 0.08, 0.035, 0.065],
            'Bacteria 2': [0.14, 0.06, 0.035, 0.065],
            'Coral': [0.16, 0.08, 0.060, 0.062],
            'Fingerprint': [0.19, 0.05, 0.060, 0.062],
            'Spirals': [0.10, 0.10, 0.018, 0.050],
            'Spirals Dense': [0.12, 0.08, 0.020, 0.050],
            'Spirals Fast': [0.10, 0.16, 0.020, 0.050],
            'Unstable': [0.16, 0.08, 0.020, 0.055],
            'Worms 1': [0.16, 0.08, 0.050, 0.065],
            'Worms 2': [0.16, 0.08, 0.054, 0.063],
            'Zebrafish': [0.16, 0.08, 0.035, 0.060]
        }
        P = np.zeros((comp_h, comp_w, 4), dtype=np.float32)
        P[:, :] = species['Unstable']

        UV = np.zeros((comp_h, comp_w, 4), dtype=np.float32)
        UV[:, :, 0] = 1.0
        r = 32
        UV[comp_h / 2 - r:comp_h / 2 + r, comp_w / 2 - r:comp_w / 2 + r,
           0] = 0.50
        UV[comp_h / 2 - r:comp_h / 2 + r, comp_w / 2 - r:comp_w / 2 + r,
           1] = 0.25
        UV += np.random.uniform(0.0, 0.01, (comp_h, comp_w, 4))
        UV[:, :, 2] = UV[:, :, 0]
        UV[:, :, 3] = UV[:, :, 1]

        self.pingpong = 1
        self.compute = Program(compute_vertex, compute_fragment, 4)
        self.compute["params"] = P
        self.compute["texture"] = UV
        self.compute["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.compute["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.compute['dt'] = dt
        self.compute['dx'] = 1.0 / comp_w
        self.compute['dy'] = 1.0 / comp_h
        self.compute['dd'] = dd
        self.compute['pingpong'] = self.pingpong

        self.render = Program(render_vertex, render_fragment, 4)
        self.render["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.render["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.render["texture"] = self.compute["texture"]
        self.render['pingpong'] = self.pingpong

        self.fbo = FrameBuffer(self.compute["texture"],
                               DepthBuffer(self.comp_size))
        set_state(depth_test=False, clear_color='black')
Exemplo n.º 14
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    def __init__(self):
        app.Canvas.__init__(self,
                            title="Conway game of life",
                            size=(512, 512),
                            keys='interactive')

        # Build programs
        # --------------
        self.comp_size = self.size
        size = self.comp_size + (4, )
        Z = np.zeros(size, dtype=np.float32)
        Z[...] = np.random.randint(0, 2, size)
        Z[:256, :256, :] = 0
        gun = """
        ........................O...........
        ......................O.O...........
        ............OO......OO............OO
        ...........O...O....OO............OO
        OO........O.....O...OO..............
        OO........O...O.OO....O.O...........
        ..........O.....O.......O...........
        ...........O...O....................
        ............OO......................"""
        x, y = 0, 0
        for i in range(len(gun)):
            if gun[i] == '\n':
                y += 1
                x = 0
            elif gun[i] == 'O':
                Z[y, x] = 1
            x += 1

        self.pingpong = 1
        self.compute = Program(compute_vertex, compute_fragment, 4)
        self.compute["texture"] = Z
        self.compute["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.compute["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.compute['dx'] = 1.0 / size[1]
        self.compute['dy'] = 1.0 / size[0]
        self.compute['pingpong'] = self.pingpong

        self.render = Program(render_vertex, render_fragment, 4)
        self.render["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.render["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.render["texture"] = self.compute["texture"]
        self.render['pingpong'] = self.pingpong

        self.fbo = FrameBuffer(self.compute["texture"],
                               RenderBuffer(self.comp_size))
        set_state(depth_test=False, clear_color='black')

        self._timer = app.Timer('auto', connect=self.update, start=True)

        self.show()
Exemplo n.º 15
0
def test_use_framebuffer():
    """Test drawing to a framebuffer"""
    shape = (100, 300)  # for some reason Windows wants a tall window...
    data = np.random.rand(*shape).astype(np.float32)
    use_shape = shape + (3, )
    with Canvas(size=shape[::-1]) as c:
        c.app.process_events()
        c.set_current()
        if c.app.backend_name.lower() == 'pyqt5':
            # PyQt5 on OSX for some reason sets this to 1024x768...
            c.size = shape[::-1]
        c.app.process_events()
        orig_tex = Texture2D(data)
        fbo_tex = Texture2D(use_shape, format='rgb')
        rbo = RenderBuffer(shape, 'color')
        fbo = FrameBuffer(color=fbo_tex)
        c.context.glir.set_verbose(True)
        assert c.size == shape[::-1]
        c.set_current()
        set_viewport((0, 0) + c.size)
        with fbo:
            draw_texture(orig_tex)
        draw_texture(fbo_tex)
        out_tex = _screenshot()[::-1, :, 0].astype(np.float32)
        assert out_tex.shape == c.size[::-1]
        assert_raises(TypeError, FrameBuffer.color_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.depth_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, fbo, 1.)
        fbo.color_buffer = rbo
        fbo.depth_buffer = RenderBuffer(shape)
        fbo.stencil_buffer = None
        print((fbo.color_buffer, fbo.depth_buffer, fbo.stencil_buffer))
        clear(color='black')
        with fbo:
            clear(color='black')
            draw_texture(orig_tex)
            out_rbo = _screenshot()[:, :, 0].astype(np.float32)
    assert_allclose(data * 255., out_tex, atol=1)
    assert_allclose(data * 255., out_rbo, atol=1)
Exemplo n.º 16
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def test_use_framebuffer():
    """Test drawing to a framebuffer"""
    shape = (100, 300)  # for some reason Windows wants a tall window...
    data = np.random.rand(*shape).astype(np.float32)
    use_shape = shape + (3,)
    with Canvas(size=shape[::-1]) as c:
        c.app.process_events()
        c.set_current()
        if c.app.backend_name.lower() == 'pyqt5':
            # PyQt5 on OSX for some reason sets this to 1024x768...
            c.size = shape[::-1]
        c.app.process_events()
        orig_tex = Texture2D(data)
        fbo_tex = Texture2D(use_shape, format='rgb')
        rbo = RenderBuffer(shape, 'color')
        fbo = FrameBuffer(color=fbo_tex)
        c.context.glir.set_verbose(True)
        assert c.size == shape[::-1]
        c.set_current()
        set_viewport((0, 0) + c.size)
        with fbo:
            draw_texture(orig_tex)
        draw_texture(fbo_tex)
        out_tex = _screenshot()[::-1, :, 0].astype(np.float32)
        assert out_tex.shape == c.size[::-1]
        assert_raises(TypeError, FrameBuffer.color_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.depth_buffer.fset, fbo, 1.)
        assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, fbo, 1.)
        fbo.color_buffer = rbo
        fbo.depth_buffer = RenderBuffer(shape)
        fbo.stencil_buffer = None
        print((fbo.color_buffer, fbo.depth_buffer, fbo.stencil_buffer))
        clear(color='black')
        with fbo:
            clear(color='black')
            draw_texture(orig_tex)
            out_rbo = _screenshot()[:, :, 0].astype(np.float32)
    assert_allclose(data * 255., out_tex, atol=1)
    assert_allclose(data * 255., out_rbo, atol=1)
Exemplo n.º 17
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    def initialize_renderer(self):
        self.fbuffer = FrameBuffer()

        vertices = np.array(
            [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]],
            np.float32)
        texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                             dtype=np.float32)

        self.fbuf_vertices = VertexBuffer(data=vertices)
        self.fbuf_texcoords = VertexBuffer(data=texcoords)

        self.fbuffer_prog = Program(src_fbuffer.vert, src_fbuffer.frag)
        self.fbuffer_prog['texcoord'] = self.fbuf_texcoords
        self.fbuffer_prog['position'] = self.fbuf_vertices

        self.vertex_buffer = VertexBuffer()
        self.index_buffer = IndexBuffer()

        self.default_prog = Program(src_default.vert, src_default.frag)

        self.reset_view()
Exemplo n.º 18
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    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------
        vertices, indices, _ = create_cube()
        vertices = VertexBuffer(vertices)
        self.indices = IndexBuffer(indices)

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        translate(view, 0, 0, -7)
        self.phi, self.theta = 60, 20
        rotate(model, self.theta, 0, 0, 1)
        rotate(model, self.phi, 0, 1, 0)

