def fill_radial_tr_gradient(self, obj, pdfpath, fill_trafo, gradient): if not fill_trafo: fill_trafo = [1.0, 0.0, 0.0, 1.0, 0.0, 0.0] stops = gradient[2] sp, ep = gradient[1] dx, dy = sp l = libgeom.distance(sp, ep) trafo = [1.0, 0.0, 0.0, 1.0, dx, dy] inv_trafo = libgeom.multiply_trafo(libgeom.invert_trafo(fill_trafo), libgeom.invert_trafo(trafo)) cv_trafo = libgeom.multiply_trafo(trafo, fill_trafo) paths = libgeom.apply_trafo_to_paths(obj.paths, obj.trafo) paths = libgeom.apply_trafo_to_paths(paths, inv_trafo) bbox = libgeom.sum_bbox(libgeom.get_paths_bbox(paths), [0.0, 0.0, l, 0.0]) bbox = libgeom.normalize_bbox(bbox) d = libgeom.distance(*libgeom.apply_trafo_to_points([[0.0, 0.0], [0.0, 1.0]], inv_trafo)) circle_paths = libgeom.get_circle_paths(0.0, 0.0, sk2_const.ARC_CHORD) trafo = [2.0, 0.0, 0.0, 2.0, -1.0, -1.0] circle_paths = libgeom.apply_trafo_to_paths(circle_paths, trafo) inner_paths = [] r = 0.0 self.canvas.saveState() self.canvas.clipPath(pdfpath, 0, 0) self.canvas.transform(*cv_trafo) while r < l: point = r / l self.canvas.setFillColor(self.get_grcolor_at_point(stops, point)) if r + d < l: coef = (r + d) else: coef = l trafo = [coef, 0.0, 0.0, coef, 0.0, 0.0] paths = libgeom.apply_trafo_to_paths(circle_paths, trafo) ring = self.make_pdfpath(inner_paths + paths)[0] inner_paths = paths self.canvas.drawPath(ring, stroke=0, fill=1) r += d self.canvas.setFillColor(self.get_grcolor_at_point(stops, 1.0)) r = max(bbox[2] - bbox[0], bbox[3] - bbox[1]) trafo = [2.0 * r, 0.0, 0.0, 2.0 * r, 0.0, 0.0] paths = libgeom.apply_trafo_to_paths(circle_paths, trafo) ring = self.make_pdfpath(inner_paths + paths)[0] self.canvas.drawPath(ring, stroke=0, fill=1) self.canvas.restoreState()
def tr_arc(self, chunk, arc_type=sk2_const.ARC_ARC):
ye, xe, ys, xs, bottom, right, top, left = get_data('<hhhhhhhh',
chunk)
left, top = apply_trafo_to_point([left, top], self.get_trafo())
right, bottom = apply_trafo_to_point([right, bottom], self.get_trafo())
xs, ys = apply_trafo_to_point([xs, ys], self.get_trafo())
xe, ye = apply_trafo_to_point([xe, ye], self.get_trafo())
if left != right and top != bottom:
t = [(right - left) / 2, 0, 0, (bottom - top) / 2,
(right + left) / 2, (top + bottom) / 2]
t = libgeom.invert_trafo(t)
xs, ys = apply_trafo_to_point([xs, ys], t)
xe, ye = apply_trafo_to_point([xe, ye], t)
end_angle = libgeom.get_point_angle([xs, ys], [0.0, 0.0])
start_angle = libgeom.get_point_angle([xe, ye], [0.0, 0.0])
else:
start_angle = end_angle = 0.0
cfg = self.layer.config
sk2_style = self.get_style()
if arc_type == sk2_const.ARC_ARC: sk2_style[0] = []
rect = [left, top, right - left, bottom - top]
ellipse = sk2_model.Circle(cfg, self.layer, rect, start_angle,
end_angle, arc_type, sk2_style)
self.layer.childs.append(ellipse)
def get_path(self): ret = [[], [], self.closed] inv_trafo = libgeom.invert_trafo(self.trafo) ret[0] = libgeom.apply_trafo_to_point(self.start_point.point, inv_trafo) for item in self.points: ret[1].append(libgeom.apply_trafo_to_point(item.point, inv_trafo)) return ret
