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Pracownia_programowania/venv/Lib/site-packages/matplotlib/backends/backend_svg.py

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2020-02-01 19:54:00 +01:00
from collections import OrderedDict
import base64
import gzip
import hashlib
import io
import logging
import re
import uuid
import numpy as np
from matplotlib import cbook, __version__, rcParams
from matplotlib.backend_bases import (
_Backend, FigureCanvasBase, FigureManagerBase, RendererBase)
from matplotlib.backends.backend_mixed import MixedModeRenderer
from matplotlib.colors import rgb2hex
from matplotlib.font_manager import findfont, get_font
from matplotlib.ft2font import LOAD_NO_HINTING
from matplotlib.mathtext import MathTextParser
from matplotlib.path import Path
from matplotlib import _path
from matplotlib.transforms import Affine2D, Affine2DBase
from matplotlib import _png
_log = logging.getLogger(__name__)
backend_version = __version__
# ----------------------------------------------------------------------
# SimpleXMLWriter class
#
# Based on an original by Fredrik Lundh, but modified here to:
# 1. Support modern Python idioms
# 2. Remove encoding support (it's handled by the file writer instead)
# 3. Support proper indentation
# 4. Minify things a little bit
# --------------------------------------------------------------------
# The SimpleXMLWriter module is
#
# Copyright (c) 2001-2004 by Fredrik Lundh
#
# By obtaining, using, and/or copying this software and/or its
# associated documentation, you agree that you have read, understood,
# and will comply with the following terms and conditions:
#
# Permission to use, copy, modify, and distribute this software and
# its associated documentation for any purpose and without fee is
# hereby granted, provided that the above copyright notice appears in
# all copies, and that both that copyright notice and this permission
# notice appear in supporting documentation, and that the name of
# Secret Labs AB or the author not be used in advertising or publicity
# pertaining to distribution of the software without specific, written
# prior permission.
#
# SECRET LABS AB AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD
# TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANT-
# ABILITY AND FITNESS. IN NO EVENT SHALL SECRET LABS AB OR THE AUTHOR
# BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY
# DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS,
# WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS
# ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE
# OF THIS SOFTWARE.
# --------------------------------------------------------------------
def escape_cdata(s):
s = s.replace("&", "&")
s = s.replace("<", "&lt;")
s = s.replace(">", "&gt;")
return s
_escape_xml_comment = re.compile(r'-(?=-)')
def escape_comment(s):
s = escape_cdata(s)
return _escape_xml_comment.sub('- ', s)
def escape_attrib(s):
s = s.replace("&", "&amp;")
s = s.replace("'", "&apos;")
s = s.replace("\"", "&quot;")
s = s.replace("<", "&lt;")
s = s.replace(">", "&gt;")
return s
def short_float_fmt(x):
"""
Create a short string representation of a float, which is %f
formatting with trailing zeros and the decimal point removed.
"""
return '{0:f}'.format(x).rstrip('0').rstrip('.')
class XMLWriter(object):
"""
Parameters
----------
file : writable text file-like object
"""
def __init__(self, file):
self.__write = file.write
if hasattr(file, "flush"):
self.flush = file.flush
self.__open = 0 # true if start tag is open
self.__tags = []
self.__data = []
self.__indentation = " " * 64
def __flush(self, indent=True):
# flush internal buffers
if self.__open:
if indent:
self.__write(">\n")
else:
self.__write(">")
self.__open = 0
if self.__data:
data = ''.join(self.__data)
self.__write(escape_cdata(data))
self.__data = []
def start(self, tag, attrib={}, **extra):
"""
Opens a new element. Attributes can be given as keyword
arguments, or as a string/string dictionary. The method returns
an opaque identifier that can be passed to the :meth:`close`
method, to close all open elements up to and including this one.
Parameters
----------
tag
Element tag.
attrib
Attribute dictionary. Alternatively, attributes can be given as
keyword arguments.
Returns
-------
An element identifier.
