def test_extremes3(self):
     # console.log((new Bezier(127,242,27,5,210,60)).extrema())
     q = QuadraticBezier(Point(127, 242), Point(27, 5), Point(210, 60))
     r = q.findExtremes()
     self.assertEqual(len(r), 2)
     self.assertAlmostEqual(r[0], 0.35335689045936397)
     self.assertAlmostEqual(r[1], 0.8116438356164384)
 def test_quadratic_bounds(self):
     # console.log((new Bezier(150,40,80,30,105,150)).bbox())
     q = QuadraticBezier(Point(150, 40), Point(80, 30), Point(105, 150))
     b = q.bounds()
     self.assertAlmostEqual(b.bl.x, 98.42105263157895)
     self.assertAlmostEqual(b.tr.x, 150)
     self.assertAlmostEqual(b.bl.y, 39.23076923076923)
     self.assertAlmostEqual(b.tr.y, 150)
示例#3
0
 def appendSegment(self, seg):
     seg = [Point(n[0], n[1]) for n in seg]
     if len(seg) == 2:
         self.segments.append(Line(*seg))
     elif len(seg) == 3:
         self.segments.append(QuadraticBezier(*seg))
     elif len(seg) == 4:
         self.segments.append(CubicBezier(*seg))
     else:
         raise ValueError("Unknown segment type")
示例#4
0
    def __get_geometry(self, shape, properties, transform):
        #======================================================
        ##
        ## Returns shape's geometry as `shapely` object.
        ##
        coordinates = []
        bezier_segments = []
        pptx_geometry = Geometry(shape)
        for path in pptx_geometry.path_list:
            bbox = (shape.width,
                    shape.height) if path.w is None or path.h is None else (
                        path.w, path.h)
            T = transform @ DrawMLTransform(shape, bbox)

            moved = False
            first_point = None
            current_point = None
            closed = False

            for c in path.getchildren():
                if c.tag == DML('arcTo'):
                    (wR, hR) = ((pptx_geometry.attrib_value(c, 'wR'),
                                 pptx_geometry.attrib_value(c, 'hR')))
                    stAng = radians(pptx_geometry.attrib_value(c, 'stAng'))
                    swAng = radians(pptx_geometry.attrib_value(c, 'swAng'))
                    p1 = ellipse_point(wR, hR, stAng)
                    p2 = ellipse_point(wR, hR, stAng + swAng)
                    pt = (current_point[0] - p1[0] + p2[0],
                          current_point[1] - p1[1] + p2[1])
                    large_arc_flag = 1 if swAng >= math.pi else 0
                    paths = bezier_paths_from_arc_endpoints(
                        tuple2(wR, hR), 0, large_arc_flag, 1,
                        tuple2(*current_point), tuple2(*pt), T)
                    bezier_segments.extend(paths.asSegments())
                    coordinates.extend(bezier_sample(paths))
                    current_point = pt

                elif c.tag == DML('close'):
                    if first_point is not None and current_point != first_point:
                        coordinates.append(T.transform_point(first_point))
                    closed = True
                    first_point = None
                    # Close current pptx_geometry and start a new one...

                elif c.tag == DML('cubicBezTo'):
                    coords = [BezierPoint(*T.transform_point(current_point))]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*T.transform_point(pt)))
                        current_point = pt
                    bz = CubicBezier(*coords)
                    bezier_segments.append(bz)
                    coordinates.extend(bezier_sample(bz))

                elif c.tag == DML('lnTo'):
                    pt = pptx_geometry.point(c.pt)
                    if moved:
                        coordinates.append(T.transform_point(current_point))
                        moved = False
                    coordinates.append(T.transform_point(pt))
                    current_point = pt

                elif c.tag == DML('moveTo'):
                    pt = pptx_geometry.point(c.pt)
                    if first_point is None:
                        first_point = pt
                    current_point = pt
                    moved = True

                elif c.tag == DML('quadBezTo'):
                    coords = [BezierPoint(*T.transform_point(current_point))]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*T.transform_point(pt)))
                        current_point = pt
                    bz = QuadraticBezier(*coords)
                    bezier_segments.append(bz)
                    coordinates.extend(bezier_sample(bz))

                else:
                    print('Unknown path element: {}'.format(c.tag))

        if settings.get('saveBeziers', False) and len(bezier_segments) > 0:
            properties['bezier-segments'] = [
                repr(bz) for bz in bezier_segments
            ]