def fill_linear_tr_gradient(self, obj, pdfpath, fill_trafo, gradient): if not fill_trafo: fill_trafo = [1.0, 0.0, 0.0, 1.0, 0.0, 0.0] stops = gradient[2] sp, ep = gradient[1] dx, dy = sp l = libgeom.distance(sp, ep) angle = libgeom.get_point_angle(ep, sp) m21 = math.sin(angle) m11 = m22 = math.cos(angle) m12 = -m21 trafo = [m11, m21, m12, m22, dx, dy] inv_trafo = libgeom.multiply_trafo(libgeom.invert_trafo(fill_trafo), libgeom.invert_trafo(trafo)) cv_trafo = libgeom.multiply_trafo(trafo, fill_trafo) paths = libgeom.apply_trafo_to_paths(obj.paths, obj.trafo) paths = libgeom.apply_trafo_to_paths(paths, inv_trafo) bbox = libgeom.sum_bbox(libgeom.get_paths_bbox(paths), [0.0, 0.0, l, 0.0]) bbox = libgeom.normalize_bbox(bbox) y = bbox[1] d = libgeom.distance(*libgeom.apply_trafo_to_points([[0.0, 0.0], [0.0, 1.0]], inv_trafo)) height = bbox[3] - bbox[1] self.canvas.saveState() self.canvas.clipPath(pdfpath, 0, 0) self.canvas.transform(*cv_trafo) self.canvas.setFillColor(self.get_grcolor_at_point(stops, 0.0)) self.canvas.rect(bbox[0], y, 0.0 - bbox[0], height, stroke=0, fill=1) x = 0.0 while x < l: point = x / l self.canvas.setFillColor(self.get_grcolor_at_point(stops, point)) if x + d < l: width = d else: width = l - x self.canvas.rect(x, y, width, height, stroke=0, fill=1) x += d self.canvas.setFillColor(self.get_grcolor_at_point(stops, 1.0)) self.canvas.rect(l, y, bbox[2] - l, height, stroke=0, fill=1) self.canvas.restoreState()
def _set_target_vector(self, temp=True): itrafo = libgeom.invert_trafo(self.target.fill_trafo) vector = [self.vector[0].point, self.vector[1].point] self.new_style[0][2][1] = libgeom.apply_trafo_to_points(vector, itrafo) if temp: self.api.set_temp_style(self.target, self.new_style) else: self.api.set_fill_style(deepcopy(self.new_style[0])) events.emit(events.APP_STATUS, self.msg)
def apply_moving(self, event, start=False, final=False):
point = event.get_point()
wpoint = self.canvas.point_win_to_doc(point)
invtrafo = libgeom.invert_trafo(self.target.trafo)
x, y = libgeom.apply_trafo_to_point(wpoint, invtrafo)
x -= 0.5
y -= 0.5
angle = 0.0
if x > 0 and y > 0:
angle = math.atan(y / x)
elif x == 0 and y > 0:
angle = math.pi / 2.0
elif x < 0 < y:
angle = math.atan(-x / y) + math.pi / 2.0
elif x < 0 and y == 0:
angle = math.pi
elif x < 0 and y < 0:
angle = math.atan(y / x) + math.pi
elif x == 0 and y < 0:
angle = 1.5 * math.pi
elif x > 0 > y:
angle = math.atan(x / -y) + 1.5 * math.pi
elif x > 0 and y == 0:
angle = 0.0
elif x == 0 and y == 0:
return
if event.is_ctrl():
fixed_angle = math.pi * config.ellipse_fixed_angle / 180.0
angle //= fixed_angle
angle *= fixed_angle
else:
contra_point = self.start_point
if start:
contra_point = self.end_point
if contra_point.is_pressed(point):
angle = contra_point.get_angle()
circle_type = self.orig_type
if event.is_alt() and not circle_type == sk2const.ARC_ARC:
circle_type = sk2const.ARC_CHORD
if libgeom.distance([x, y]) < 0.5:
circle_type = sk2const.ARC_PIE_SLICE
angle1 = self.orig_angle1
angle2 = self.orig_angle2
if start:
angle1 = angle
else:
angle2 = angle
if final:
self.api.set_circle_properties_final(circle_type, angle1, angle2,
self.orig_type,
self.orig_angle1,
self.orig_angle2, self.target)
else:
self.api.set_circle_properties(circle_type, angle1, angle2,
self.target)
self.update_points()
