Esempio n. 1
0
 def test_rect_from_point_width_height (self):
     rect = Shapes.rect(Point(100,100), 300, 300)
     self.assertEqual(4, len(rect.segments))
     self.assertEqual(Point(100,100), rect.head)
     self.assertEqual(Point(400,100), rect.segments[0]['p2'])
     self.assertEqual(Point(400,400), rect.segments[1]['p2'])
     self.assertEqual(Point(100,400), rect.segments[2]['p2'])
Esempio n. 2
0
 def with_frame(self, color, width: int):
     Shapes.rect(Point(0, 0), self.surface.width(), width)\
         .fill(color).reg(self)
     Shapes.rect(Point(self.surface.width() - width, 0), width, self.surface.height())\
         .fill(color).reg(self)
     Shapes.rect(Point(0, self.surface.height() - width), self.surface.width(), width)\
         .fill(color).reg(self)
     Shapes.rect(Point(0, 0), width,
                 self.surface.height()).fill(color).reg(self)
     return self
Esempio n. 3
0
def curve(p0: Point, p1: Point, p2: Point, p3: Point) -> Shape:
    s = Shape.Shape()
    p0 = p0 if type(p0) == Point else Point(p0[0], p0[1])
    c1 = p1 if type(p1) == Point else Point(p1[0], p1[1])
    c2 = p2 if type(p2) == Point else Point(p2[0], p2[1])
    p2 = p3 if type(p3) == Point else Point(p3[0], p3[1])
    s.head = p0
    s.add(c2, c1, p2)
    s.closed = False
    return s
Esempio n. 4
0
 def test_interpolate(self):
     self.assertEqual((10, 10), Point.interpolate(Point(0, 0),
                                                  Point(20, 20)))
     self.assertEqual((-5, -5),
                      Point.interpolate(Point(0, 0), Point(-10, -10)))
     self.assertEqual((10, 30),
                      Point.interpolate(Point(10, 10), Point(10, 50)))
Esempio n. 5
0
 def __init__(self,
              pos: Point = Point(0, 0),
              speed: Point = Point(0, 0),
              ttl: float = -1):
     self.position = pos
     self.speed = speed
     self.initial_speed = speed.cp()
     self.acceleration = Point(0, 0)
     self.ttl = ttl
     self.alive = True
     self.trace = [self.position]
Esempio n. 6
0
 def test_subd(self):
     rect = Shapes.rect(Point(100, 100), 300, 300)
     rect.subd(0.5)
     self.assertEqual(8, len(rect.segments))
     self.assertEqual(Point(100, 100), rect.head)
     self.assertEqual(Point(250, 100), rect.segments[0]['p2'])
     self.assertEqual(Point(400, 100), rect.segments[1]['p2'])
     self.assertEqual(Point(400, 250), rect.segments[2]['p2'])
     self.assertEqual(Point(400, 400), rect.segments[3]['p2'])
     self.assertEqual(Point(250, 400), rect.segments[4]['p2'])
     self.assertEqual(Point(100, 400), rect.segments[5]['p2'])
     self.assertEqual(Point(100, 250), rect.segments[6]['p2'])
     self.assertEqual(Point(100, 100), rect.segments[7]['p2'])
Esempio n. 7
0
 def adjust(self):
     for i in range(1, len(self.segments)):
         s0 = self.segments[i - 1]
         d = Point.distance(s0['c2'], s0['p2'])
         nc1 = Utils.proj(s0['c2'], s0['p2'], 2 * d)
         self.segments[i]['c1'] = nc1
     return self
Esempio n. 8
0
 def __init__(self,
              pos: Point = Point(0, 0),
              mass: float = 100.0,
              decay: float = 0.0):
     self.pos = pos
     self.mass = mass
     self.decay = decay
Esempio n. 9
0
 def grid(self, xrows, yrows, width, height) -> plist:
     points = plist([], self.seed)
     xspan = width / xrows
     yspan = height / yrows
     for ypoints in range(1, yrows):
         for xpoints in range(1, xrows):
             points.append(Point(xpoints * xspan, ypoints * yspan))
     return points
Esempio n. 10
0
 def submit(self, fs: list[Field]):
     total_acc = Point(0, 0)
     for field in fs:
         v = field.pos - self.position
         mag = (v.x * v.x) + (v.y * v.y)
         force = field.mass / mag
         total_acc = total_acc + v * force
     self.acceleration = total_acc
     return self
Esempio n. 11
0
 def contour_points(self, points: list[Point], width: float):
     outer = []
     inner = []
     outer.append(Point.off(points[0], points[1], width))
     inner.append(Point.off(points[0], points[1], -width))
     pairs = list(zip(points[::1], points[1::1]))
     for i in range(0, len(pairs)):
         pair = pairs[i]
         p1 = Point.off(pair[1], pair[0], -width)
         p2 = Point.off(pair[1], pair[0], width)
         #if i < len(pairs)-1:
         #    nxt = pairs[i+1][0]
         #    p1 = Point.rotate(p1, pair[1], Point.angle(pair[1], nxt))
         #    p2 = Point.rotate(p2, pair[1], Point.angle(pair[1], nxt))
         outer.append(p1)
         inner.append(p2)
     self.left = outer
     self.right = inner
     return outer, inner
Esempio n. 12
0
def catmull_rom(ps: plist, res):
    """Computes Catmull-Rom Spline for given support points and resolution.