"""
self.__flush()
tag = escape_cdata(tag)
self.__data = []
self.__tags.append(tag)
self.__write(self.__indentation[:len(self.__tags) - 1])
self.__write("<%s" % tag)
for k, v in sorted({**attrib, **extra}.items()):
if not v == '':
k = escape_cdata(k)
v = escape_attrib(v)
self.__write(' %s="%s"' % (k, v))
self.__open = 1
return len(self.__tags)-1
def comment(self, comment):
"""
Adds a comment to the output stream.
Parameters
----------
comment : str
Comment text.
"""
self.__flush()
self.__write(self.__indentation[:len(self.__tags)])
self.__write("<!-- %s -->\n" % escape_comment(comment))
def data(self, text):
"""
Adds character data to the output stream.
Parameters
----------
text : str
Character data.
"""
self.__data.append(text)
def end(self, tag=None, indent=True):
"""
Closes the current element (opened by the most recent call to
:meth:`start`).
Parameters
----------
tag
Element tag. If given, the tag must match the start tag. If
omitted, the current element is closed.
"""
if tag:
assert self.__tags, "unbalanced end(%s)" % tag
assert escape_cdata(tag) == self.__tags[-1], \
"expected end(%s), got %s" % (self.__tags[-1], tag)
else:
assert self.__tags, "unbalanced end()"
tag = self.__tags.pop()
if self.__data:
self.__flush(indent)
elif self.__open:
self.__open = 0
self.__write("/>\n")
return
if indent:
self.__write(self.__indentation[:len(self.__tags)])
self.__write("</%s>\n" % tag)
def close(self, id):
"""
Closes open elements, up to (and including) the element identified
by the given identifier.
Parameters
----------
id
Element identifier, as returned by the :meth:`start` method.
"""
while len(self.__tags) > id:
self.end()
def element(self, tag, text=None, attrib={}, **extra):
"""
Adds an entire element. This is the same as calling :meth:`start`,
:meth:`data`, and :meth:`end` in sequence. The *text* argument can be
omitted.
"""
self.start(*(tag, attrib), **extra)
if text:
self.data(text)
self.end(indent=False)
def flush(self):
"""Flushes the output stream."""
pass # replaced by the constructor
def generate_transform(transform_list=[]):
if len(transform_list):
output = io.StringIO()
for type, value in transform_list:
if (type == 'scale' and (value == (1,) or value == (1, 1))
or type == 'translate' and value == (0, 0)
or type == 'rotate' and value == (0,)):
continue
if type == 'matrix' and isinstance(value, Affine2DBase):
value = value.to_values()
output.write('%s(%s)' % (
type, ' '.join(short_float_fmt(x) for x in value)))
return output.getvalue()
return ''
def generate_css(attrib={}):
if attrib:
output = io.StringIO()
attrib = sorted(attrib.items())
for k, v in attrib:
k = escape_attrib(k)
v = escape_attrib(v)
output.write("%s:%s;" % (k, v))
return output.getvalue()
return ''
_capstyle_d = {'projecting': 'square', 'butt': 'butt', 'round': 'round'}
class RendererSVG(RendererBase):
def __init__(self, width, height, svgwriter, basename=None, image_dpi=72):
self.width = width
self.height = height
self.writer = XMLWriter(svgwriter)
self.image_dpi = image_dpi # actual dpi at which we rasterize stuff
self._groupd = {}