def apply_moving(self, event, start=False, final=False): point = event.get_point() wpoint = self.canvas.point_win_to_doc(point) invtrafo = libgeom.invert_trafo(self.target.trafo) x, y = libgeom.apply_trafo_to_point(wpoint, invtrafo) x -= 0.5 y -= 0.5 angle = 0.0 if x > 0 and y > 0: angle = math.atan(y / x) elif x == 0 and y > 0: angle = math.pi / 2.0 elif x < 0 and y > 0: angle = math.atan(-x / y) + math.pi / 2.0 elif x < 0 and y == 0: angle = math.pi elif x < 0 and y < 0: angle = math.atan(y / x) + math.pi elif x == 0 and y < 0: angle = 1.5 * math.pi elif x > 0 and y < 0: angle = math.atan(x / -y) + 1.5 * math.pi elif x > 0 and y == 0: angle = 0.0 elif x == 0 and y == 0: return if event.is_ctrl(): fixed_angle = math.pi * config.ellipse_fixed_angle / 180.0 angle //= fixed_angle angle *= fixed_angle else: contra_point = self.start_point if start:contra_point = self.end_point if contra_point.is_pressed(point): angle = contra_point.get_angle() circle_type = self.orig_type if event.is_alt() and not circle_type == sk2_const.ARC_ARC: circle_type = sk2_const.ARC_CHORD if libgeom.distance([x, y]) < 0.5: circle_type = sk2_const.ARC_PIE_SLICE angle1 = self.orig_angle1 angle2 = self.orig_angle2 if start: angle1 = angle else: angle2 = angle if final: self.api.set_circle_properties_final(circle_type, angle1, angle2, self.orig_type, self.orig_angle1, self.orig_angle2, self.target) else: self.api.set_circle_properties(circle_type, angle1, angle2, self.target) self.update_points()
def fill_pattern(self, obj, pdfpath, fill_trafo, pattern):
if not fill_trafo:
fill_trafo = [1.0, 0.0, 0.0, 1.0, 0.0, 0.0]
inv_ptrn_trafo = libgeom.invert_trafo(pattern[3])
inv_trafo = libgeom.multiply_trafo(
libgeom.invert_trafo(fill_trafo),
libgeom.invert_trafo(inv_ptrn_trafo))
paths = libgeom.apply_trafo_to_paths(obj.paths, obj.trafo)
paths = libgeom.apply_trafo_to_paths(paths, inv_trafo)
bbox = libgeom.get_paths_bbox(paths)
cv_trafo = libgeom.multiply_trafo(pattern[3], fill_trafo)
bmpstr = b64decode(pattern[1])
image_obj = sk2_model.Pixmap(obj.config)
libimg.set_image_data(self.cms, image_obj, bmpstr)
if pattern[0] == sk2const.PATTERN_IMG and \
len(pattern) > 2:
image_obj.style[3] = deepcopy(pattern[2])
libimg.update_image(self.cms, image_obj)
self.canvas.saveState()
self.canvas.clipPath(pdfpath, 0, 0)
self.canvas.transform(*cv_trafo)
w, h = image_obj.get_size()
x = bbox[0]
y = bbox[3]
while y > bbox[1] - h:
while x < bbox[2]:
self.canvas.saveState()
self.canvas.transform(1.0, 0.0, 0.0, 1.0, x, y)
self.draw_pixmap_obj(image_obj)
self.canvas.restoreState()
x += w
y -= h
x = bbox[0]
self.canvas.restoreState()
def fill_pattern(self, obj, pdfpath, fill_trafo, pattern): if not fill_trafo: fill_trafo = [1.0, 0.0, 0.0, 1.0, 0.0, 0.0] inv_ptrn_trafo = libgeom.invert_trafo(pattern[3]) inv_trafo = libgeom.multiply_trafo(libgeom.invert_trafo(fill_trafo), libgeom.invert_trafo(inv_ptrn_trafo)) paths = libgeom.apply_trafo_to_paths(obj.paths, obj.trafo) paths = libgeom.apply_trafo_to_paths(paths, inv_trafo) bbox = libgeom.get_paths_bbox(paths) cv_trafo = libgeom.multiply_trafo(pattern[3], fill_trafo) bmpstr = b64decode(pattern[1]) image_obj = sk2_model.Pixmap(obj.config) libimg.set_image_data(self.cms, image_obj, bmpstr) if pattern[0] == sk2_const.PATTERN_IMG and \ len(pattern) > 2: image_obj.style[3] = deepcopy(pattern[2]) libimg.update_image(self.cms, image_obj) self.canvas.saveState() self.canvas.clipPath(pdfpath, 0, 0) self.canvas.transform(*cv_trafo) w, h = image_obj.get_size() x = bbox[0] y = bbox[3] while y > bbox[1] - h: while x < bbox[2]: self.canvas.saveState() self.canvas.transform(1.0, 0.0, 0.0, 1.0, x, y) self.draw_pixmap_obj(image_obj) self.canvas.restoreState() x += w y -= h x = bbox[0] self.canvas.restoreState()