    Args:
        p_x: array of x-coords
        p_y: array of y-coords
        res: resolution of a segment (including the start point, but not the
            endpoint of the segment)
    """
    # create arrays for spline points
    p_x = [p.x for p in ps]
    p_y = [p.y for p in ps]
    x_intpol = np.empty(res * (len(p_x) - 1) + 1)
    y_intpol = np.empty(res * (len(p_x) - 1) + 1)

    # set the last x- and y-coord, the others will be set in the loop
    x_intpol[-1] = p_x[-1]
    y_intpol[-1] = p_y[-1]

    # loop over segments (we have n-1 segments for n points)
    for i in range(len(p_x) - 1):
        # set x-coords
        x_intpol[i * res:(i + 1) * res] = np.linspace(p_x[i],
                                                      p_x[i + 1],
                                                      res,
                                                      endpoint=False)
        if i == 0:
            # need to estimate an additional support point before the first
            y_intpol[:res] = np.array([
                catmull_rom_one_point(
                    x,
                    p_y[0] - (p_y[1] - p_y[0]),  # estimated start point,
                    p_y[0],
                    p_y[1],
                    p_y[2]) for x in np.linspace(0., 1., res, endpoint=False)
            ])
        elif i == len(p_x) - 2:
            # need to estimate an additional support point after the last
            y_intpol[i * res:-1] = np.array([
                catmull_rom_one_point(
                    x,
                    p_y[i - 1],
                    p_y[i],
                    p_y[i + 1],
                    p_y[i + 1] + (p_y[i + 1] - p_y[i])  # estimated end point
                ) for x in np.linspace(0., 1., res, endpoint=False)
            ])
        else:
            y_intpol[i * res:(i + 1) * res] = np.array([
                catmull_rom_one_point(x, p_y[i - 1], p_y[i], p_y[i + 1],
                                      p_y[i + 2])
                for x in np.linspace(0., 1., res, endpoint=False)
            ])