if not rcParams['svg.image_inline']:
assert basename is not None
self.basename = basename
self._imaged = {}
self._clipd = OrderedDict()
self._markers = {}
self._path_collection_id = 0
self._imaged = {}
self._hatchd = OrderedDict()
self._has_gouraud = False
self._n_gradients = 0
self._fonts = OrderedDict()
self.mathtext_parser = MathTextParser('SVG')
RendererBase.__init__(self)
self._glyph_map = dict()
str_height = short_float_fmt(height)
str_width = short_float_fmt(width)
svgwriter.write(svgProlog)
self._start_id = self.writer.start(
'svg',
width='%spt' % str_width,
height='%spt' % str_height,
viewBox='0 0 %s %s' % (str_width, str_height),
xmlns="http://www.w3.org/2000/svg",
version="1.1",
attrib={'xmlns:xlink': "http://www.w3.org/1999/xlink"})
self._write_default_style()
def finalize(self):
self._write_clips()
self._write_hatches()
self.writer.close(self._start_id)
self.writer.flush()
def _write_default_style(self):
writer = self.writer
default_style = generate_css({
'stroke-linejoin': 'round',
'stroke-linecap': 'butt'})
writer.start('defs')
writer.start('style', type='text/css')
writer.data('*{%s}\n' % default_style)
writer.end('style')
writer.end('defs')
def _make_id(self, type, content):
salt = rcParams['svg.hashsalt']
if salt is None:
salt = str(uuid.uuid4())
m = hashlib.md5()
m.update(salt.encode('utf8'))
m.update(str(content).encode('utf8'))
return '%s%s' % (type, m.hexdigest()[:10])
def _make_flip_transform(self, transform):
return (transform +
Affine2D()
.scale(1.0, -1.0)
.translate(0.0, self.height))
def _get_font(self, prop):
fname = findfont(prop)
font = get_font(fname)
font.clear()
size = prop.get_size_in_points()
font.set_size(size, 72.0)
return font
def _get_hatch(self, gc, rgbFace):
"""
Create a new hatch pattern
"""
if rgbFace is not None:
rgbFace = tuple(rgbFace)
edge = gc.get_hatch_color()
if edge is not None:
edge = tuple(edge)
dictkey = (gc.get_hatch(), rgbFace, edge)
oid = self._hatchd.get(dictkey)
if oid is None:
oid = self._make_id('h', dictkey)
self._hatchd[dictkey] = ((gc.get_hatch_path(), rgbFace, edge), oid)
else:
_, oid = oid
return oid
def _write_hatches(self):
if not len(self._hatchd):
return
HATCH_SIZE = 72
writer = self.writer
writer.start('defs')
for (path, face, stroke), oid in self._hatchd.values():
writer.start(
'pattern',
id=oid,
patternUnits="userSpaceOnUse",
x="0", y="0", width=str(HATCH_SIZE),
height=str(HATCH_SIZE))
path_data = self._convert_path(
path,
Affine2D()
.scale(HATCH_SIZE).scale(1.0, -1.0).translate(0, HATCH_SIZE),
simplify=False)
if face is None:
fill = 'none'
else:
fill = rgb2hex(face)
writer.element(
'rect',
x="0", y="0", width=str(HATCH_SIZE+1),
height=str(HATCH_SIZE+1),
fill=fill)
writer.element(
'path',
d=path_data,
style=generate_css({
'fill': rgb2hex(stroke),
'stroke': rgb2hex(stroke),
'stroke-width': str(rcParams['hatch.linewidth']),
'stroke-linecap': 'butt',
'stroke-linejoin': 'miter'
})
)
writer.end('pattern')
writer.end('defs')
def _get_style_dict(self, gc, rgbFace):
"""Generate a style string from the GraphicsContext and rgbFace."""