def apply_rounding(self, point, final=False, inplace=False):
wpoint = self.canvas.point_win_to_doc(point)
invtrafo = libgeom.invert_trafo(self.target.trafo)
wpoint = libgeom.apply_trafo_to_point(wpoint, invtrafo)
corners = [] + self.target.corners
name = str(self.rnd_index) + str(self.rnd_subindex)
if self.stop2:
val = abs(wpoint[0] - self.start[0])
val2 = abs(wpoint[1] - self.start[1])
start = self.start
if val > val2:
if self.rnd_index in (0, 2):
stop = self.stop2
res = (wpoint[0] - start[0]) / (stop[0] - start[0])
else:
stop = self.stop
res = (wpoint[0] - start[0]) / (stop[0] - start[0])
else:
if self.rnd_index in (0, 2):
stop = self.stop
res = (wpoint[1] - start[1]) / (stop[1] - start[1])
else:
stop = self.stop2
res = (wpoint[1] - start[1]) / (stop[1] - start[1])
else:
start = self.start
stop = self.stop
if name in H_ORIENT:
res = (wpoint[0] - start[0]) / (stop[0] - start[0])
else:
res = (wpoint[1] - start[1]) / (stop[1] - start[1])
if res < 0.0:
res = 0.0
if res > 1.0:
res = 1.0
if inplace:
corners[self.rnd_index] = res
else:
corners = [res, res, res, res]
if final:
self.api.set_rect_corners_final(corners, self.orig_corners,
self.target)
else:
self.api.set_rect_corners(corners, self.target)
self.update_points()
def get_index_by_point(self, point):
doc_point = self.canvas.win_to_doc(point)
inv_trafo = libgeom.invert_trafo(self.target.trafo)
doc_point = libgeom.apply_trafo_to_point(doc_point, inv_trafo)
line = -1
for item in self.target.cache_line_points:
line += 1
if doc_point[1] >= item[1]: break
index = self.lines[line][0]
for item in range(*self.lines[line]):
layout = self.target.cache_layout_data
pos = layout[index][0] + layout[index][2] / 2.0
if doc_point[0] <= pos: break
index += 1
return index
def apply_resizing(self, point, final=False): wpoint = self.canvas.point_win_to_doc(point) invtrafo = libgeom.invert_trafo(self.target.trafo) wpoint = libgeom.apply_trafo_to_point(wpoint, invtrafo) rect = self.target.get_rect() corners = [] + self.target.corners if self.res_index == 0: rect[2] -= wpoint[0] - rect[0] rect[0] = wpoint[0] if rect[2] < 0: self.res_index = 2 c0, c1, c2, c3 = corners corners = [c3, c2, c1, c0] elif self.res_index == 1: rect[3] = wpoint[1] - rect[1] if rect[3] < 0: self.res_index = 3 c0, c1, c2, c3 = corners corners = [c1, c0, c3, c2] elif self.res_index == 2: rect[2] = wpoint[0] - rect[0] if rect[2] < 0: self.res_index = 0 c0, c1, c2, c3 = corners corners = [c3, c2, c1, c0] elif self.res_index == 3: rect[3] -= wpoint[1] - rect[1] rect[1] = wpoint[1] if rect[3] < 0: self.res_index = 1 c0, c1, c2, c3 = corners corners = [c1, c0, c3, c2] rect = libgeom.normalize_rect(rect) if final: self.api.set_rect_final(self.target, rect, self.orig_rect) if not corners == self.orig_corners: self.api.set_rect_corners_final(corners, self.orig_corners, self.target) self.orig_corners = [] + self.target.corners self.orig_rect = self.target.get_rect() else: self.api.set_rect(self.target, rect) if not corners == self.target.corners: self.api.set_rect_corners(corners, self.target) self.update_points()