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube.bind(vertices)
        self.cube["texture"] = checkerboard()
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        depth = DepthBuffer((512, 512))
        color = Texture2D(shape=(512, 512, 3), interpolation='linear',
                          dtype=np.dtype(np.float32))
        self.framebuffer = FrameBuffer(color=color, depth=depth)

        self.quad = Program(quad_vertex, quad_fragment, count=4)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.quad['texture'] = color

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self._set_projection(self.size)
Exemplo n.º 19
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    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------

        texcoord = [(0, 0), (0, 1), (1, 0), (1, 1)]
        vertices = [(-2, -1, 0), (-2, +1, 0), (+2, -1, 0), (+2, +1, 0)]

        vertices = VertexBuffer(vertices)

        camera_pitch = 0.0 # Degrees
        self.rotate = [camera_pitch, 0, 0]
        self.translate = [0, 0, -3]

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        scale(model, 1, 1, 1)
        self.phi = 0

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube['position'] = vertices
        # 4640 x 2256
        imtex = cv2.imread(os.path.join(img_path, 'stage.jpg')) 
        self.cube['texcoord'] = texcoord
        self.cube["texture"] = np.uint8(np.clip(imtex + np.random.randint(-60, 20, size=imtex.shape), 0, 255)) + 5
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view


        color = Texture2D((640, 640, 3), interpolation='linear')
        self.framebuffer = FrameBuffer(color, RenderBuffer((640, 640)))

        self.quad = Program(quad_vertex, quad_fragment)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]

        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]

        self.quad['texture'] = color

        self.objects = [self.cube]

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self.pub_timer = app.Timer(0.1, connect=self.send_ros_img, start=True)
        self._set_projection(self.size)
Exemplo n.º 20
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    def on_initialize(self, event):
        # Build programs
        # --------------
        self.comp_size = (512, 512)
        size = self.comp_size + (4, )
        Z = np.zeros(size, dtype=np.float32)
        Z[...] = np.random.randint(0, 2, size)
        Z[:256, :256, :] = 0
        gun = """
        ........................O...........
        ......................O.O...........
        ............OO......OO............OO
        ...........O...O....OO............OO
        OO........O.....O...OO..............
        OO........O...O.OO....O.O...........
        ..........O.....O.......O...........
        ...........O...O....................
        ............OO......................"""
        x, y = 0, 0
        for i in range(len(gun)):
            if gun[i] == '\n':
                y += 1
                x = 0
            elif gun[i] == 'O':
                Z[y, x] = 1
            x += 1

        self.pingpong = 1
        self.compute = Program(compute_vertex, compute_fragment, 4)
        self.compute["texture"] = Z
        self.compute["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.compute["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.compute['dx'] = 1.0 / size[1]
        self.compute['dy'] = 1.0 / size[0]
        self.compute['pingpong'] = self.pingpong

        self.render = Program(render_vertex, render_fragment, 4)
        self.render["position"] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.render["texcoord"] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.render["texture"] = self.compute["texture"]
        self.render['pingpong'] = self.pingpong

        self.fbo = FrameBuffer(self.compute["texture"],
                               DepthBuffer(self.comp_size))
        set_state(depth_test=False, clear_color='black')
Exemplo n.º 21
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    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------
        vertices, indices, _ = cube()
        vertices = VertexBuffer(vertices)
        self.indices = IndexBuffer(indices)

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        translate(view, 0, 0, -7)
        self.phi, self.theta = 60, 20
        rotate(model, self.theta, 0, 0, 1)
        rotate(model, self.phi, 0, 1, 0)

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube.bind(vertices)
        self.cube["texture"] = checkerboard()
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        depth = DepthBuffer((512, 512))
        color = Texture2D(shape=(512, 512, 3), dtype=np.dtype(np.float32))
        self.framebuffer = FrameBuffer(color=color, depth=depth)

        self.quad = Program(quad_vertex, quad_fragment, count=4)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.quad['texture'] = color
        self.quad["texture"].interpolation = 'linear'

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer(1.0 / 60)
        self.timer.connect(self.on_timer)
        self.timer.start()
        self._set_projection(self.size)
Exemplo n.º 22
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    def __init__(self):
        app.Canvas.__init__(self,
                            title='Framebuffer post-processing',
                            keys='interactive',
                            size=(512, 512))

        # Build cube data
        # --------------------------------------
        vertices, indices, _ = create_cube()
        vertices = VertexBuffer(vertices)
        self.indices = IndexBuffer(indices)

        # Build program
        # --------------------------------------
        view = translate((0, 0, -7))
        self.phi, self.theta = 60, 20
        model = rotate(self.theta, (0, 0, 1)).dot(rotate(self.phi, (0, 1, 0)))

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube.bind(vertices)
        self.cube["texture"] = checkerboard()
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        color = Texture2D((512, 512, 3), interpolation='linear')
        self.framebuffer = FrameBuffer(color, RenderBuffer((512, 512)))

        self.quad = Program(quad_vertex, quad_fragment, count=4)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.quad['texture'] = color

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self._set_projection(self.physical_size)

        self.show()
Exemplo n.º 23
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class Canvas(app.Canvas):

    def __init__(self):
        app.Canvas.__init__(self, title='Framebuffer post-processing',
                            keys='interactive', size=(512, 512))

    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------
        vertices, indices, _ = create_cube()
        vertices = VertexBuffer(vertices)
        self.indices = IndexBuffer(indices)

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        translate(view, 0, 0, -7)
        self.phi, self.theta = 60, 20
        rotate(model, self.theta, 0, 0, 1)
        rotate(model, self.phi, 0, 1, 0)

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube.bind(vertices)
        self.cube["texture"] = checkerboard()
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        depth = DepthBuffer((512, 512))
        color = Texture2D(shape=(512, 512, 3), interpolation='linear',
                          dtype=np.dtype(np.float32))
        self.framebuffer = FrameBuffer(color=color, depth=depth)

        self.quad = Program(quad_vertex, quad_fragment, count=4)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.quad['texture'] = color

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self._set_projection(self.size)

    def on_draw(self, event):
        self.framebuffer.activate()
        set_viewport(0, 0, 512, 512)
        clear(color=True, depth=True)
        set_state(depth_test=True)
        self.cube.draw('triangles', self.indices)
        self.framebuffer.deactivate()
        set_viewport(0, 0, *self.size)
        clear(color=True)
        set_state(depth_test=False)
        self.quad.draw('triangle_strip')

    def on_resize(self, event):
        self._set_projection(event.size)
    
    def _set_projection(self, size):
        width, height = size
        set_viewport(0, 0, width, height)
        projection = perspective(30.0, width / float(height), 2.0, 10.0)
        self.cube['projection'] = projection

    def on_timer(self, event):
        self.theta += .5
        self.phi += .5
        model = np.eye(4, dtype=np.float32)
        rotate(model, self.theta, 0, 0, 1)
        rotate(model, self.phi, 0, 1, 0)
        self.cube['model'] = model
        self.update()
Exemplo n.º 24
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class OpenGLRenderer(ABC):
    def __init__(self, src_fbuffer, src_default):
        self.default_prog = None
        self.fbuffer_prog = None

        self.fbuffer = None
        self.fbuffer_tex_front = None
        self.fbuffer_tex_back = None

        self.vertex_buffer = None
        self.index_buffer = None

        # Renderer Globals: STYLE/MATERIAL PROPERTIES
        #
        self.style = Style()

        # Renderer Globals: Curves
        self.stroke_weight = 1
        self.stroke_cap = ROUND
        self.stroke_join = MITER

        # Renderer Globals
        # VIEW MATRICES, ETC
        #
        self.viewport = None
        self.texture_viewport = None
        self.transform_matrix = np.identity(4)
        self.projection_matrix = np.identity(4)

        # Renderer Globals: RENDERING
        self.draw_queue = []

        # Shaders
        self.fbuffer_prog = Program(src_fbuffer.vert, src_fbuffer.frag)
        self.default_prog = Program(src_default.vert, src_default.frag)

    def initialize_renderer(self):
        self.fbuffer = FrameBuffer()

        vertices = np.array(
            [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]],
            np.float32)
        texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                             dtype=np.float32)

        self.fbuf_vertices = VertexBuffer(data=vertices)
        self.fbuf_texcoords = VertexBuffer(data=texcoords)

        self.fbuffer_prog['texcoord'] = self.fbuf_texcoords
        self.fbuffer_prog['position'] = self.fbuf_vertices

        self.vertex_buffer = VertexBuffer()
        self.index_buffer = IndexBuffer()

    def render_default(self, draw_type, draw_queue):
        # 1. Get the maximum number of vertices persent in the shapes
        # in the draw queue.
        #
        if len(draw_queue) == 0:
            return

        num_vertices = 0
        for vertices, _, _ in draw_queue:
            num_vertices = num_vertices + len(vertices)

        # 2. Create empty buffers based on the number of vertices.
        #
        data = np.zeros(num_vertices,
                        dtype=[('position', np.float32, 3),
                               ('color', np.float32, 4)])

        # 3. Loop through all the shapes in the geometry queue adding
        # it's information to the buffer.
        #
        sidx = 0
        draw_indices = []
        for vertices, idx, color in draw_queue:
            num_shape_verts = len(vertices)

            data['position'][sidx:(sidx +
                                   num_shape_verts), ] = np.array(vertices)

            color_array = np.array([color] * num_shape_verts)
            data['color'][sidx:sidx + num_shape_verts, :] = color_array

            draw_indices.append(sidx + idx)

            sidx += num_shape_verts

        self.vertex_buffer.set_data(data)
        self.index_buffer.set_data(np.hstack(draw_indices))

        # 4. Bind the buffer to the shader.
        #
        self.default_prog.bind(self.vertex_buffer)

        # 5. Draw the shape using the proper shape type and get rid of
        # the buffers.
        #
        self.default_prog.draw(draw_type, indices=self.index_buffer)

    def cleanup(self):
        """Run the clean-up routine for the renderer.