    return [Point(x_intpol[i], y_intpol[i]) for i in range(0, len(x_intpol))]
Esempio n. 13
0
 def rotate(self, deg: float, origin: Point = None):
     points = [self.head]
     points.extend(
         np.concatenate([[s['c1'], s['c2'], s['p2']]
                         for s in self.segments]))
     points = list(map(lambda p: (p.x, p.y), points))
     origin = self.center() if origin is None else origin
     origin = (origin.x, origin.y)
     angle = np.deg2rad(deg)
     r = np.array([[np.cos(angle), -np.sin(angle)],
                   [np.sin(angle), np.cos(angle)]])
     o = np.atleast_2d(origin)
     p = np.atleast_2d(points)
     rotpoints = np.squeeze((r.dot(p.T - o.T) + o.T).T)
     self.head = Point(rotpoints[0][0], rotpoints[0][1])
     self.segments.clear()
     for i in range(1, len(rotpoints) - 2, 3):
         c1 = Point(rotpoints[i][0], rotpoints[i][1])
         c2 = Point(rotpoints[i + 1][0], rotpoints[i + 1][1])
         p2 = Point(rotpoints[i + 2][0], rotpoints[i + 2][1])
         self.segments.append({'c1': c1, 'c2': c2, 'p2': p2})
     return self
Esempio n. 14
0
 def linear(self, outer: list[Point], inner: list[Point]):
     shape = Shape(outer[0])
     for i in range(1, len(outer)):
         start = outer[i - 1]
         end = outer[i]
         d = Point.distance(start, end)
         shape.add(Utils.proj(start, end, d / 3),
                   Utils.proj(start, end, 2 * d / 3), end)
     last_innpoint = inner[-1]
     d = Point.distance(end, last_innpoint)
     shape.add(Utils.proj(end, last_innpoint, d / 3),
               Utils.proj(end, last_innpoint, 2 * d / 3), last_innpoint)
     inner.reverse()
     for i in range(1, len(inner)):
         start = inner[i - 1]
         end = inner[i]
         d = Point.distance(start, end)
         shape.add(Utils.proj(start, end, d / 3),
                   Utils.proj(start, end, 2 * d / 3), end)
     d = Point.distance(end, outer[0])
     shape.add(Utils.proj(end, outer[0], d / 3),
               Utils.proj(end, outer[0], 2 * d / 3), outer[0])
     return shape
Esempio n. 15
0
class Emitter:
    pos: Point = Point(0, 0)
    speed: Point = 0.0
    xsize: int = 10
    ysize: int = 10
    particle_life: float = 10
    spread: float = 1.0
    rate: float = 5.0
    rnd: numpy.random = random()

    def emit_particle(self):
        part_pos = self.pos + (self.xsize * self.rnd(),
                               self.ysize * self.rnd())
        return Particle(pos=part_pos, speed=self.speed, ttl=self.particle_life)
Esempio n. 16
0
def rect(p0: Point, *args):
    """
    rect (Point, width, height)
    rect (Point, Point, width)
    """
    assert len(args) == 2 or len(args) == 1
    param1 = args[0]
    param2 = args[1]
    if type(param1) == Point:
        assert type(param2) == int or type(param2) == float
        p1, height = args
        dist = Point.distance(p0, p1)
        angle = Point.angle(p0, p1)
        return rect(Point(p0.x, p0.y - height/2), dist, height)\
            .rotate(angle, p0)
    else:
        width, height = args
        p1 = Point (p0.x+width, p0.y)
        p2 = Point (p1.x, p1.y + height)
        p3 = Point (p0.x, p0.y + height)
        return Shape.Shape.line(p0, p1).addPoint(p2).addPoint(p3).addPoint(p0)
Esempio n. 17
0
def spline(pts: list, numpoints: float = 100) -> plist:
    ps = Spline.bspline(pts.as_tuples(), numpoints, 4)
    return plist([Point(p[0], p[1]) for p in ps])
Esempio n. 18
0
 def test_angle(self):
     a = Point.angle(Point(50, 50), Point(100, 100))
     self.assertEqual(a, 45.0)
Esempio n. 19
0
 def test_rotate(self):
     self.assertEqual((0, 100), Point.rotate(Point(100, 0), Point(0, 0),
                                             90))
     self.assertEqual((-100, 0),
                      Point.rotate(Point(100, 0), Point(0, 0), 180))
Esempio n. 20
0
def circle(p: Point, r: float) -> Shape:
    c = 0.551915024494 * r
    circle = Shape.Shape(Point(0, -r))
    circle.add(Point(-c, -r), Point(-r, -c), Point(-r, 0))
    circle.add(Point(-r, c), Point(-c, r), Point(0, r))
    circle.add(Point(c, r), Point(r, c), Point(r, 0))
    circle.add(Point(r, -c), Point(c, -r), Point(0, -r))
    return circle.translate(p)
Esempio n. 21
0
 def furthest(self, p: Point) -> Point:
     dists = [Point.distance(p, pt) for pt in self if p != pt]
     cl = max(dists)
     return self[dists.index(cl)]
Esempio n. 22
0
 def test_tang(self):
     p0 = Point(0, 0)
     p1 = Point(20, 20)
     tang = Point.tang(p0, p0, p1, p1, 0.5)
     print(tang)
Esempio n. 23
0
class Shape:
    def __init__(self, start_point: Point = None):
        self.head = start_point if start_point else None
        self.segments: list = []
        self.closed = False
        self.zindex = 0
        self.style = {}  # fill, stroke, stroke_width