def apply_rounding(self, point, final=False, inplace=False): wpoint = self.canvas.point_win_to_doc(point) invtrafo = libgeom.invert_trafo(self.target.trafo) wpoint = libgeom.apply_trafo_to_point(wpoint, invtrafo) corners = [] + self.target.corners name = str(self.rnd_index) + str(self.rnd_subindex) res = 0.0 if self.stop2: val = abs(wpoint[0] - self.start[0]) val2 = abs(wpoint[1] - self.start[1]) start = self.start if val > val2: if self.rnd_index in (0, 2): stop = self.stop2 res = (wpoint[0] - start[0]) / (stop[0] - start[0]) else: stop = self.stop res = (wpoint[0] - start[0]) / (stop[0] - start[0]) else: if self.rnd_index in (0, 2): stop = self.stop res = (wpoint[1] - start[1]) / (stop[1] - start[1]) else: stop = self.stop2 res = (wpoint[1] - start[1]) / (stop[1] - start[1]) else: start = self.start stop = self.stop if name in H_ORIENT: res = (wpoint[0] - start[0]) / (stop[0] - start[0]) else: res = (wpoint[1] - start[1]) / (stop[1] - start[1]) if res < 0.0: res = 0.0 if res > 1.0: res = 1.0 if inplace: corners[self.rnd_index] = res else: corners = [res, res, res, res] if final: self.api.set_rect_corners_final(corners, self.orig_corners, self.target) else: self.api.set_rect_corners(corners, self.target) self.update_points()
def apply_resizing(self, point, final=False):
wpoint = self.canvas.point_win_to_doc(point)
invtrafo = libgeom.invert_trafo(self.target.trafo)
wpoint = libgeom.apply_trafo_to_point(wpoint, invtrafo)
rect = self.target.get_rect()
corners = [] + self.target.corners
if self.res_index == 0:
rect[2] -= wpoint[0] - rect[0]
rect[0] = wpoint[0]
if rect[2] < 0:
self.res_index = 2
c0, c1, c2, c3 = corners
corners = [c3, c2, c1, c0]
elif self.res_index == 1:
rect[3] = wpoint[1] - rect[1]
if rect[3] < 0:
self.res_index = 3
c0, c1, c2, c3 = corners
corners = [c1, c0, c3, c2]
elif self.res_index == 2:
rect[2] = wpoint[0] - rect[0]
if rect[2] < 0:
self.res_index = 0
c0, c1, c2, c3 = corners
corners = [c3, c2, c1, c0]
elif self.res_index == 3:
rect[3] -= wpoint[1] - rect[1]
rect[1] = wpoint[1]
if rect[3] < 0:
self.res_index = 1
c0, c1, c2, c3 = corners
corners = [c1, c0, c3, c2]
rect = libgeom.normalize_rect(rect)
if final:
self.api.set_rect_final(self.target, rect, self.orig_rect)
if not corners == self.orig_corners:
self.api.set_rect_corners_final(corners, self.orig_corners,
self.target)
self.orig_corners = [] + self.target.corners
self.orig_rect = self.target.get_rect()
else:
self.api.set_rect(self.target, rect)
if not corners == self.target.corners:
self.api.set_rect_corners(corners, self.target)
self.update_points()