attrib = {}
forced_alpha = gc.get_forced_alpha()
if gc.get_hatch() is not None:
attrib['fill'] = "url(#%s)" % self._get_hatch(gc, rgbFace)
if (rgbFace is not None and len(rgbFace) == 4 and rgbFace[3] != 1.0
and not forced_alpha):
attrib['fill-opacity'] = short_float_fmt(rgbFace[3])
else:
if rgbFace is None:
attrib['fill'] = 'none'
else:
if tuple(rgbFace[:3]) != (0, 0, 0):
attrib['fill'] = rgb2hex(rgbFace)
if (len(rgbFace) == 4 and rgbFace[3] != 1.0
and not forced_alpha):
attrib['fill-opacity'] = short_float_fmt(rgbFace[3])
if forced_alpha and gc.get_alpha() != 1.0:
attrib['opacity'] = short_float_fmt(gc.get_alpha())
offset, seq = gc.get_dashes()
if seq is not None:
attrib['stroke-dasharray'] = ','.join(
short_float_fmt(val) for val in seq)
attrib['stroke-dashoffset'] = short_float_fmt(float(offset))
linewidth = gc.get_linewidth()
if linewidth:
rgb = gc.get_rgb()
attrib['stroke'] = rgb2hex(rgb)
if not forced_alpha and rgb[3] != 1.0:
attrib['stroke-opacity'] = short_float_fmt(rgb[3])
if linewidth != 1.0:
attrib['stroke-width'] = short_float_fmt(linewidth)
if gc.get_joinstyle() != 'round':
attrib['stroke-linejoin'] = gc.get_joinstyle()
if gc.get_capstyle() != 'butt':
attrib['stroke-linecap'] = _capstyle_d[gc.get_capstyle()]
return attrib
def _get_style(self, gc, rgbFace):
return generate_css(self._get_style_dict(gc, rgbFace))
def _get_clip(self, gc):
cliprect = gc.get_clip_rectangle()
clippath, clippath_trans = gc.get_clip_path()
if clippath is not None:
clippath_trans = self._make_flip_transform(clippath_trans)
dictkey = (id(clippath), str(clippath_trans))
elif cliprect is not None:
x, y, w, h = cliprect.bounds
y = self.height-(y+h)
dictkey = (x, y, w, h)
else:
return None
clip = self._clipd.get(dictkey)
if clip is None:
oid = self._make_id('p', dictkey)
if clippath is not None:
self._clipd[dictkey] = ((clippath, clippath_trans), oid)
else:
self._clipd[dictkey] = (dictkey, oid)
else:
clip, oid = clip
return oid
def _write_clips(self):
if not len(self._clipd):
return
writer = self.writer
writer.start('defs')
for clip, oid in self._clipd.values():
writer.start('clipPath', id=oid)
if len(clip) == 2:
clippath, clippath_trans = clip
path_data = self._convert_path(
clippath, clippath_trans, simplify=False)
writer.element('path', d=path_data)
else:
x, y, w, h = clip
writer.element(
'rect',
x=short_float_fmt(x),
y=short_float_fmt(y),
width=short_float_fmt(w),
height=short_float_fmt(h))
writer.end('clipPath')
writer.end('defs')
def open_group(self, s, gid=None):
# docstring inherited
if gid:
self.writer.start('g', id=gid)
else:
self._groupd[s] = self._groupd.get(s, 0) + 1
self.writer.start('g', id="%s_%d" % (s, self._groupd[s]))
def close_group(self, s):
# docstring inherited
self.writer.end('g')
def option_image_nocomposite(self):
# docstring inherited
return not rcParams['image.composite_image']
def _convert_path(self, path, transform=None, clip=None, simplify=None,
sketch=None):
if clip:
clip = (0.0, 0.0, self.width, self.height)
else:
clip = None
return _path.convert_to_string(
path, transform, clip, simplify, sketch, 6,
[b'M', b'L', b'Q', b'C', b'z'], False).decode('ascii')
def draw_path(self, gc, path, transform, rgbFace=None):
# docstring inherited
trans_and_flip = self._make_flip_transform(transform)
clip = (rgbFace is None and gc.get_hatch_path() is None)
simplify = path.should_simplify and clip
path_data = self._convert_path(
path, trans_and_flip, clip=clip, simplify=simplify,
sketch=gc.get_sketch_params())
attrib = {}
attrib['style'] = self._get_style(gc, rgbFace)