        if closed:
            geometry = shapely.geometry.Polygon(coordinates)
        else:
            geometry = shapely.geometry.LineString(coordinates)
            if properties.get('closed', False):
                # Return a polygon if flagged as `closed`
                coordinates.append(coordinates[0])
                return shapely.geometry.Polygon(coordinates)
        return geometry
示例#5
0
 def derivative(self):
     """Returns a `QuadraticBezier` representing the derivative of this curve."""
     return QuadraticBezier((self[1] - self[0]) * 3,
                            (self[2] - self[1]) * 3,
                            (self[3] - self[2]) * 3)
示例#6
0
    def __get_geometry(self, element, properties, transform):
    #=======================================================
    ##
    ## Returns path element as a `shapely` object.
    ##
        coordinates = []
        bezier_segments = []
        moved = False
        first_point = None
        current_point = None
        closed = False
        path_tokens = []

        T = transform@SVGTransform(element.attrib.get('transform'))
        if element.tag == SVG_NS('path'):
            path_tokens = list(parse_svg_path(element.attrib.get('d', '')))

        elif element.tag == SVG_NS('rect'):
            x = length_as_pixels(element.attrib.get('x', 0))
            y = length_as_pixels(element.attrib.get('y', 0))
            width = length_as_pixels(element.attrib.get('width', 0))
            height = length_as_pixels(element.attrib.get('height', 0))
            rx = length_as_pixels(element.attrib.get('rx'))
            ry = length_as_pixels(element.attrib.get('ry'))
            if width == 0 or height == 0: return None

            if rx is None and ry is None:
                rx = ry = 0
            elif ry is None:
                ry = rx
            elif rx is None:
                rx = ry
            rx = min(rx, width/2)
            ry = min(ry, height/2)
            if rx == 0 and ry == 0:
                path_tokens = ['M', x, y,
                               'H', x+width,
                               'V', y+height,
                               'H', x,
                               'V', y,
                               'Z']
            else:
                path_tokens = ['M', x+rx, y,
                               'H', x+width-rx,
                               'A', rx, ry, 0, 0, 1, x+width, y+ry,
                               'V', y+height-ry,
                               'A', rx, ry, 0, 0, 1, x+width-rx, y+height,
                               'H', x+rx,
                               'A', rx, ry, 0, 0, 1, x, y+height-ry,
                               'V', y+ry,
                               'A', rx, ry, 0, 0, 1, x+rx, y,
                               'Z']

        elif element.tag == SVG_NS('line'):
            x1 = length_as_pixels(element.attrib.get('x1', 0))
            y1 = length_as_pixels(element.attrib.get('y1', 0))
            x2 = length_as_pixels(element.attrib.get('x2', 0))
            y2 = length_as_pixels(element.attrib.get('y2', 0))
            path_tokens = ['M', x1, y1, x2, y2]

        elif element.tag == SVG_NS('polyline'):
            points = element.attrib.get('points', '').replace(',', ' ').split()
            path_tokens = ['M'] + points

        elif element.tag == SVG_NS('polygon'):
            points = element.attrib.get('points', '').replace(',', ' ').split()
            path_tokens = ['M'] + points + ['Z']

        elif element.tag == SVG_NS('circle'):
            cx = length_as_pixels(element.attrib.get('cx', 0))
            cy = length_as_pixels(element.attrib.get('cy', 0))
            r = length_as_pixels(element.attrib.get('r', 0))
            if r == 0: return None
            path_tokens = ['M', cx+r, cy,
                           'A', r, r, 0, 0, 0, cx, cy-r,
                           'A', r, r, 0, 0, 0, cx-r, cy,
                           'A', r, r, 0, 0, 0, cx, cy+r,
                           'A', r, r, 0, 0, 0, cx+r, cy,
                           'Z']

        elif element.tag == SVG_NS('ellipse'):
            cx = length_as_pixels(element.attrib.get('cx', 0))
            cy = length_as_pixels(element.attrib.get('cy', 0))
            rx = length_as_pixels(element.attrib.get('rx', 0))
            ry = length_as_pixels(element.attrib.get('ry', 0))
            if rx == 0 or ry == 0: return None
            path_tokens = ['M', cx+rx, cy,
                           'A', rx, ry, 0, 0, 0, cx, cy-ry,
                           'A', rx, ry, 0, 0, 0, cx-rx, cy,
                           'A', rx, ry, 0, 0, 0, cx, cy+ry,
                           'A', rx, ry, 0, 0, 0, cx+rx, cy,
                           'Z']