def apply_midpoint_change(self, point, index, control=False, final=False): wpoint = self.canvas.point_win_to_doc(point) invtrafo = libgeom.invert_trafo(self.target.trafo) x, y = libgeom.apply_trafo_to_point(wpoint, invtrafo) radius = self.target.get_midpoint_radius() angle = self.target.get_midpoint_angle(index) coef2 = libgeom.get_point_radius([x, y]) / radius if control: props = [self.orig_angle1, self.orig_angle2, self.orig_coef1, coef2] else: angle2 = libgeom.get_point_angle([x, y]) - angle props = [self.orig_angle1, angle2, self.orig_coef1, coef2] if final: props_before = [self.orig_angle1, self.orig_angle2, self.orig_coef1, self.orig_coef2] self.api.set_polygon_properties_final(props, props_before, self.target) else: self.api.set_polygon_properties(props, self.target) self.update_points()
def apply_midpoint_change(self, point, index, control=False, final=False):
wpoint = self.canvas.point_win_to_doc(point)
invtrafo = libgeom.invert_trafo(self.target.trafo)
x, y = libgeom.apply_trafo_to_point(wpoint, invtrafo)
radius = self.target.get_midpoint_radius()
angle = self.target.get_midpoint_angle(index)
coef2 = libgeom.get_point_radius([x, y]) / radius
if control:
props = [self.orig_angle1, self.orig_angle2,
self.orig_coef1, coef2]
else:
angle2 = libgeom.get_point_angle([x, y]) - angle
props = [self.orig_angle1, angle2,
self.orig_coef1, coef2]
if final:
props_before = [self.orig_angle1, self.orig_angle2,
self.orig_coef1, self.orig_coef2]
self.api.set_polygon_properties_final(props, props_before,
self.target)
else:
self.api.set_polygon_properties(props, self.target)
self.update_points()
def parse_svg_path_cmds(pathcmds):
index = 0
last = None
last_index = 0
cmds = []
pathcmds = re.sub(' *', ' ', pathcmds)
for item in pathcmds:
if item in 'MmZzLlHhVvCcSsQqTtAa':
if last:
coords = parse_svg_coords(pathcmds[last_index + 1:index])
cmds.append((last, coords))
last = item
last_index = index
index += 1
coords = parse_svg_coords(pathcmds[last_index + 1:index])
cmds.append([last, coords])
paths = []
path = []
cpoint = []
rel_flag = False
last_cmd = 'M'
last_quad = None
for cmd in cmds:
if cmd[0] in 'Mm':
if path: paths.append(path)
path = deepcopy(PATH_STUB)
rel_flag = cmd[0] == 'm'
points = [cmd[1][i:i + 2] for i in range(0, len(cmd[1]), 2)]
for point in points:
if cpoint and rel_flag:
point = add_points(base_point(cpoint), point)
if not path[0]:
path[0] = point
else:
path[1].append(point)
cpoint = point
elif cmd[0] in 'Zz':
p0 = [] + base_point(cpoint)
p1 = [] + path[0]
if not libgeom.is_equal_points(p0, p1, 8):
path[1].append([] + path[0])
path[2] = sk2const.CURVE_CLOSED
cpoint = [] + path[0]
elif cmd[0] in 'Cc':
rel_flag = cmd[0] == 'c'
points = [cmd[1][i:i + 2] for i in range(0, len(cmd[1]), 2)]
points = [points[i:i + 3] for i in range(0, len(points), 3)]
for point in points:
if rel_flag:
point = [
add_points(base_point(cpoint), point[0]),
add_points(base_point(cpoint), point[1]),
add_points(base_point(cpoint), point[2])
]
qpoint = [] + point
qpoint.append(sk2const.NODE_CUSP)
path[1].append(qpoint)
cpoint = point
elif cmd[0] in 'Ll':
rel_flag = cmd[0] == 'l'
points = [cmd[1][i:i + 2] for i in range(0, len(cmd[1]), 2)]
for point in points:
if rel_flag:
point = add_points(base_point(cpoint), point)
path[1].append(point)
cpoint = point
elif cmd[0] in 'Hh':
rel_flag = cmd[0] == 'h'
for x in cmd[1]:
dx, y = base_point(cpoint)
if rel_flag:
point = [x + dx, y]
else:
point = [x, y]
path[1].append(point)
cpoint = point
elif cmd[0] in 'Vv':
rel_flag = cmd[0] == 'v'
for y in cmd[1]:
x, dy = base_point(cpoint)
if rel_flag:
point = [x, y + dy]
else:
point = [x, y]