        This method is called when all drawing has been completed and the
        program is about to exit.

        """
        self.default_prog.delete()
        self.fbuffer_prog.delete()
        self.fbuffer.delete()

    def _transform_vertices(self, vertices, local_matrix, global_matrix):
        return np.dot(np.dot(vertices, local_matrix.T), global_matrix.T)[:, :3]
Exemplo n.º 25
0
class Renderer2D:
    def __init__(self):
        self.default_prog = None
        self.fbuffer_prog = None
        self.texture_prog = None
        self.line_prog = None

        self.fbuffer = None
        self.fbuffer_tex_front = None
        self.fbuffer_tex_back = None

        self.vertex_buffer = None
        self.index_buffer = None

        ## Renderer Globals: USEFUL CONSTANTS
        self.COLOR_WHITE = (1, 1, 1, 1)
        self.COLOR_BLACK = (0, 0, 0, 1)
        self.COLOR_DEFAULT_BG = (0.8, 0.8, 0.8, 1.0)

        ## Renderer Globals: STYLE/MATERIAL PROPERTIES
        ##
        self.background_color = self.COLOR_DEFAULT_BG

        self.fill_color = self.COLOR_WHITE
        self.fill_enabled = True

        self.stroke_color = self.COLOR_BLACK
        self.stroke_enabled = True

        self.tint_color = self.COLOR_BLACK
        self.tint_enabled = False

        ## Renderer Globals: Curves
        self.stroke_weight = 1
        self.stroke_cap = 2
        self.stroke_join = 0

        ## Renderer Globals
        ## VIEW MATRICES, ETC
        ##
        self.viewport = None
        self.texture_viewport = None
        self.transform_matrix = np.identity(4)
        self.modelview_matrix = np.identity(4)
        self.projection_matrix = np.identity(4)

        ## Renderer Globals: RENDERING
        self.draw_queue = []

    def initialize_renderer(self):
        self.fbuffer = FrameBuffer()

        vertices = np.array(
            [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]],
            np.float32)
        texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                             dtype=np.float32)

        self.fbuf_vertices = VertexBuffer(data=vertices)
        self.fbuf_texcoords = VertexBuffer(data=texcoords)

        self.fbuffer_prog = Program(src_fbuffer.vert, src_fbuffer.frag)
        self.fbuffer_prog['texcoord'] = self.fbuf_texcoords
        self.fbuffer_prog['position'] = self.fbuf_vertices

        self.vertex_buffer = VertexBuffer()
        self.index_buffer = IndexBuffer()

        self.default_prog = Program(src_default.vert, src_default.frag)
        self.texture_prog = Program(src_texture.vert, src_texture.frag)
        self.texture_prog['texcoord'] = self.fbuf_texcoords

        self.reset_view()

    def reset_view(self):
        self.viewport = (
            0,
            0,
            int(builtins.width * builtins.pixel_x_density),
            int(builtins.height * builtins.pixel_y_density),
        )
        self.texture_viewport = (
            0,
            0,
            builtins.width,
            builtins.height,
        )

        gloo.set_viewport(*self.viewport)

        cz = (builtins.height / 2) / math.tan(math.radians(30))
        self.projection_matrix = matrix.perspective_matrix(
            math.radians(60), builtins.width / builtins.height, 0.1 * cz,
            10 * cz)
        self.modelview_matrix = matrix.translation_matrix(-builtins.width / 2, \
                    builtins.height / 2, \
                    -cz)
        self.modelview_matrix = self.modelview_matrix.dot(
            matrix.scale_transform(1, -1, 1))

        self.transform_matrix = np.identity(4)

        self.default_prog['modelview'] = self.modelview_matrix.T.flatten()
        self.default_prog['projection'] = self.projection_matrix.T.flatten()

        self.texture_prog['modelview'] = self.modelview_matrix.T.flatten()
        self.texture_prog['projection'] = self.projection_matrix.T.flatten()

        self.line_prog = Program(src_line.vert, src_line.frag)

        self.line_prog['modelview'] = self.modelview_matrix.T.flatten()
        self.line_prog['projection'] = self.projection_matrix.T.flatten()
        self.line_prog["height"] = builtins.height

        self.fbuffer_tex_front = Texture2D(
            (builtins.height, builtins.width, 3))
        self.fbuffer_tex_back = Texture2D((builtins.height, builtins.width, 3))

        for buf in [self.fbuffer_tex_front, self.fbuffer_tex_back]:
            self.fbuffer.color_buffer = buf
            with self.fbuffer:
                self.clear()

    def clear(self, color=True, depth=True):
        """Clear the renderer background."""
        gloo.set_state(clear_color=self.background_color)
        gloo.clear(color=color, depth=depth)

    def _comm_toggles(self, state=True):
        gloo.set_state(blend=state)
        gloo.set_state(depth_test=state)

        if state:
            gloo.set_state(blend_func=('src_alpha', 'one_minus_src_alpha'))
            gloo.set_state(depth_func='lequal')

    @contextmanager
    def draw_loop(self):
        """The main draw loop context manager.
		"""

        self.transform_matrix = np.identity(4)

        self.default_prog['modelview'] = self.modelview_matrix.T.flatten()
        self.default_prog['projection'] = self.projection_matrix.T.flatten()

        self.fbuffer.color_buffer = self.fbuffer_tex_back

        with self.fbuffer:
            gloo.set_viewport(*self.texture_viewport)
            self._comm_toggles()
            self.fbuffer_prog['texture'] = self.fbuffer_tex_front
            self.fbuffer_prog.draw('triangle_strip')

            yield

            self.flush_geometry()
            self.transform_matrix = np.identity(4)

        gloo.set_viewport(*self.viewport)
        self._comm_toggles(False)
        self.clear()
        self.fbuffer_prog['texture'] = self.fbuffer_tex_back
        self.fbuffer_prog.draw('triangle_strip')

        self.fbuffer_tex_front, self.fbuffer_tex_back = self.fbuffer_tex_back, self.fbuffer_tex_front

    def _transform_vertices(self, vertices, local_matrix, global_matrix):
        return np.dot(np.dot(vertices, local_matrix.T), global_matrix.T)[:, :3]

    def _add_to_draw_queue_simple(self, stype, vertices, idx, fill, stroke,
                                  stroke_weight, stroke_cap, stroke_join):
        """Adds shape of stype to draw queue
		"""
        if stype == 'lines':
            self.draw_queue.append(
                (stype, (vertices, idx, stroke, stroke_weight, stroke_cap,
                         stroke_join)))
        else:
            self.draw_queue.append((stype, (vertices, idx, fill)))

    def render(self, shape):
        fill = shape.fill.normalized if shape.fill else None
        stroke = shape.stroke.normalized if shape.stroke else None
        stroke_weight = shape.stroke_weight
        stroke_cap = shape.stroke_cap
        stroke_join = shape.stroke_join

        obj_list = get_render_primitives(shape)
        for obj in obj_list:
            stype, vertices, idx = obj
            # Transform vertices
            vertices = self._transform_vertices(
                np.hstack([vertices, np.ones((len(vertices), 1))]),
                shape._matrix, self.transform_matrix)
            # Add to draw queue
            self._add_to_draw_queue_simple(stype, vertices, idx, fill, stroke,
                                           stroke_weight, stroke_cap,
                                           stroke_join)

    def flush_geometry(self):
        """Flush all the shape geometry from the draw queue to the GPU.
		"""
        current_queue = []
        for index, shape in enumerate(self.draw_queue):
            current_shape = self.draw_queue[index][0]
            current_queue.append(self.draw_queue[index][1])

            if current_shape == "lines":
                self.render_line(current_queue)
            else:
                self.render_default(current_shape, current_queue)

            current_queue = []

        self.draw_queue = []

    def render_default(self, draw_type, draw_queue):
        # 1. Get the maximum number of vertices persent in the shapes
        # in the draw queue.
        #
        if len(draw_queue) == 0:
            return

        num_vertices = 0
        for vertices, _, _ in draw_queue:
            num_vertices = num_vertices + len(vertices)