        elif element.tag == SVG_NS('image'):
            if 'id' in properties or 'class' in properties:
                width = length_as_pixels(element.attrib.get('width', 0))
                height = length_as_pixels(element.attrib.get('height', 0))
                path_tokens = ['M', 0, 0,
                               'H', width,
                               'V', height,
                               'H', 0,
                               'V', 0,
                               'Z']

        pos = 0
        while pos < len(path_tokens):
            if isinstance(path_tokens[pos], str) and path_tokens[pos].isalpha():
                cmd = path_tokens[pos]
                pos += 1
            # Else repeat previous command with new coordinates
            # with `moveTo` becoming `lineTo`
            elif cmd == 'M':
                cmd = 'L'
            elif cmd == 'm':
                cmd = 'l'

            if cmd not in ['s', 'S']:
                second_cubic_control = None
            if cmd not in ['t', 'T']:
                second_quad_control = None

            if cmd in ['a', 'A']:
                params = [float(x) for x in path_tokens[pos:pos+7]]
                pos += 7
                pt = params[5:7]
                if cmd == 'a':
                    pt[0] += current_point[0]
                    pt[1] += current_point[1]
                phi = radians(params[2])
                path = bezier_path_from_arc_endpoints(tuple2(*params[0:2]), phi, *params[3:5],
                                                        tuple2(*current_point), tuple2(*pt), T)
                bezier_segments.extend(path.asSegments())
                coordinates.extend(bezier_sample(path))
                current_point = pt

            elif cmd in ['c', 'C', 's', 'S']:
                coords = [BezierPoint(*T.transform_point(current_point))]
                if cmd in ['c', 'C']:
                    n_params = 6
                else:
                    n_params = 4
                    if second_cubic_control is None:
                        coords.append(BezierPoint(*T.transform_point(current_point)))
                    else:
                        coords.append(BezierPoint(*T.transform_point(
                            reflect_point(second_cubic_control, current_point))))
                params = [float(x) for x in path_tokens[pos:pos+n_params]]
                pos += n_params
                for n in range(0, n_params, 2):
                    pt = params[n:n+2]
                    if cmd.islower():
                        pt[0] += current_point[0]
                        pt[1] += current_point[1]
                    if n == (n_params - 4):
                        second_cubic_control = pt
                    coords.append(BezierPoint(*T.transform_point(pt)))
                bz = CubicBezier(*coords)
                bezier_segments.append(bz)
                coordinates.extend(bezier_sample(bz))
                current_point = pt

            elif cmd in ['l', 'L', 'h', 'H', 'v', 'V']:
                if cmd in ['l', 'L']:
                    params = [float(x) for x in path_tokens[pos:pos+2]]
                    pos += 2
                    pt = params[0:2]
                    if cmd == 'l':
                        pt[0] += current_point[0]
                        pt[1] += current_point[1]
                else:
                    param = float(path_tokens[pos])
                    pos += 1
                    if cmd == 'h':
                        param += current_point[0]
                    elif cmd == 'v':
                        param += current_point[1]
                    if cmd in ['h', 'H']:
                        pt = [param, current_point[1]]
                    else:
                        pt = [current_point[0], param]
                if moved:
                    coordinates.append(T.transform_point(current_point))
                    moved = False
                coordinates.append(T.transform_point(pt))
                current_point = pt

            elif cmd in ['m', 'M']:
                params = [float(x) for x in path_tokens[pos:pos+2]]
                pos += 2
                pt = params[0:2]
                if first_point is None:
                    # First `m` in a path is treated as `M`
                    first_point = pt
                else:
                    if cmd == 'm':
                        pt[0] += current_point[0]
                        pt[1] += current_point[1]
                current_point = pt
                moved = True

            elif cmd in ['q', 'Q', 't', 'T']:
                coords = [BezierPoint(*T.transform_point(current_point))]
                if cmd in ['q', 'Q']:
                    n_params = 4
                else:
                    n_params = 2
                    if second_quad_control is None:
                        coords.append(BezierPoint(*T.transform_point(current_point)))
                    else:
                        coords.append(BezierPoint(*T.transform_point(
                            reflect_point(second_quad_control, current_point))))
                params = [float(x) for x in path_tokens[pos:pos+n_params]]
                pos += n_params
                for n in range(0, n_params, 2):
                    pt = params[n:n+2]
                    if cmd.islower():
                        pt[0] += current_point[0]
                        pt[1] += current_point[1]
                    if n == (n_params - 4):
                        second_quad_control = pt
                    coords.append(BezierPoint(*T.transform_point(pt)))
                bz = QuadraticBezier(*coords)
                bezier_segments.append(bz)
                coordinates.extend(bezier_sample(bz))
                current_point = pt