clipid = self._get_clip(gc)
if clipid is not None:
attrib['clip-path'] = 'url(#%s)' % clipid
if gc.get_url() is not None:
self.writer.start('a', {'xlink:href': gc.get_url()})
self.writer.element('path', d=path_data, attrib=attrib)
if gc.get_url() is not None:
self.writer.end('a')
def draw_markers(
self, gc, marker_path, marker_trans, path, trans, rgbFace=None):
# docstring inherited
if not len(path.vertices):
return
writer = self.writer
path_data = self._convert_path(
marker_path,
marker_trans + Affine2D().scale(1.0, -1.0),
simplify=False)
style = self._get_style_dict(gc, rgbFace)
dictkey = (path_data, generate_css(style))
oid = self._markers.get(dictkey)
style = generate_css({k: v for k, v in style.items()
if k.startswith('stroke')})
if oid is None:
oid = self._make_id('m', dictkey)
writer.start('defs')
writer.element('path', id=oid, d=path_data, style=style)
writer.end('defs')
self._markers[dictkey] = oid
attrib = {}
clipid = self._get_clip(gc)
if clipid is not None:
attrib['clip-path'] = 'url(#%s)' % clipid
writer.start('g', attrib=attrib)
trans_and_flip = self._make_flip_transform(trans)
attrib = {'xlink:href': '#%s' % oid}
clip = (0, 0, self.width*72, self.height*72)
for vertices, code in path.iter_segments(
trans_and_flip, clip=clip, simplify=False):
if len(vertices):
x, y = vertices[-2:]
attrib['x'] = short_float_fmt(x)
attrib['y'] = short_float_fmt(y)
attrib['style'] = self._get_style(gc, rgbFace)
writer.element('use', attrib=attrib)
writer.end('g')
def draw_path_collection(self, gc, master_transform, paths, all_transforms,
offsets, offsetTrans, facecolors, edgecolors,
linewidths, linestyles, antialiaseds, urls,
offset_position):
# Is the optimization worth it? Rough calculation:
# cost of emitting a path in-line is
# (len_path + 5) * uses_per_path
# cost of definition+use is
# (len_path + 3) + 9 * uses_per_path
len_path = len(paths[0].vertices) if len(paths) > 0 else 0
uses_per_path = self._iter_collection_uses_per_path(
paths, all_transforms, offsets, facecolors, edgecolors)
should_do_optimization = \
len_path + 9 * uses_per_path + 3 < (len_path + 5) * uses_per_path
if not should_do_optimization:
return RendererBase.draw_path_collection(
self, gc, master_transform, paths, all_transforms,
offsets, offsetTrans, facecolors, edgecolors,
linewidths, linestyles, antialiaseds, urls,
offset_position)
writer = self.writer
path_codes = []
writer.start('defs')
for i, (path, transform) in enumerate(self._iter_collection_raw_paths(
master_transform, paths, all_transforms)):
transform = Affine2D(transform.get_matrix()).scale(1.0, -1.0)
d = self._convert_path(path, transform, simplify=False)
oid = 'C%x_%x_%s' % (
self._path_collection_id, i, self._make_id('', d))
writer.element('path', id=oid, d=d)
path_codes.append(oid)
writer.end('defs')
for xo, yo, path_id, gc0, rgbFace in self._iter_collection(
gc, master_transform, all_transforms, path_codes, offsets,
offsetTrans, facecolors, edgecolors, linewidths, linestyles,
antialiaseds, urls, offset_position):
clipid = self._get_clip(gc0)
url = gc0.get_url()
if url is not None:
writer.start('a', attrib={'xlink:href': url})
if clipid is not None:
writer.start('g', attrib={'clip-path': 'url(#%s)' % clipid})
attrib = {
'xlink:href': '#%s' % path_id,
'x': short_float_fmt(xo),
'y': short_float_fmt(self.height - yo),
'style': self._get_style(gc0, rgbFace)
}
writer.element('use', attrib=attrib)
if clipid is not None:
writer.end('g')
if url is not None:
writer.end('a')
self._path_collection_id += 1
def draw_gouraud_triangle(self, gc, points, colors, trans):