        # 2. Create empty buffers based on the number of vertices.
        #
        data = np.zeros(num_vertices,
                        dtype=[('position', np.float32, 3),
                               ('color', np.float32, 4)])

        # 3. Loop through all the shapes in the geometry queue adding
        # it's information to the buffer.
        #
        sidx = 0
        draw_indices = []
        for vertices, idx, color in draw_queue:
            num_shape_verts = len(vertices)

            data['position'][sidx:(sidx + num_shape_verts), ] = vertices

            color_array = np.array([color] * num_shape_verts)
            data['color'][sidx:sidx + num_shape_verts, :] = color_array

            draw_indices.append(sidx + idx)

            sidx += num_shape_verts

        self.vertex_buffer.set_data(data)
        self.index_buffer.set_data(np.hstack(draw_indices))

        # 4. Bind the buffer to the shader.
        #
        self.default_prog.bind(self.vertex_buffer)

        # 5. Draw the shape using the proper shape type and get rid of
        # the buffers.
        #
        self.default_prog.draw(draw_type, indices=self.index_buffer)

    def render_line(self, queue):
        '''
		This rendering algorithm works by tesselating the line into
		multiple triangles.

		Reference: https://blog.mapbox.com/drawing-antialiased-lines-with-opengl-8766f34192dc
		'''

        if len(queue) == 0:
            return

        pos = []
        posPrev = []
        posCurr = []
        posNext = []
        markers = []
        side = []

        linewidth = []
        join_type = []
        cap_type = []
        color = []

        for line in queue:
            if len(line[1]) == 0:
                continue

            for segment in line[1]:
                for i in range(
                        len(segment) -
                        1):  # the data is sent to renderer in line segments
                    for j in [0, 0, 1, 0, 1,
                              1]:  # all the vertices of triangles
                        if i + j - 1 >= 0:
                            posPrev.append(line[0][segment[i + j - 1]])
                        else:
                            posPrev.append(line[0][segment[i + j]])

                        if i + j + 1 < len(segment):
                            posNext.append(line[0][segment[i + j + 1]])
                        else:
                            posNext.append(line[0][segment[i + j]])

                        posCurr.append(line[0][segment[i + j]])

                    markers.extend(
                        [1.0, -1.0, -1.0, -1.0, 1.0,
                         -1.0])  # Is the vertex up/below the line segment
                    side.extend([1.0, 1.0, -1.0, 1.0, -1.0,
                                 -1.0])  # Left or right side of the segment
                    pos.extend([line[0][segment[i]]] *
                               6)  # Left vertex of each segment
                    linewidth.extend([line[3]] * 6)
                    join_type.extend([line[5]] * 6)
                    cap_type.extend([line[4]] * 6)
                    color.extend([line[2]] * 6)

        if len(pos) == 0:
            return

        posPrev = np.array(posPrev, np.float32)
        posCurr = np.array(posCurr, np.float32)
        posNext = np.array(posNext, np.float32)
        markers = np.array(markers, np.float32)
        side = np.array(side, np.float32)
        pos = np.array(pos, np.float32)
        linewidth = np.array(linewidth, np.float32)
        join_type = np.array(join_type, np.float32)
        cap_type = np.array(cap_type, np.float32)
        color = np.array(color, np.float32)

        self.line_prog['pos'] = gloo.VertexBuffer(pos)
        self.line_prog['posPrev'] = gloo.VertexBuffer(posPrev)
        self.line_prog['posCurr'] = gloo.VertexBuffer(posCurr)
        self.line_prog['posNext'] = gloo.VertexBuffer(posNext)
        self.line_prog['marker'] = gloo.VertexBuffer(markers)
        self.line_prog['side'] = gloo.VertexBuffer(side)
        self.line_prog['linewidth'] = gloo.VertexBuffer(linewidth)
        self.line_prog['join_type'] = gloo.VertexBuffer(join_type)
        self.line_prog['cap_type'] = gloo.VertexBuffer(cap_type)
        self.line_prog["color"] = gloo.VertexBuffer(color)

        self.line_prog.draw('triangles')

    def render_image(self, image, location, size):
        """Render the image.

		:param image: image to be rendered
		:type image: builtins.Image

		:param location: top-left corner of the image
		:type location: tuple | list | builtins.Vector

		:param size: target size of the image to draw.
		:type size: tuple | list | builtins.Vector
		"""
        self.flush_geometry()

        self.texture_prog[
            'fill_color'] = self.tint_color if self.tint_enabled else self.COLOR_WHITE
        self.texture_prog['transform'] = self.transform_matrix.T.flatten()

        x, y = location
        sx, sy = size
        imx, imy = image.size
        data = np.zeros(4,
                        dtype=[('position', np.float32, 2),
                               ('texcoord', np.float32, 2)])
        data['texcoord'] = np.array(
            [[0.0, 1.0], [1.0, 1.0], [0.0, 0.0], [1.0, 0.0]], dtype=np.float32)
        data['position'] = np.array(
            [[x, y + sy], [x + sx, y + sy], [x, y], [x + sx, y]],
            dtype=np.float32)

        self.texture_prog['texture'] = image._texture
        self.texture_prog.bind(VertexBuffer(data))
        self.texture_prog.draw('triangle_strip')

    def cleanup(self):
        """Run the clean-up routine for the renderer.

		This method is called when all drawing has been completed and the
		program is about to exit.

		"""
        self.default_prog.delete()
        self.fbuffer_prog.delete()
        self.line_prog.delete()
        self.fbuffer.delete()
Exemplo n.º 26
0
    def __init__(self, canvas, background_color=(0,0,0,0), text_color=(1,1,1)):
        # State.register_button(position, text)
        
        self.canvas = canvas
        self.text = None
        self.tcolor = (text_color[0],text_color[1],text_color[2], 1)
        self.bcolor = background_color
        self.timer = 0
        self.fade_timer = 0
        self.projection = np.eye(4)
        self.view = np.eye(4)
        self.model = np.eye(4)
        height, width = 5.0, 15.0  # Meters

        orientation_vector = (1, 1, 0)
        unit_orientation_angle = np.array(orientation_vector) / np.linalg.norm(orientation_vector)

        scale_factor = 0.4
        lowest_button = -5.2 
        midset = 0.2
        position = -2
        
        scale(self.model, scale_factor)
        #yrotate(self.model, -90)
        # rotate(self.model, 30, *unit_orientation_angle)
        offset = (position * ((height + midset) * scale_factor))
        translate(self.model, -4.4, lowest_button + offset, -10)

        self.size = (int(height*100), int(width*100))

        # Add texture coordinates
        # Rectangle of height height
        self.vertices = np.array([
            [-width / 2, -height / 2, 0],
            [ width / 2, -height / 2, 0],
            [ width / 2,  height / 2, 0],
            [-width / 2,  height / 2, 0],
        ], dtype=np.float32)
        
        self.tex_coords = np.array([
            [0, 0],
            [1, 0],
            [1, 1],
            [0, 1],

        ], dtype=np.float32)

        self.indices = IndexBuffer([
            0, 1, 2,
            2, 3, 0,
        ])

        self.program = Program(self.toast_vertex_shader, self.toast_fragment_shader)

        self.program['vertex_position'] = self.vertices
        self.program['default_texcoord'] = self.tex_coords
        self.program['view'] = self.view
        self.program['model'] = self.model
        self.program['projection'] = self.projection
        self.program['background_color'] = (0,0,0,0) # no background yet
        self.program['text_color'] = (0,0,0,0) # no text yet

        # self.texture = Texture2D(shape=(1000, 1000) + (3,))        
        # self.text_buffer = FrameBuffer(self.texture, RenderBuffer((1000, 1000)))
        self.texture = Texture2D(shape=self.size + (3,))        
        self.text_buffer = FrameBuffer(self.texture, RenderBuffer(self.size))

        self.program['texture'] = self.texture
        #self.program['text_color'] = self.tcolor # set the tcolor
        #self.program['background_color'] = self.bcolor # set the tcolor
        self.first = False # do not draw text until needed
        self.make_text('Default Text') # Create Empty text object
Exemplo n.º 27
0
class Canvas(app.Canvas):

    def __init__(self):
        app.Canvas.__init__(self, title='Framebuffer post-processing',
                            keys='interactive', size=(640, 640))
        rospy.init_node('simulated_arm_view')
        self.img_pub = Image_Publisher('/sim/arm_camera/image_rect', encoding='8UC1')

        self.listener = tf.TransformListener()