path[1].append(point)
cpoint = point
elif cmd[0] in 'Ss':
rel_flag = cmd[0] == 's'
points = [cmd[1][i:i + 2] for i in range(0, len(cmd[1]), 2)]
points = [points[i:i + 2] for i in range(0, len(points), 2)]
for point in points:
q = cpoint
p = cpoint
if len(cpoint) > 2:
q = cpoint[1]
p = cpoint[2]
p1 = sub_points(add_points(p, p), q)
if rel_flag:
p2 = add_points(base_point(cpoint), point[0])
p3 = add_points(base_point(cpoint), point[1])
else:
p2, p3 = point
point = [p1, p2, p3]
qpoint = [] + point
qpoint.append(sk2const.NODE_CUSP)
path[1].append(qpoint)
cpoint = point
elif cmd[0] in 'Qq':
rel_flag = cmd[0] == 'q'
groups = [cmd[1][i:i + 4] for i in range(0, len(cmd[1]), 4)]
for vals in groups:
p = base_point(cpoint)
if rel_flag:
q = add_points(p, [vals[0], vals[1]])
p3 = add_points(p, [vals[2], vals[3]])
else:
q = [vals[0], vals[1]]
p3 = [vals[2], vals[3]]
p1 = add_points(mult_point(p, F13), mult_point(q, F23))
p2 = add_points(mult_point(p3, F13), mult_point(q, F23))
point = [p1, p2, p3]
qpoint = [] + point
qpoint.append(sk2const.NODE_CUSP)
path[1].append(qpoint)
cpoint = point
last_quad = q
elif cmd[0] in 'Tt':
rel_flag = cmd[0] == 't'
groups = [cmd[1][i:i + 2] for i in range(0, len(cmd[1]), 2)]
if last_cmd not in 'QqTt' or last_quad is None:
last_quad = base_point(cpoint)
for vals in groups:
p = base_point(cpoint)
q = sub_points(mult_point(p, 2.0), last_quad)
if rel_flag:
p3 = add_points(p, [vals[0], vals[1]])
else:
p3 = [vals[0], vals[1]]
p1 = add_points(mult_point(p, F13), mult_point(q, F23))
p2 = add_points(mult_point(p3, F13), mult_point(q, F23))
point = [p1, p2, p3]
qpoint = [] + point
qpoint.append(sk2const.NODE_CUSP)
path[1].append(qpoint)
cpoint = point
last_quad = q
elif cmd[0] in 'Aa':
rel_flag = cmd[0] == 'a'
arcs = [cmd[1][i:i + 7] for i in range(0, len(cmd[1]), 7)]
for arc in arcs:
cpoint = base_point(cpoint)
rev_flag = False
rx, ry, xrot, large_arc_flag, sweep_flag, x, y = arc
rx = abs(rx)
ry = abs(ry)
if rel_flag:
x += cpoint[0]
y += cpoint[1]
if cpoint == [x, y]: continue
if not rx or not ry:
path[1].append([x, y])
continue
vector = [[] + cpoint, [x, y]]
if sweep_flag:
vector = [[x, y], [] + cpoint]
rev_flag = True
cpoint = [x, y]
dir_tr = libgeom.trafo_rotate_grad(-xrot)
if rx > ry:
tr = [1.0, 0.0, 0.0, rx / ry, 0.0, 0.0]
r = rx
else:
tr = [ry / rx, 0.0, 0.0, 1.0, 0.0, 0.0]
r = ry
dir_tr = libgeom.multiply_trafo(dir_tr, tr)
vector = libgeom.apply_trafo_to_points(vector, dir_tr)
l = libgeom.distance(*vector)
if l > 2.0 * r: r = l / 2.0
mp = libgeom.midpoint(*vector)
tr0 = libgeom.trafo_rotate(math.pi / 2.0, mp[0], mp[1])
pvector = libgeom.apply_trafo_to_points(vector, tr0)
k = math.sqrt(r * r - l * l / 4.0)
if large_arc_flag:
center = libgeom.midpoint(mp, pvector[1], 2.0 * k / l)
else:
center = libgeom.midpoint(mp, pvector[0], 2.0 * k / l)
angle1 = libgeom.get_point_angle(vector[0], center)
angle2 = libgeom.get_point_angle(vector[1], center)
da = angle2 - angle1
start = angle1
end = angle2
if large_arc_flag:
if -math.pi >= da or da <= math.pi:
start = angle2
end = angle1
rev_flag = not rev_flag
else:
if -math.pi <= da or da >= math.pi:
start = angle2
end = angle1
rev_flag = not rev_flag
pth = libgeom.get_circle_paths(start, end, sk2const.ARC_ARC)[0]
if rev_flag:
pth = libgeom.reverse_path(pth)
points = pth[1]
for point in points:
if len(point) == 3:
point.append(sk2const.NODE_CUSP)
tr0 = [1.0, 0.0, 0.0, 1.0, -0.5, -0.5]
points = libgeom.apply_trafo_to_points(points, tr0)
tr1 = [2.0 * r, 0.0, 0.0, 2.0 * r, 0.0, 0.0]
points = libgeom.apply_trafo_to_points(points, tr1)
tr2 = [1.0, 0.0, 0.0, 1.0, center[0], center[1]]
points = libgeom.apply_trafo_to_points(points, tr2)
tr3 = libgeom.invert_trafo(dir_tr)
points = libgeom.apply_trafo_to_points(points, tr3)
for point in points:
path[1].append(point)
last_cmd = cmd[0]
if path: paths.append(path)
return paths
def is_point_in_layout_bbox(self, point):
bbox = self.target.cache_layout_bbox
doc_point = self.canvas.win_to_doc(point)
inv_trafo = libgeom.invert_trafo(self.target.trafo)
doc_point = libgeom.apply_trafo_to_point(doc_point, inv_trafo)
return libgeom.is_point_in_bbox(doc_point, bbox)
def set_sk2_style(sk1_style, dest_obj=None):
sk2_style = [[], [], [], []]
line_pattern = sk1_style.line_pattern
fill_pattern = sk1_style.fill_pattern
if not line_pattern.is_Empty:
sk2_line = [
sk2const.STROKE_MIDDLE, sk1_style.line_width,
get_sk2_color(line_pattern.color),
list(sk1_style.line_dashes), SK2_LINE_CAP[sk1_style.line_cap],
SK2_LINE_JOIN[sk1_style.line_join], 10.0, 0, 0, []
]
sk2_style[1] = sk2_line
if fill_pattern.is_Solid:
sk2_fill = []
if fill_pattern.is_Solid:
sk2_fill = [
sk2const.FILL_EVENODD, sk2const.FILL_SOLID,
get_sk2_color(fill_pattern.color)
]
sk2_style[0] = sk2_fill
elif fill_pattern.is_AxialGradient:
stops = get_sk2_stops(fill_pattern.gradient.colors)
point = [fill_pattern.direction.x, fill_pattern.direction.y]
angle = libgeom.get_point_angle(point, [0.0, 0.0])
points = [[0.0, 0.0], [1.0, 0.0], [1.0, 1.0], [0.0, 1.0]]
m21 = math.sin(-angle)
m11 = m22 = math.cos(-angle)
m12 = -m21
dx = 0.5 - m11 * 0.5 + m21 * 0.5
dy = 0.5 - m21 * 0.5 - m11 * 0.5
trafo = [m11, m21, m12, m22, dx, dy]
points = libgeom.apply_trafo_to_points(points, trafo)
bbox = libgeom.bbox_for_points(points)
w, h = libgeom.bbox_size(bbox)
vector = [[bbox[0], 0.5], [bbox[2], 0.5]]
invtrafo = libgeom.invert_trafo(trafo)
vector = libgeom.apply_trafo_to_points(vector, invtrafo)
dest_obj.update()
bbox = dest_obj.cache_bbox
w, h = libgeom.bbox_size(bbox)
trafo = [w, 0.0, 0.0, h, bbox[0], bbox[1]]
vector = libgeom.apply_trafo_to_points(vector, trafo)
sk2_fill = [
sk2const.FILL_EVENODD, sk2const.FILL_GRADIENT,
[sk2const.GRADIENT_LINEAR, vector, stops]
]
sk2_style[0] = sk2_fill
dest_obj.fill_trafo = [] + sk2const.NORMAL_TRAFO
elif fill_pattern.is_RadialGradient or fill_pattern.is_ConicalGradient:
stops = get_sk2_stops(fill_pattern.gradient.colors)
dest_obj.update()
bbox = dest_obj.cache_bbox
cg = [fill_pattern.center.x, fill_pattern.center.y]
w, h = libgeom.bbox_size(bbox)
start_point = [bbox[0] + w * cg[0], bbox[1] + h * cg[1]]
points = libgeom.bbox_points(bbox)
r = 0
for point in points:
dist = libgeom.distance(point, start_point)
r = max(r, dist)
end_point = [start_point[0] + r, start_point[1]]
sk2_fill = [
sk2const.FILL_EVENODD, sk2const.FILL_GRADIENT,
[sk2const.GRADIENT_RADIAL, [start_point, end_point], stops]
]
sk2_style[0] = sk2_fill
dest_obj.fill_trafo = [] + sk2const.NORMAL_TRAFO
dest_obj.style = sk2_style