            elif cmd in ['z', 'Z']:
                if first_point is not None and current_point != first_point:
                    coordinates.append(T.transform_point(first_point))
                closed = True
                first_point = None

            else:
                log.warn('Unknown path command: {}'.format(cmd))

        if len(bezier_segments) > 0:
            properties['bezier-path'] = BezierPath.fromSegments(bezier_segments)

        if closed and len(coordinates) >= 3:
            geometry = shapely.geometry.Polygon(coordinates)
        elif properties.get('closed', False) and len(coordinates) >= 3:
            # Return a polygon if flagged as `closed`
            coordinates.append(coordinates[0])
            geometry = shapely.geometry.Polygon(coordinates)
        elif len(coordinates) >= 2:
            geometry = shapely.geometry.LineString(coordinates)
        else:
            geometry = None
        return geometry
 def test_split(self):
     # console.log((new Bezier(150,40,80,30,105,150)).split(0.2))
     q = QuadraticBezier(Point(150, 40), Point(80, 30), Point(105, 150))
     left, right = q.splitAtTime(0.2)
     self.assertEqual(left[1], Point(136, 38))
     self.assertEqual(right[1], Point(85, 54))
 def test_extremes4(self):
     q = QuadraticBezier(Point(664, 1075), Point(732, 1167),
                         Point(800, 1239))
     r = q.findExtremes()
     self.assertEqual(len(r), 0)
 def test_extremes2(self):
     # console.log((new Bezier(127,242,71,150,210,60)).extrema())
     q = QuadraticBezier(Point(127, 242), Point(71, 150), Point(210, 60))
     r = q.findExtremes()
     self.assertEqual(len(r), 1)
     self.assertAlmostEqual(r[0], 0.28717948717948716)
 def test_extremes(self):
     q = QuadraticBezier(Point(70, 250), Point(13, 187), Point(209, 58))
     r = q.findExtremes()
     self.assertEqual(len(r), 1)
     self.assertAlmostEqual(r[0], 0.22529644268774704)
示例#11
0
    def process_shape(self, shape, properties, transform):
        #=====================================================
        ##
        ## Returns shape's geometry as `shapely` object.
        ##
        coordinates = []
        pptx_geometry = Geometry(shape)
        for path in pptx_geometry.path_list:
            bbox = (shape.width,
                    shape.height) if path.w is None or path.h is None else (
                        path.w, path.h)
            T = transform @ Transform(shape, bbox).matrix()

            moved = False
            first_point = None
            current_point = None
            closed = False

            for c in path.getchildren():
                if c.tag == DML('arcTo'):
                    wR = pptx_geometry.attrib_value(c, 'wR')
                    hR = pptx_geometry.attrib_value(c, 'hR')
                    stAng = radians(pptx_geometry.attrib_value(c, 'stAng'))
                    swAng = radians(pptx_geometry.attrib_value(c, 'swAng'))
                    p1 = ellipse_point(wR, hR, stAng)
                    p2 = ellipse_point(wR, hR, stAng + swAng)
                    pt = (current_point[0] - p1[0] + p2[0],
                          current_point[1] - p1[1] + p2[1])
                    large_arc_flag = 1 if swAng >= math.pi else 0
                    beziers = cubic_beziers_from_arc(tuple2(wR, hR), 0,
                                                     large_arc_flag, 1,
                                                     tuple2(*current_point),
                                                     tuple2(*pt))
                    for bz in beziers:
                        coordinates.extend(transform_bezier_samples(T, bz))
                    current_point = pt

                elif c.tag == DML('close'):
                    if first_point is not None and current_point != first_point:
                        coordinates.append(transform_point(T, first_point))
                    closed = True
                    first_point = None
                    # Close current pptx_geometry and start a new one...