    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------

        texcoord = [(0, 0), (0, 1), (1, 0), (1, 1)]
        vertices = [(-1, -1, 0), (-1, +1, 0), (+1, -1, 0), (+1, +1, 0)]

        vertices = VertexBuffer(vertices)

        #self.listener.waitForTransform("/robot", "/wrist_joint", rospy.Time(), rospy.Duration(4))

        """while not rospy.is_shutdown():
            try:
                now = rospy.Time.now()
                self.listener.waitForTransform("/wrist_joint", "/robot", rospy.Time(), rospy.Duration(4))
                (trans,rot) = listener.lookupTransform("/wrist_joint", "/robot", rospy.Time(), rospy.Duration(4))
        """

        #pos, rot = self.listener.lookupTransform("/wrist_joint", "/robot", rospy.Time(0))

        #print list(pos)
        
        camera_pitch = 0.0 # Degrees
        self.rotate = [camera_pitch, 0, 0]
        #self.translate = list(pos)
        self.translate = [0, 0, -5]

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        scale(model, 10, 10, 10)
        self.phi = 0

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube['position'] = vertices
        # 4640 x 2256
        imtex = cv2.imread(os.path.join(img_path, 'rubixFront.jpg')) 
        self.cube['texcoord'] = texcoord
        self.cube["texture"] = np.uint8(np.clip(imtex + np.random.randint(-60, 20, size=imtex.shape), 0, 255)) + 5
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view


        color = Texture2D((640, 640, 3), interpolation='linear')
        self.framebuffer = FrameBuffer(color, RenderBuffer((640, 640)))

        self.quad = Program(quad_vertex, quad_fragment)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]

        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]

        self.quad['texture'] = color

        self.objects = [self.cube]

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self.pub_timer = app.Timer(0.1, connect=self.send_ros_img, start=True)
        self._set_projection(self.size)

    def send_ros_img(self, event):
        # Read frame buffer, get rid of alpha channel
        img = self.framebuffer.read()[:, :, 2]
        self.img_pub.publish(img)

    def on_draw(self, event):

        # Image rect
        with self.framebuffer:
            set_clear_color('gray')
            clear(color=True, depth=True)
            set_state(depth_test=True)
            self.cube.draw('triangle_strip')

        set_clear_color('pink')
        clear(color=True)
        set_state(depth_test=True)
        self.quad.draw('triangle_strip')

    def on_resize(self, event):
        self._set_projection(event.size)

    def _set_projection(self, size):
        width, height = self.size
        set_viewport(0, 0, width, height)
        projection = perspective(100.0, width / float(height), 1.0, 20.0)
        self.cube['projection'] = projection

    def on_timer(self, event):

        model = np.eye(4, dtype=np.float32)
        #scale(model, 1, 1, 1)
        self.cube['model'] = model

        self.view = np.eye(4)
        xrotate(self.view, self.rotate[0])
        yrotate(self.view, self.rotate[1])
        zrotate(self.view, self.rotate[2])
        translate(self.view, *self.translate)

        self.listener.waitForTransform("/robot", "/wrist_joint", rospy.Time(), rospy.Duration(4))
        
        pos, rot = self.listener.lookupTransform("/robot", "/wrist_joint", rospy.Time(0))

        print list(pos)
        
        self.translate[0] = -list(pos)[0] * 10
        self.translate[1] = -list(pos)[1] * 10
        self.translate[2] = -5

        self.cube['view'] = self.view



        self.update()

    
    def on_key_press(self, event):
        """Controls -
        a(A) - move left
        d(D) - move right
        w(W) - move up
        s(S) - move down"""
        

        if(event.text.lower() == 'p'):
            print(self.view)

        elif(event.text.lower() == 'd'):
            self.translate[0] += -0.1
        elif(event.text.lower() == 'a'):
            self.translate[0] += 0.1

        elif(event.text.lower() == 'w'):
            self.translate[1] += -0.1
        elif(event.text.lower() == 's'):
            self.translate[1] += 0.1

        elif(event.text.lower() == 'q'):
            self.rotate[2] += -1
        elif(event.text.lower() == 'e'):
            self.rotate[2] += 1

        elif(event.text.lower() == 'z'):
            self.translate[2] += -0.1
        elif(event.text.lower() == 'x'):
            self.translate[2] += 0.1
Exemplo n.º 28
0
    def __init__(self, text, canvas, position=1, color=(0.1, 0.0, 0.7)):
        '''
        Give this the 
        - text to be written
        - main app.canvas
        - position (1-9, or which button position this should occupy)
        '''

        # State Controller
        State.register_button(position, text)

        self.position = position
        self.canvas = canvas
        self.projection = np.eye(4)
        self.view = np.eye(4)
        self.model = np.eye(4)
        height, width = 5.0, 15.0  # Meters

        orientation_vector = (1, 1, 0)
        unit_orientation_angle = np.array(orientation_vector) / np.linalg.norm(
            orientation_vector)

        scale_factor = 0.2
        lowest_button = -5.2
        midset = 0.2

        scale(self.model, scale_factor)
        yrotate(self.model, -60)
        # rotate(self.model, 30, *unit_orientation_angle)
        offset = (position * ((height + midset) * scale_factor))
        translate(self.model, -7.4, lowest_button + offset, -10)

        pixel_to_length = 10
        self.size = map(lambda o: pixel_to_length * o, [width, height])

        # Add texture coordinates
        # Rectangle of height height
        self.vertices = np.array([
            [-width / 2, -height / 2, 0],
            [width / 2, -height / 2, 0],
            [width / 2, height / 2, 0],
            [-width / 2, height / 2, 0],
        ],
                                 dtype=np.float32)

        self.tex_coords = np.array([
            [0, 0],
            [1, 0],
            [1, 1],
            [0, 1],
        ],
                                   dtype=np.float32)

        self.indices = IndexBuffer([
            0,
            1,
            2,
            2,
            3,
            0,
        ])

        self.program = Program(self.button_vertex_shader,
                               self.button_fragment_shader)

        self.program['vertex_position'] = self.vertices
        self.program['default_texcoord'] = self.tex_coords
        self.program['view'] = self.view
        self.program['model'] = self.model
        self.program['projection'] = self.projection
        self.program['background_color'] = color

        self.program['highlighted'] = 0

        # self.texture = Texture2D(shape=(1000, 1000) + (3,))
        # self.text_buffer = FrameBuffer(self.texture, RenderBuffer((1000, 1000)))
        self.texture = Texture2D(shape=(500, 1500) + (3, ))
        self.text_buffer = FrameBuffer(self.texture, RenderBuffer((500, 1500)))

        self.program['texture'] = self.texture
        self.text = text
        self.make_text(self.text)

        self.first = True
Exemplo n.º 29
0
class Canvas(app.Canvas):

    def __init__(self):
        app.Canvas.__init__(self, title='Framebuffer post-processing',
                            keys='interactive', size=(512, 512))

    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------
        vertices, indices, _ = create_cube()
        vertices = VertexBuffer(vertices)
        self.indices = IndexBuffer(indices)

        # Build program
        # --------------------------------------
        view = translate((0,0,-7))
        self.phi, self.theta = np.radians(60), np.radians(20)
        model = rotate(self.theta, (0, 0, 1)) * rotate(self.phi, (0, 1, 0))


        self.cube = Program(cube_vertex, cube_fragment)
        self.cube.bind(vertices)
        self.cube["texture"] = checkerboard()
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view

        depth = DepthBuffer((512, 512))
        color = Texture2D(shape=(512, 512, 3), dtype=np.dtype(np.float32))
        self.framebuffer = FrameBuffer(color=color, depth=depth)

        self.quad = Program(quad_vertex, quad_fragment, count=4)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]
        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]
        self.quad['texture'] = color
        self.quad["texture"].interpolation = 'linear'

