Exemplo n.º 1
0
    def draw_arrow(
            self,
            segment: Segment,
            length: float,
            height: float
    ):
        """
        Draws a segment with an arrow in it's end.
        The arrow's dimensions are given by `length` and `height`.

        :param segment: `Segment`
        :param length: `Int` length of the arrow head
        :param height: `Int` height of the arrow head
        """
        director = segment.direction_vector
        v_l = director.opposite().with_length(length)
        v_h1 = director.perpendicular().with_length(height / 2.0)
        v_h2 = v_h1.opposite()

        self.draw_segment(segment)
        self.draw_segment(
            Segment(
                segment.end,
                segment.end.displaced(v_l + v_h1)
            )
        )
        self.draw_segment(
            Segment(
                segment.end,
                segment.end.displaced(v_l + v_h2)
            )
        )
Exemplo n.º 2
0
    def geometry(self):
        """
        Line segment representing the geometry of the bar.

        :return: `Segment`
        """
        return Segment(self.start_node.position, self.end_node.position)
Exemplo n.º 3
0
def vector_to_svg(
        position: Point,
        vector: Vector,
        scale: float,
        color: str,
        config
):
    """
    Creates an SVG representation of the given vector using an
    arrow and a label aligned with the arrow.

    :param position: origin of the vector
    :param vector: `Vector`
    :param scale: scale to use in the drawing
    :param color: color to use for the arrow and label
    :param config: configuration dictionary
    :return: SVG arrow and label
    """
    segment = Segment(
        position.displaced(vector, -scale),
        position
    )
    caption_origin = segment.start.displaced(
        segment.normal_versor,
        __CAPTION_DISP
    )

    def svg_arrow():
        width = config['sizes']['stroke']
        arrow_size = config['sizes']['arrow']

        return svg.arrow(
            segment,
            arrow_size,
            arrow_size,
            [
                attributes.stroke_color(color),
                attributes.stroke_width(width),
                attributes.fill_color('none')
            ]
        )

    def svg_caption():
        return caption_to_svg(
            vector.to_formatted_str(__DECIMAL_POS),
            caption_origin,
            vector.angle_to(__I_VERSOR),
            color,
            config
        )

    return svg.group([
        svg_arrow(),
        svg_caption()
    ])
Exemplo n.º 4
0
    def final_geometry(self):
        """
        The bar's geometry, described by a line segment, after the
        computed displacements are applied.

        :return: the solution bar's geometry
        """
        return Segment(
            self.start_node.displaced_pos,
            self.end_node.displaced_pos
        )
Exemplo n.º 5
0
    def final_geometry_scaling_displacement(self, scale: float):
        """
        Computes the geometry of the bar after the displacements
        of its nodes have been applied with a given scale factor.

        This scaled geometry can be used for drawing the solution
        diagram.

        :param scale: used to scale the displacements
        :return: the solution bar's final geometry scaled
        """
        return Segment(
            self.start_node.displaced_pos_scaled(scale),
            self.end_node.displaced_pos_scaled(scale)
        )
Exemplo n.º 6
0
def parse_segment(line):
    match = re.match(__SEGM_RE, line)
    return Segment(start=Point(float(match.group('sx')),
                               float(match.group('sy'))),
                   end=Point(float(match.group('ex')),
                             float(match.group('ey'))))
Exemplo n.º 7
0
def simulate(transform, primitives, config):
    # ---------- UI DEFINITION ---------- #
    tk = Tk()
    tk.title("Affine Transformations")
    tk.minsize(width=400, height=400)

    canvas = Canvas(tk)
    canvas.pack(fill='both', side='top', expand=True)

    def start_simulation():
        tk.update()
        main_loop(update_system, redraw, should_continue)

    button = Button(tk, text='Play', command=start_simulation)
    button.pack(anchor='center', side='bottom')

    # ---------- UPDATE, DRAW & CONTINUE ---------- #
    frames = config['frames']
    transform_seq = __make_transform_sequence(transform, frames)
    axis_length = config['axes']['length']
    x_axis = Segment(Point(0, 0), Point(axis_length, 0))
    y_axis = Segment(Point(0, 0), Point(0, axis_length))
    drawing = CanvasDrawing(canvas, transform_seq[0])

    def update_system(time_delta_s, time_s, frame):
        drawing.transform = transform_seq[frame - 1]
        tk.update()

    def redraw():
        drawing.clear_drawing()

        drawing.outline_width = config['axes']['stroke-width']
        drawing.outline_color = config['axes']['x-color']
        drawing.draw_arrow(x_axis, config['axes']['arrow-length'],
                           config['axes']['arrow-height'])

        drawing.outline_color = config['axes']['y-color']
        drawing.draw_arrow(y_axis, config['axes']['arrow-length'],
                           config['axes']['arrow-height'])

        drawing.outline_width = config['geometry']['stroke-width']
        drawing.outline_color = config['geometry']['stroke-color']

        for circle in primitives['circs']:
            drawing.draw_circle(circle)

        for rect in primitives['rects']:
            drawing.draw_rectangle(rect)

        for polygon in primitives['polys']:
            drawing.draw_polygon(polygon)

        for segment in primitives['segs']:
            drawing.draw_segment(segment)

    def should_continue(frame, time_s):
        return frame <= frames

    # ---------- MAIN LOOP ---------- #
    redraw()
    tk.mainloop()
Exemplo n.º 8
0
 def test_segment(self):
     segment = Segment(Point(2, 3), Point(4, 5))
     actual = primitives.segment(segment)
     expected = '<line x1="2" y1="3" x2="4" y2="5" />'
     self.assertEqual(expected, actual)