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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# -----------------------------------------------------------------------------
#
# FreeType high-level python API - Copyright 2011 Nicolas P. Rougier
# Distributed under the terms of the new BSD license.
#
# - The code is incomplete and over-simplified, as it ignores the 3rd order
# bezier curve bit and always intepolate between off-curve points.
# This is only correct for truetype fonts (which only use 2nd order bezier curves).
# - Also it seems to assume the first point is always on curve; this is
# unusual but legal.
#
# -----------------------------------------------------------------------------
'''
Show how to access glyph outline description.
'''
from freetype import *
if __name__ == '__main__':
import numpy
import matplotlib.pyplot as plt
from matplotlib.path import Path
import matplotlib.patches as patches
face = Face('./Vera.ttf')
face.set_char_size( 48*64 )
face.load_char('S')
slot = face.glyph
outline = slot.outline
points = numpy.array(outline.points, dtype=[('x',float), ('y',float)])
x, y = points['x'], points['y']
figure = plt.figure(figsize=(8,10))
axis = figure.add_subplot(111)
#axis.scatter(points['x'], points['y'], alpha=.25)
start, end = 0, 0
VERTS, CODES = [], []
# Iterate over each contour
for i in range(len(outline.contours)):
end = outline.contours[i]
points = outline.points[start:end+1]
points.append(points[0])
tags = outline.tags[start:end+1]
tags.append(tags[0])
segments = [ [points[0],], ]
for j in range(1, len(points) ):
segments[-1].append(points[j])
if tags[j] & (1 << 0) and j < (len(points)-1):
segments.append( [points[j],] )
verts = [points[0], ]
codes = [Path.MOVETO,]
for segment in segments:
if len(segment) == 2:
verts.extend(segment[1:])
codes.extend([Path.LINETO])
elif len(segment) == 3:
verts.extend(segment[1:])
codes.extend([Path.CURVE3, Path.CURVE3])
else:
verts.append(segment[1])
codes.append(Path.CURVE3)
for i in range(1,len(segment)-2):
A,B = segment[i], segment[i+1]
C = ((A[0]+B[0])/2.0, (A[1]+B[1])/2.0)
verts.extend([ C, B ])
codes.extend([ Path.CURVE3, Path.CURVE3])
verts.append(segment[-1])
codes.append(Path.CURVE3)
VERTS.extend(verts)
CODES.extend(codes)
start = end+1
# Draw glyph lines
path = Path(VERTS, CODES)
glyph = patches.PathPatch(path, facecolor='.75', lw=1)
# Draw "control" lines
for i, code in enumerate(CODES):
if code == Path.CURVE3:
CODES[i] = Path.LINETO
path = Path(VERTS, CODES)
patch = patches.PathPatch(path, ec='.5', fill=False, ls='dashed', lw=1 )
axis.add_patch(patch)
axis.add_patch(glyph)
axis.set_xlim(x.min()-100, x.max()+100)
plt.xticks([])
axis.set_ylim(y.min()-100, y.max()+100)
plt.yticks([])
plt.show()
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