# This uses a method described here:
#
# http://www.svgopen.org/2005/papers/Converting3DFaceToSVG/index.html
#
# that uses three overlapping linear gradients to simulate a
# Gouraud triangle. Each gradient goes from fully opaque in
# one corner to fully transparent along the opposite edge.
# The line between the stop points is perpendicular to the
# opposite edge. Underlying these three gradients is a solid
# triangle whose color is the average of all three points.
writer = self.writer
if not self._has_gouraud:
self._has_gouraud = True
writer.start(
'filter',
id='colorAdd')
writer.element(
'feComposite',
attrib={'in': 'SourceGraphic'},
in2='BackgroundImage',
operator='arithmetic',
k2="1", k3="1")
writer.end('filter')
# feColorMatrix filter to correct opacity
writer.start(
'filter',
id='colorMat')
writer.element(
'feColorMatrix',
attrib={'type': 'matrix'},
values='1 0 0 0 0 \n0 1 0 0 0 \n0 0 1 0 0' +
' \n1 1 1 1 0 \n0 0 0 0 1 ')
writer.end('filter')
avg_color = np.sum(colors[:, :], axis=0) / 3.0
# Just skip fully-transparent triangles
if avg_color[-1] == 0.0:
return
trans_and_flip = self._make_flip_transform(trans)
tpoints = trans_and_flip.transform(points)
writer.start('defs')
for i in range(3):
x1, y1 = tpoints[i]
x2, y2 = tpoints[(i + 1) % 3]
x3, y3 = tpoints[(i + 2) % 3]
c = colors[i][:]
if x2 == x3:
xb = x2
yb = y1
elif y2 == y3:
xb = x1
yb = y2
else:
m1 = (y2 - y3) / (x2 - x3)
b1 = y2 - (m1 * x2)
m2 = -(1.0 / m1)
b2 = y1 - (m2 * x1)
xb = (-b1 + b2) / (m1 - m2)
yb = m2 * xb + b2
writer.start(
'linearGradient',
id="GR%x_%d" % (self._n_gradients, i),
gradientUnits="userSpaceOnUse",
x1=short_float_fmt(x1), y1=short_float_fmt(y1),
x2=short_float_fmt(xb), y2=short_float_fmt(yb))
writer.element(
'stop',
offset='1',
style=generate_css({'stop-color': rgb2hex(avg_color),
'stop-opacity': short_float_fmt(c[-1])}))
writer.element(
'stop',
offset='0',
style=generate_css({'stop-color': rgb2hex(c),
'stop-opacity': "0"}))
writer.end('linearGradient')
writer.end('defs')
# triangle formation using "path"
dpath = "M " + short_float_fmt(x1)+',' + short_float_fmt(y1)
dpath += " L " + short_float_fmt(x2) + ',' + short_float_fmt(y2)
dpath += " " + short_float_fmt(x3) + ',' + short_float_fmt(y3) + " Z"
writer.element(
'path',
attrib={'d': dpath,
'fill': rgb2hex(avg_color),
'fill-opacity': '1',
'shape-rendering': "crispEdges"})
writer.start(
'g',
attrib={'stroke': "none",
'stroke-width': "0",
'shape-rendering': "crispEdges",
'filter': "url(#colorMat)"})
writer.element(
'path',
attrib={'d': dpath,
'fill': 'url(#GR%x_0)' % self._n_gradients,
'shape-rendering': "crispEdges"})
writer.element(
'path',
attrib={'d': dpath,
'fill': 'url(#GR%x_1)' % self._n_gradients,
'filter': 'url(#colorAdd)',
'shape-rendering': "crispEdges"})
writer.element(
'path',
attrib={'d': dpath,
'fill': 'url(#GR%x_2)' % self._n_gradients,
'filter': 'url(#colorAdd)',
'shape-rendering': "crispEdges"})
writer.end('g')
self._n_gradients += 1
def draw_gouraud_triangles(self, gc, triangles_array, colors_array,
transform):
attrib = {}
clipid = self._get_clip(gc)
if clipid is not None:
attrib['clip-path'] = 'url(#%s)' % clipid
self.writer.start('g', attrib=attrib)
transform = transform.frozen()
for tri, col in zip(triangles_array, colors_array):
self.draw_gouraud_triangle(gc, tri, col, transform)
self.writer.end('g')
def option_scale_image(self):
# docstring inherited
return True
def get_image_magnification(self):
return self.image_dpi / 72.0
def draw_image(self, gc, x, y, im, transform=None):
# docstring inherited
h, w = im.shape[:2]
if w == 0 or h == 0:
return
attrib = {}
clipid = self._get_clip(gc)