    def tail(self) -> Point:
        return self.segments[-1]['p2']

    def addPoint(self, p: Point):
        last_point = self.tail()
        self.segments.append({'c1': p, 'c2': last_point, 'p2': p})
        return self

    def add(self, p0: Point, p1: Point, p2: Point):
        self.segments.append({'c1': p0, 'c2': p1, 'p2': p2})
        return self

    def close(self):
        self.closed = True
        return self

    def fill(self, fill: str, alpha=1):
        fill = resolve(fill)
        alpha = resolve(alpha)
        color: colour.Color = colour.hex2rgb(fill)
        self.style['fill'] = Color4f(color[0], color[1], color[2], alpha)
        return self

    def stroke(self, color: str, alpha=1, width=5):
        stroke_color = resolve(color)
        alpha = resolve(alpha)
        stroke_width = resolve(width)
        color: colour.Color = colour.hex2rgb(stroke_color)
        self.style['stroke'] = Color4f(color[0], color[1], color[2], alpha)
        self.style['stroke_width'] = stroke_width if stroke_width else None
        return self

    @staticmethod
    def line(p0: Point = (0, 0), p1: Point = (0, 0)):
        p0 = p0 if type(p0) == Point else Point(p0[0], p0[1])
        p1 = p1 if type(p1) == Point else Point(p1[0], p1[1])
        return Shapes.curve(p0, p0, p1, p1)

    def draw(self) -> Path:
        path = Path()
        path.moveTo(self.head)
        for seg in self.segments:
            path.cubicTo(seg['c1'], seg['c2'], seg['p2'])
        path.close() if self.closed else None
        return path

    def rotate(self, deg: float, origin: Point = None):
        points = [self.head]
        points.extend(
            np.concatenate([[s['c1'], s['c2'], s['p2']]
                            for s in self.segments]))
        points = list(map(lambda p: (p.x, p.y), points))
        origin = self.center() if origin is None else origin
        origin = (origin.x, origin.y)
        angle = np.deg2rad(deg)
        r = np.array([[np.cos(angle), -np.sin(angle)],
                      [np.sin(angle), np.cos(angle)]])
        o = np.atleast_2d(origin)
        p = np.atleast_2d(points)
        rotpoints = np.squeeze((r.dot(p.T - o.T) + o.T).T)
        self.head = Point(rotpoints[0][0], rotpoints[0][1])
        self.segments.clear()
        for i in range(1, len(rotpoints) - 2, 3):
            c1 = Point(rotpoints[i][0], rotpoints[i][1])
            c2 = Point(rotpoints[i + 1][0], rotpoints[i + 1][1])
            p2 = Point(rotpoints[i + 2][0], rotpoints[i + 2][1])
            self.segments.append({'c1': c1, 'c2': c2, 'p2': p2})
        return self