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self._set_projection(self.size)

    def on_draw(self, event):
        self.framebuffer.activate()
        set_viewport(0, 0, 512, 512)
        clear(color=True, depth=True)
        set_state(depth_test=True)
        self.cube.draw('triangles', self.indices)
        self.framebuffer.deactivate()
        set_viewport(0, 0, *self.size)
        clear(color=True)
        set_state(depth_test=False)
        self.quad.draw('triangle_strip')

    def on_resize(self, event):
        self._set_projection(event.size)
    
    def _set_projection(self, size):
        width, height = size
        set_viewport(0, 0, width, height)
        projection = perspective(30.0, width / float(height), 2.0, 10.0)
        self.cube['projection'] = projection

    def on_timer(self, event):
        self.theta += .02
        self.phi += .02
        model = rotate(self.theta, (0, 0, 1)) * rotate(self.phi, (0, 1, 0))
        self.cube['model'] = model
        self.update()
Exemplo n.º 30
0
def test_framebuffer():

    # Test init with no args
    F = FrameBuffer()
    glir_cmds = F._glir.clear()
    assert len(glir_cmds) == 1
    glir_cmds[0][0] == 'CREATE'

    # Activate / deactivate
    F.activate()
    glir_cmd = F._glir.clear()[-1]
    assert glir_cmd[0] == 'FRAMEBUFFER'
    assert glir_cmd[2] is True
    #
    F.deactivate()
    glir_cmd = F._glir.clear()[-1]
    assert glir_cmd[0] == 'FRAMEBUFFER'
    assert glir_cmd[2] is False
    #
    with F:
        pass
    glir_cmds = F._glir.clear()
    assert len(glir_cmds) == 2
    assert glir_cmds[0][0] == 'FRAMEBUFFER'
    assert glir_cmds[1][0] == 'FRAMEBUFFER'
    assert glir_cmds[0][2] is True and glir_cmds[1][2] is False

    # Init with args
    R = RenderBuffer((3, 3))
    F = FrameBuffer(R)
    assert F.color_buffer is R
    #
    R2 = RenderBuffer((3, 3))
    F.color_buffer = R2
    assert F.color_buffer is R2

    # Wrong buffers
    F = FrameBuffer()
    assert_raises(TypeError, FrameBuffer.color_buffer.fset, F, 'FOO')
    assert_raises(TypeError, FrameBuffer.color_buffer.fset, F, [])
    assert_raises(TypeError, FrameBuffer.depth_buffer.fset, F, 'FOO')
    assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, F, 'FOO')
    color_buffer = RenderBuffer((9, 9), 'color')
    assert_raises(ValueError, FrameBuffer.depth_buffer.fset, F, color_buffer)
    # But None is allowed!
    F.color_buffer = None

    # Shape
    R1 = RenderBuffer((3, 3))
    R2 = RenderBuffer((3, 3))
    R3 = RenderBuffer((3, 3))
    F = FrameBuffer(R1, R2, R3)
    assert F.shape == R1.shape
    assert R1.format == 'color'
    assert R2.format == 'depth'
    assert R3.format == 'stencil'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert F.shape == R1.shape
    assert F.shape == R2.shape
    assert F.shape == R3.shape
    assert R1.format == 'color'
    assert R2.format == 'depth'
    assert R3.format == 'stencil'
    # Shape from any buffer
    F.color_buffer = None
    assert F.shape == (10, 10)
    F.depth_buffer = None
    assert F.shape == (10, 10)
    F.stencil_buffer = None
    assert_raises(RuntimeError, FrameBuffer.shape.fget, F)

    # Also with Texture luminance
    T = gloo.Texture2D((20, 30))
    R = RenderBuffer(T.shape)
    assert T.format == 'luminance'
    F = FrameBuffer(T, R)
    assert F.shape == T.shape[:2]
    assert F.shape == R.shape
    assert T.format == 'luminance'
    assert R.format == 'depth'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert T.shape == (10, 10, 1)
    assert F.shape == R.shape
    assert T.format == 'luminance'
    assert R.format == 'depth'

    # Also with Texture RGB
    T = gloo.Texture2D((20, 30, 3))
    R = RenderBuffer(T.shape)
    assert T.format == 'rgb'
    F = FrameBuffer(T, R)
    assert F.shape == T.shape[:2]
    assert F.shape == R.shape
    assert T.format == 'rgb'
    assert R.format == 'depth'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert T.shape == (10, 10, 3)
    assert F.shape == R.shape
    assert T.format == 'rgb'
    assert R.format == 'depth'

    # Wrong shape in resize
    assert_raises(ValueError, F.resize, (9, 9, 1))
    assert_raises(ValueError, F.resize, (9, ))
    assert_raises(ValueError, F.resize, 'FOO')
Exemplo n.º 31
0
    def __init__(self):
        self.projection = np.eye(4)
        self.view = np.eye(4)
        self.model = np.eye(4)

        height, width = 3.0, 6.0
        scale_factor = 0.2
        x_offset = -8
        y_offset = 2
        pixel_to_length = 10
        color = (1.0, 1.0, 1.0)

        scale(self.model, scale_factor)
        yrotate(self.model, -60)
        translate(self.model, x_offset, y_offset, -10)
        size = (int(height * 100), int(width * 100))

        self.vertices = np.array([
            [-width / 2, -height / 2, 0],
            [width / 2, -height / 2, 0],
            [width / 2, height / 2, 0],
            [-width / 2, height / 2, 0],
        ],
                                 dtype=np.float32)

        self.tex_coords = np.array([
            [0, 0],
            [1, 0],
            [1, 1],
            [0, 1],
        ],
                                   dtype=np.float32)

        self.indices = IndexBuffer([
            0,
            1,
            2,
            2,
            3,
            0,
        ])

        self.program = Program(self.battery_vertex_shader,
                               self.battery_fragment_shader)

        self.texture = Texture2D(shape=size + (3, ))
        self.text_buffer = FrameBuffer(self.texture, RenderBuffer(size))

        images = []
        images.append(
            Image.open(
                os.path.join(Paths.get_path_to_visar(), 'visar', 'images',
                             'battery', 'battery_low_color.png')))
        images.append(
            Image.open(
                os.path.join(Paths.get_path_to_visar(), 'visar', 'images',
                             'battery', 'battery_used_color.png')))
        images.append(
            Image.open(
                os.path.join(Paths.get_path_to_visar(), 'visar', 'images',
                             'battery', 'battery_full_color.png')))

        self.level_texture = {}  # texture for each level

        for x in range(0, len(images)):
            default_image = images[x]
            default_image = default_image.rotate(-90)
            default_image = default_image.resize(size)
            default_image = default_image.transpose(Image.FLIP_TOP_BOTTOM)
            default_image_array = np.asarray(default_image)
            self.level_texture[x + 1] = default_image_array

        #default_image_array = imageio.imread(os.path.join(Paths.get_path_to_visar(), 'visar', 'images', 'battery', 'battery_full_color.png'))

        # self.default_tex = Texture2D(data=default_image_array)
        # self.default_tex = Texture2D(shape=size + (3,))
        # self.default_tex.set_data(self.level_texture[3])

        self.program['vertex_position'] = self.vertices
        self.program['default_texcoord'] = self.tex_coords
        self.program['view'] = self.view
        self.program['model'] = self.model
        self.program['projection'] = self.projection
        self.program['hide'] = 0

        # self.tex_program = Program(self.tex_vert_shader, self.battery_fragment_shader)

        # self.tex_program['vertex_position']  = self.vertices
        # self.tex_program['default_texcoord'] = self.tex_coords
        # self.tex_program['hide']             = 0
        # self.tex_program['texture']          = self.default_tex

        self.flag = True  # flag to update the texture

        self.level = 3  # level of the battery 1 - 3
        full_middle_split = 75  # split between levels 2 and 3
        middle_low_split = 25  # split between levels 1 and 2
        fault_tolerance = 5
        self.full_lower = full_middle_split - fault_tolerance  # lower limit for going from 3 to 2
        self.middle_upper = full_middle_split + fault_tolerance  # upper limit for going from 2 to 3
        self.middle_lower = middle_low_split - fault_tolerance  # lower limit for going from 2 to 1
        self.low_upper = middle_low_split + fault_tolerance  # upper limit for going from 1 to 2
Exemplo n.º 32
0
def test_framebuffer():
    
    # Test init with no args
    gloo.get_a_context().glir.clear()
    F = FrameBuffer()
    glir_cmds = F._context.glir.clear()
    assert len(glir_cmds) == 1
    glir_cmds[0][0] == 'CREATE'
    
    # Activate / deactivate
    F.activate()
    glir_cmd = F._context.glir.clear()[-1]
    assert glir_cmd[0] == 'FRAMEBUFFER'
    assert glir_cmd[2] is True
    #
    F.deactivate()
    glir_cmd = F._context.glir.clear()[-1]
    assert glir_cmd[0] == 'FRAMEBUFFER'
    assert glir_cmd[2] is False
    #
    with F:
        pass
    glir_cmds = F._context.glir.clear()
    assert len(glir_cmds) == 2
    assert glir_cmds[0][0] == 'FRAMEBUFFER'
    assert glir_cmds[1][0] == 'FRAMEBUFFER'
    assert glir_cmds[0][2] is True and glir_cmds[1][2] is False
    