                elif c.tag == DML('cubicBezTo'):
                    coords = [BezierPoint(*current_point)]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*pt))
                        current_point = pt
                    bz = CubicBezier(*coords)
                    coordinates.extend(transform_bezier_samples(T, bz))

                elif c.tag == DML('lnTo'):
                    pt = pptx_geometry.point(c.pt)
                    if moved:
                        coordinates.append(transform_point(T, current_point))
                        moved = False
                    coordinates.append(transform_point(T, pt))
                    current_point = pt

                elif c.tag == DML('moveTo'):
                    pt = pptx_geometry.point(c.pt)
                    if first_point is None:
                        first_point = pt
                    current_point = pt
                    moved = True

                elif c.tag == DML('quadBezTo'):
                    coords = [BezierPoint(*current_point)]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*pt))
                        current_point = pt
                    bz = QuadraticBezier(*coords)
                    coordinates.extend(transform_bezier_samples(T, bz))

                else:
                    print('Unknown path element: {}'.format(c.tag))

        if closed:
            geometry = shapely.geometry.Polygon(coordinates)
        else:
            geometry = shapely.geometry.LineString(coordinates)
            if properties.get('closed', False):
                # Return a polygon if flagged as `closed`
                coordinates.append(coordinates[0])
                return shapely.geometry.Polygon(coordinates)
        return geometry
示例#12
0
    def process_shape(self, shape, transform):
        feature = {'type': 'Feature', 'id': shape.shape_id, 'properties': {}}
        if shape.name_id != '':
            feature['properties']['id'] = '{}/{}'.format(
                self.layer_id, shape.name_id)
            feature['properties']['selectable'] = True
        if len(shape.name_attributes):
            feature['properties']['type'] = shape.name_attributes[0]
        geometry = {}
        coordinates = []

        pptx_geometry = Geometry(shape)
        for path in pptx_geometry.path_list:
            bbox = (shape.width, shape.height) if path.w is None else (path.w,
                                                                       path.h)
            T = transform * Transform(shape, bbox).matrix()

            moved = False
            first_point = None
            current_point = None
            closed = False

            for c in path.getchildren():
                if c.tag == DML('arcTo'):
                    wR = pptx_geometry.attrib_value(c, 'wR')
                    hR = pptx_geometry.attrib_value(c, 'hR')
                    stAng = radians(pptx_geometry.attrib_value(c, 'stAng'))
                    swAng = radians(pptx_geometry.attrib_value(c, 'swAng'))
                    p1 = ellipse_point(wR, hR, stAng)
                    p2 = ellipse_point(wR, hR, stAng + swAng)
                    pt = (current_point[0] - p1[0] + p2[0],
                          current_point[1] - p1[1] + p2[1])
                    large_arc_flag = 1 if swAng >= math.pi else 0
                    beziers = cubic_beziers_from_arc(tuple2(wR, hR), 0,
                                                     large_arc_flag, 1,
                                                     tuple2(*current_point),
                                                     tuple2(*pt))
                    for bz in beziers:
                        coordinates.extend(transform_bezier_samples(T, bz))
                    current_point = pt

                elif c.tag == DML('close'):
                    if first_point is not None and current_point != first_point:
                        coordinates.append(transform_point(T, first_point))
                    closed = True
                    first_point = None
                    # Close current pptx_geometry and start a new one...

                elif c.tag == DML('cubicBezTo'):
                    coords = [BezierPoint(*current_point)]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*pt))
                        current_point = pt
                    bz = CubicBezier(*coords)
                    coordinates.extend(transform_bezier_samples(T, bz))

                elif c.tag == DML('lnTo'):
                    pt = pptx_geometry.point(c.pt)
                    if moved:
                        coordinates.append(transform_point(T, current_point))
                        moved = False
                    coordinates.append(transform_point(T, pt))
                    current_point = pt

                elif c.tag == DML('moveTo'):
                    pt = pptx_geometry.point(c.pt)
                    if first_point is None:
                        first_point = pt
                    current_point = pt
                    moved = True

                elif c.tag == DML('quadBezTo'):
                    coords = [BezierPoint(*current_point)]
                    for p in c.getchildren():
                        pt = pptx_geometry.point(p)
                        coords.append(BezierPoint(*pt))
                        current_point = pt
                    bz = QuadraticBezier(*coords)
                    coordinates.extend(transform_bezier_samples(T, bz))

                else:
                    print('Unknown path element: {}'.format(c.tag))

            lat_lon = points_to_lon_lat(coordinates)
            if closed:
                geometry['type'] = 'Polygon'
                geometry['coordinates'] = [lat_lon]
            else:
                geometry['type'] = 'LineString'
                geometry['coordinates'] = lat_lon

            feature['geometry'] = geometry
            self._features.append(feature)
    def test_quadraticLength(self):
        b1 = QuadraticBezier(Point(150, 40), Point(80, 30), Point(105, 150))
        self.assertAlmostEqual(b1.length, 144.79561403359523)

        b2 = QuadraticBezier(Point(707, 596), Point(645, 596), Point(592, 623))
        self.assertAlmostEqual(b2.length, 119.25113694489232)