    def center(self) -> Point:
        points = [self.head] + [s['p2'] for s in self.segments]
        x = np.average([p.x for p in points])
        y = np.average([p.y for p in points])
        return Point(x, y)

    def translate(self, p: Point):
        self.head = self.head + p
        for seg in self.segments:
            seg['c1'] = seg['c1'] + p
            seg['c2'] = seg['c2'] + p
            seg['p2'] = seg['p2'] + p
        return self

    def cp(self):
        new_shape = Shape()
        new_shape.head = self.head.cp()
        new_shape.segments = [{
            'c2': s['c2'],
            'c1': s['c1'],
            'p2': s['p2']
        } for s in self.segments]
        new_shape.closed = self.closed
        new_shape.zindex = self.zindex
        new_shape.style = self.style.copy()
        return new_shape

    def subd(self, t: float):
        prev_p1 = self.head
        new_segs = []
        for seg in self.segments:
            a = prev_p1
            d = seg['p2']
            b = seg['c1']
            c = seg['c2']
            e = ((b - a) * t) + a
            f = ((c - b) * t) + b
            g = ((d - c) * t) + c
            h = ((f - e) * t) + e
            j = ((g - f) * t) + f
            k = ((j - h) * t) + h
            new_segs.append({'c1': e, 'c2': h, 'p2': k})
            new_segs.append({'c1': j, 'c2': g, 'p2': d})
            prev_p1 = d
        self.segments = new_segs
        return self

    def reg(self, canvas: Canvas):
        canvas.add(self)
        return self

    def cpoints(self) -> list[Point]:
        return [self.head] + [seg['p2'] for seg in self.segments]

    def adjust(self):
        for i in range(1, len(self.segments)):
            s0 = self.segments[i - 1]
            d = Point.distance(s0['c2'], s0['p2'])
            nc1 = Utils.proj(s0['c2'], s0['p2'], 2 * d)
            self.segments[i]['c1'] = nc1
        return self

    def noise(self, func):
        self.head = func(self, self.head)
        for index, seg in enumerate(self.segments):
            func(index, seg)
        return self
Esempio n. 24
0
 def test_rect_from_two_points (self):
     rect = Shapes.rect(Point(100, 100), Point(100, 400), 20)
     self.assertEqual(4, len(rect.segments))
Esempio n. 25
0
 def test_proj(self):
     mid = Point.mid(Point(100,100), Point(200,200))
     self.assertEqual(Point(150,150), mid)
Esempio n. 26
0
 def line(p0: Point = (0, 0), p1: Point = (0, 0)):
     p0 = p0 if type(p0) == Point else Point(p0[0], p0[1])
     p1 = p1 if type(p1) == Point else Point(p1[0], p1[1])
     return Shapes.curve(p0, p0, p1, p1)
Esempio n. 27
0
 def center(self) -> Point:
     points = [self.head] + [s['p2'] for s in self.segments]
     x = np.average([p.x for p in points])
     y = np.average([p.y for p in points])
     return Point(x, y)
Esempio n. 28
0
 def test_point_at(self):
     p = Point.point_at(Point(0, 0), Point(0, 0), Point(100, 100),
                        Point(100, 100), 0.5)
     self.assertEqual(Point(50, 50), p)
     p = Point.point_at(Point(100, 100), Point(100, 100), Point(1000, 100),
                        Point(1000, 100), 0.2)
     self.assertEqual(Point(193.6, 100), p)
Esempio n. 29
0
 def test_interpolate(self):
     mylist = plist([Point(0, 0), Point(20, 30)])
     points = mylist.interpolate()
     self.assertEqual(3, len(points))
     self.assertEqual(Point(10, 15), points[1])