    # Init with args
    R = RenderBuffer((3, 3))
    F = FrameBuffer(R)
    assert F.color_buffer is R
    #
    R2 = RenderBuffer((3, 3))
    F.color_buffer = R2
    assert F.color_buffer is R2
    
    # Wrong buffers
    F = FrameBuffer()
    assert_raises(TypeError, FrameBuffer.color_buffer.fset, F, 'FOO')
    assert_raises(TypeError, FrameBuffer.color_buffer.fset, F, [])
    assert_raises(TypeError, FrameBuffer.depth_buffer.fset, F, 'FOO')
    assert_raises(TypeError, FrameBuffer.stencil_buffer.fset, F, 'FOO')
    color_buffer = RenderBuffer((9, 9), 'color')
    assert_raises(ValueError, FrameBuffer.depth_buffer.fset, F, color_buffer)
    # But None is allowed!
    F.color_buffer = None
    
    # Shape
    R1 = RenderBuffer((3, 3))
    R2 = RenderBuffer((3, 3))
    R3 = RenderBuffer((3, 3))
    F = FrameBuffer(R1, R2, R3)
    assert F.shape == R1.shape 
    assert R1.format == 'color'
    assert R2.format == 'depth'
    assert R3.format == 'stencil'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert F.shape == R1.shape 
    assert F.shape == R2.shape 
    assert F.shape == R3.shape 
    assert R1.format == 'color'
    assert R2.format == 'depth'
    assert R3.format == 'stencil'
    # Shape from any buffer
    F.color_buffer = None
    assert F.shape == (10, 10)
    F.depth_buffer = None
    assert F.shape == (10, 10)
    F.stencil_buffer = None
    assert_raises(RuntimeError, FrameBuffer.shape.fget, F)
    
    # Also with Texture luminance
    T = gloo.Texture2D((20, 30))
    R = RenderBuffer(T.shape)
    assert T.format == 'luminance'
    F = FrameBuffer(T, R)
    assert F.shape == T.shape[:2]
    assert F.shape == R.shape
    assert T.format == 'luminance'
    assert R.format == 'depth'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert T.shape == (10, 10, 1)
    assert F.shape == R.shape 
    assert T.format == 'luminance'
    assert R.format == 'depth'
    
    # Also with Texture RGB
    T = gloo.Texture2D((20, 30, 3))
    R = RenderBuffer(T.shape)
    assert T.format == 'rgb'
    F = FrameBuffer(T, R)
    assert F.shape == T.shape[:2]
    assert F.shape == R.shape
    assert T.format == 'rgb'
    assert R.format == 'depth'
    # Resize
    F.resize((10, 10))
    assert F.shape == (10, 10)
    assert T.shape == (10, 10, 3)
    assert F.shape == R.shape 
    assert T.format == 'rgb'
    assert R.format == 'depth'
    
    # Wrong shape in resize
    assert_raises(ValueError, F. resize, (9, 9, 1))
    assert_raises(ValueError, F. resize, (9,))
    assert_raises(ValueError, F. resize, 'FOO')
Exemplo n.º 33
0
class Renderer3D:
    def __init__(self):
        self.default_prog = None

        self.fbuffer = None
        self.fbuffer_tex_front = None
        self.fbuffer_tex_back = None

        self.vertex_buffer = None
        self.index_buffer = None

        ## Renderer Globals: USEFUL CONSTANTS
        self.COLOR_WHITE = (1, 1, 1, 1)
        self.COLOR_BLACK = (0, 0, 0, 1)
        self.COLOR_DEFAULT_BG = (0.8, 0.8, 0.8, 1.0)

        ## Renderer Globals: STYLE/MATERIAL PROPERTIES
        ##
        self.background_color = self.COLOR_DEFAULT_BG

        self.fill_color = self.COLOR_WHITE
        self.fill_enabled = True

        self.stroke_color = self.COLOR_BLACK
        self.stroke_enabled = True

        self.tint_color = self.COLOR_BLACK
        self.tint_enabled = False

        ## Renderer Globals: Curves
        self.stroke_weight = 1
        self.stroke_cap = 2
        self.stroke_join = 0

        ## Renderer Globals
        ## VIEW MATRICES, ETC
        ##
        self.viewport = None
        self.texture_viewport = None
        self.transform_matrix = np.identity(4)
        self.projection_matrix = np.identity(4)
        self.lookat_matrix = np.identity(4)

        ## Renderer Globals: RENDERING
        self.draw_queue = []

    def initialize_renderer(self):
        self.fbuffer = FrameBuffer()

        vertices = np.array(
            [[-1.0, -1.0], [+1.0, -1.0], [-1.0, +1.0], [+1.0, +1.0]],
            np.float32)
        texcoords = np.array([[0.0, 0.0], [1.0, 0.0], [0.0, 1.0], [1.0, 1.0]],
                             dtype=np.float32)

        self.fbuf_vertices = VertexBuffer(data=vertices)
        self.fbuf_texcoords = VertexBuffer(data=texcoords)

        self.fbuffer_prog = Program(src_fbuffer.vert, src_fbuffer.frag)
        self.fbuffer_prog['texcoord'] = self.fbuf_texcoords
        self.fbuffer_prog['position'] = self.fbuf_vertices

        self.vertex_buffer = VertexBuffer()
        self.index_buffer = IndexBuffer()

        self.default_prog = Program(src_default.vert, src_default.frag)

        self.reset_view()

    def reset_view(self):
        self.viewport = (
            0,
            0,
            int(builtins.width * builtins.pixel_x_density),
            int(builtins.height * builtins.pixel_y_density),
        )
        self.texture_viewport = (
            0,
            0,
            builtins.width,
            builtins.height,
        )

        gloo.set_viewport(*self.viewport)

        cz = (builtins.height / 2) / math.tan(math.radians(30))
        self.projection_matrix = matrix.perspective_matrix(
            math.radians(60), builtins.width / builtins.height, 0.1 * cz,
            10 * cz)

        self.transform_matrix = np.identity(4)

        self.default_prog['projection'] = self.projection_matrix.T.flatten()
        self.default_prog['perspective_matrix'] = self.lookat_matrix.T.flatten(
        )

        self.fbuffer_tex_front = Texture2D(
            (builtins.height, builtins.width, 3))
        self.fbuffer_tex_back = Texture2D((builtins.height, builtins.width, 3))

        for buf in [self.fbuffer_tex_front, self.fbuffer_tex_back]:
            self.fbuffer.color_buffer = buf
            with self.fbuffer:
                self.clear()

        self.fbuffer.depth_buffer = gloo.RenderBuffer(
            (builtins.height, builtins.width))

    def clear(self, color=True, depth=True):
        """Clear the renderer background."""
        gloo.set_state(clear_color=self.background_color)
        gloo.clear(color=color, depth=depth)

    def _comm_toggles(self, state=True):
        gloo.set_state(blend=state)
        gloo.set_state(depth_test=state)

        if state:
            gloo.set_state(blend_func=('src_alpha', 'one_minus_src_alpha'))
            gloo.set_state(depth_func='lequal')

    @contextmanager
    def draw_loop(self):
        """The main draw loop context manager.
		"""

        self.transform_matrix = np.identity(4)

        self.default_prog['projection'] = self.projection_matrix.T.flatten()
        self.default_prog['perspective_matrix'] = self.lookat_matrix.T.flatten(
        )

        self.fbuffer.color_buffer = self.fbuffer_tex_back

        with self.fbuffer:
            gloo.set_viewport(*self.texture_viewport)
            self._comm_toggles()
            self.fbuffer_prog['texture'] = self.fbuffer_tex_front
            self.fbuffer_prog.draw('triangle_strip')

            yield

            self.flush_geometry()
            self.transform_matrix = np.identity(4)

        gloo.set_viewport(*self.viewport)
        self._comm_toggles(False)
        self.clear()
        self.fbuffer_prog['texture'] = self.fbuffer_tex_back
        self.fbuffer_prog.draw('triangle_strip')

        self.fbuffer_tex_front, self.fbuffer_tex_back = self.fbuffer_tex_back, self.fbuffer_tex_front

    def _transform_vertices(self, vertices, local_matrix, global_matrix):
        return np.dot(np.dot(vertices, local_matrix.T), global_matrix.T)[:, :3]

    def render(self, shape):
        if isinstance(shape, Geometry):
            n = len(shape.vertices)
            tverts = self._transform_vertices(
                np.hstack([shape.vertices, np.ones((n, 1))]), shape.matrix,
                self.transform_matrix)

            edges = shape.edges
            faces = shape.faces

            self.add_to_draw_queue('poly', tverts, edges, faces,
                                   self.fill_color, self.stroke_color)

        elif isinstance(shape, PShape):
            vertices = shape._draw_vertices
            n, _ = vertices.shape
            tverts = self._transform_vertices(
                np.hstack([vertices,
                           np.zeros((n, 1)),
                           np.ones((n, 1))]), shape._matrix,
                self.transform_matrix)

            fill = shape.fill.normalized if shape.fill else None
            stroke = shape.stroke.normalized if shape.stroke else None
            edges = shape._draw_edges
            faces = shape._draw_faces

            if edges is None:
                print(vertices)
                print("whale")
                exit()

            if 'open' in shape.attribs:
                overtices = shape._draw_outline_vertices
                no, _ = overtices.shape
                toverts = self._transform_vertices(
                    np.hstack([overtices,
                               np.zeros((no, 1)),
                               np.ones((no, 1))]), shape._matrix,
                    self.transform_matrix)

                self.add_to_draw_queue('poly', tverts, edges, faces, fill,
                                       None)
                self.add_to_draw_queue('path', toverts, edges[:-1], None, None,
                                       stroke)
            else:
                self.add_to_draw_queue(shape.kind, tverts, edges, faces, fill,
                                       stroke)

    def add_to_draw_queue(self,
                          stype,
                          vertices,
                          edges,
                          faces,
                          fill=None,
                          stroke=None):
        """Add the given vertex data to the draw queue.

		:param stype: type of shape to be added. Should be one of {'poly',
			'path', 'point'}
		:type stype: str

		:param vertices: (N, 3) array containing the vertices to be drawn.
		:type vertices: np.ndarray

		:param edges: (N, 2) array containing edges as tuples of indices
			into the vertex array. This can be None when not appropriate
			(eg. for points)
		:type edges: None | np.ndarray

		:param faces: (N, 3) array containing faces as tuples of indices
			into the vertex array. For 'point' and 'path' shapes, this can
			be None
		:type faces: np.ndarray

		:param fill: Fill color of the shape as a normalized RGBA tuple.
			When set to `None` the shape doesn't get a fill (default: None)
		:type fill: None | tuple

		:param stroke: Stroke color of the shape as a normalized RGBA
			tuple. When set to `None` the shape doesn't get stroke
			(default: None)
		:type stroke: None | tuple

		"""

        fill_shape = self.fill_enabled and not (fill is None)
        stroke_shape = self.stroke_enabled and not (stroke is None)

        if fill_shape and stype not in ['point', 'path']:
            idx = np.array(faces, dtype=np.uint32).ravel()
            self.draw_queue.append(["triangles", (vertices, idx, fill)])

        if stroke_shape:
            if stype == 'point':
                idx = np.arange(0, len(vertices), dtype=np.uint32)
                self.draw_queue.append(["points", (vertices, idx, stroke)])
            else:
                idx = np.array(edges, dtype=np.uint32).ravel()
                self.draw_queue.append(["lines", (vertices, idx, stroke)])

    def flush_geometry(self):
        """Flush all the shape geometry from the draw queue to the GPU.
		"""
        current_queue = []
        for index, shape in enumerate(self.draw_queue):
            current_shape, current_obj = self.draw_queue[index][
                0], self.draw_queue[index][1]
            # If current_shape is lines, bring it to the front by epsilon
            # to resolve z-fighting
            if current_shape == 'lines':
                # line_transform is used whenever we render lines to break ties in depth
                # We transform the points to camera space, move them by Z_EPSILON, and them move them back to world space
                line_transform = inv(self.lookat_matrix).dot(
                    translation_matrix(0, 0,
                                       Z_EPSILON).dot(self.lookat_matrix))
                vertices = current_obj[0]
                current_obj = (np.hstack(
                    [vertices, np.ones(
                        (vertices.shape[0], 1))]).dot(line_transform.T)[:, :3],
                               current_obj[1], current_obj[2])
            current_queue.append(current_obj)

            if index < len(self.draw_queue) - 1:
                if self.draw_queue[index][0] == self.draw_queue[index + 1][0]:
                    continue

            self.render_default(current_shape, current_queue)
            current_queue = []

        self.draw_queue = []

    def render_default(self, draw_type, draw_queue):
        # 1. Get the maximum number of vertices persent in the shapes
        # in the draw queue.
        #
        if len(draw_queue) == 0:
            return

        num_vertices = 0
        for vertices, _, _ in draw_queue:
            num_vertices = num_vertices + len(vertices)

        # 2. Create empty buffers based on the number of vertices.
        #
        data = np.zeros(num_vertices,
                        dtype=[('position', np.float32, 3),
                               ('color', np.float32, 4)])

        # 3. Loop through all the shapes in the geometry queue adding
        # it's information to the buffer.
        #
        sidx = 0
        draw_indices = []
        for vertices, idx, color in draw_queue:
            num_shape_verts = len(vertices)

            data['position'][sidx:(sidx +
                                   num_shape_verts), ] = np.array(vertices)

            color_array = np.array([color] * num_shape_verts)
            data['color'][sidx:sidx + num_shape_verts, :] = color_array

            draw_indices.append(sidx + idx)

            sidx += num_shape_verts

        self.vertex_buffer.set_data(data)
        self.index_buffer.set_data(np.hstack(draw_indices))

        # 4. Bind the buffer to the shader.
        #
        self.default_prog.bind(self.vertex_buffer)

        # 5. Draw the shape using the proper shape type and get rid of
        # the buffers.
        #
        self.default_prog.draw(draw_type, indices=self.index_buffer)

    def cleanup(self):
        """Run the clean-up routine for the renderer.

		This method is called when all drawing has been completed and the
		program is about to exit.

		"""
        self.default_prog.delete()
        self.fbuffer_prog.delete()
        self.fbuffer.delete()
Exemplo n.º 34
0
    def on_initialize(self, event):
        # Build cube data
        # --------------------------------------

        texcoord = [(0, 0), (0, 1), (1, 0), (1, 1)]
        vertices = [(-1, -1, 0), (-1, +1, 0), (+1, -1, 0), (+1, +1, 0)]

        vertices = VertexBuffer(vertices)

        #self.listener.waitForTransform("/robot", "/wrist_joint", rospy.Time(), rospy.Duration(4))

        """while not rospy.is_shutdown():
            try:
                now = rospy.Time.now()
                self.listener.waitForTransform("/wrist_joint", "/robot", rospy.Time(), rospy.Duration(4))
                (trans,rot) = listener.lookupTransform("/wrist_joint", "/robot", rospy.Time(), rospy.Duration(4))
        """

        #pos, rot = self.listener.lookupTransform("/wrist_joint", "/robot", rospy.Time(0))

        #print list(pos)
        
        camera_pitch = 0.0 # Degrees
        self.rotate = [camera_pitch, 0, 0]
        #self.translate = list(pos)
        self.translate = [0, 0, -5]

        # Build program
        # --------------------------------------
        view = np.eye(4, dtype=np.float32)
        model = np.eye(4, dtype=np.float32)
        scale(model, 10, 10, 10)
        self.phi = 0

        self.cube = Program(cube_vertex, cube_fragment)
        self.cube['position'] = vertices
        # 4640 x 2256
        imtex = cv2.imread(os.path.join(img_path, 'rubixFront.jpg')) 
        self.cube['texcoord'] = texcoord
        self.cube["texture"] = np.uint8(np.clip(imtex + np.random.randint(-60, 20, size=imtex.shape), 0, 255)) + 5
        self.cube["texture"].interpolation = 'linear'
        self.cube['model'] = model
        self.cube['view'] = view


        color = Texture2D((640, 640, 3), interpolation='linear')
        self.framebuffer = FrameBuffer(color, RenderBuffer((640, 640)))

        self.quad = Program(quad_vertex, quad_fragment)
        self.quad['texcoord'] = [(0, 0), (0, 1), (1, 0), (1, 1)]

        self.quad['position'] = [(-1, -1), (-1, +1), (+1, -1), (+1, +1)]

        self.quad['texture'] = color

        self.objects = [self.cube]

        # OpenGL and Timer initalization
        # --------------------------------------
        set_state(clear_color=(.3, .3, .35, 1), depth_test=True)
        self.timer = app.Timer('auto', connect=self.on_timer, start=True)
        self.pub_timer = app.Timer(0.1, connect=self.send_ros_img, start=True)
        self._set_projection(self.size)