if clipid is not None:
# Can't apply clip-path directly to the image because the
# image has a transformation, which would also be applied
# to the clip-path
self.writer.start('g', attrib={'clip-path': 'url(#%s)' % clipid})
oid = gc.get_gid()
url = gc.get_url()
if url is not None:
self.writer.start('a', attrib={'xlink:href': url})
if rcParams['svg.image_inline']:
bytesio = io.BytesIO()
_png.write_png(im, bytesio)
oid = oid or self._make_id('image', bytesio.getvalue())
attrib['xlink:href'] = (
"data:image/png;base64,\n" +
base64.b64encode(bytesio.getvalue()).decode('ascii'))
else:
self._imaged[self.basename] = (
self._imaged.get(self.basename, 0) + 1)
filename = '%s.image%d.png' % (
self.basename, self._imaged[self.basename])
_log.info('Writing image file for inclusion: %s', filename)
_png.write_png(im, filename)
oid = oid or 'Im_' + self._make_id('image', filename)
attrib['xlink:href'] = filename
attrib['id'] = oid
if transform is None:
w = 72.0 * w / self.image_dpi
h = 72.0 * h / self.image_dpi
self.writer.element(
'image',
transform=generate_transform([
('scale', (1, -1)), ('translate', (0, -h))]),
x=short_float_fmt(x),
y=short_float_fmt(-(self.height - y - h)),
width=short_float_fmt(w), height=short_float_fmt(h),
attrib=attrib)
else:
alpha = gc.get_alpha()
if alpha != 1.0:
attrib['opacity'] = short_float_fmt(alpha)
flipped = (
Affine2D().scale(1.0 / w, 1.0 / h) +
transform +
Affine2D()
.translate(x, y)
.scale(1.0, -1.0)
.translate(0.0, self.height))
attrib['transform'] = generate_transform(
[('matrix', flipped.frozen())])
self.writer.element(
'image',
width=short_float_fmt(w), height=short_float_fmt(h),
attrib=attrib)
if url is not None:
self.writer.end('a')
if clipid is not None:
self.writer.end('g')
def _adjust_char_id(self, char_id):
return char_id.replace("%20", "_")
def _draw_text_as_path(self, gc, x, y, s, prop, angle, ismath, mtext=None):
"""
draw the text by converting them to paths using textpath module.
Parameters
----------
prop : `matplotlib.font_manager.FontProperties`
font property
s : str
text to be converted
usetex : bool
If True, use matplotlib usetex mode.
ismath : bool
If True, use mathtext parser. If "TeX", use *usetex* mode.
"""
writer = self.writer
writer.comment(s)
glyph_map = self._glyph_map
text2path = self._text2path
color = rgb2hex(gc.get_rgb())
fontsize = prop.get_size_in_points()
style = {}
if color != '#000000':
style['fill'] = color
alpha = gc.get_alpha() if gc.get_forced_alpha() else gc.get_rgb()[3]
if alpha != 1:
style['opacity'] = short_float_fmt(alpha)
if not ismath:
font = text2path._get_font(prop)
_glyphs = text2path.get_glyphs_with_font(
font, s, glyph_map=glyph_map, return_new_glyphs_only=True)
glyph_info, glyph_map_new, rects = _glyphs
if glyph_map_new:
writer.start('defs')
for char_id, glyph_path in glyph_map_new.items():
path = Path(*glyph_path)
path_data = self._convert_path(path, simplify=False)
writer.element('path', id=char_id, d=path_data)
writer.end('defs')
glyph_map.update(glyph_map_new)
attrib = {}
attrib['style'] = generate_css(style)
font_scale = fontsize / text2path.FONT_SCALE
attrib['transform'] = generate_transform([
('translate', (x, y)),
('rotate', (-angle,)),
('scale', (font_scale, -font_scale))])
writer.start('g', attrib=attrib)
for glyph_id, xposition, yposition, scale in glyph_info:
attrib = {'xlink:href': '#%s' % glyph_id}
if xposition != 0.0:
attrib['x'] = short_float_fmt(xposition)
if yposition != 0.0:
attrib['y'] = short_float_fmt(yposition)
writer.element(
'use',
attrib=attrib)
writer.end('g')
else:
if ismath == "TeX":
_glyphs = text2path.get_glyphs_tex(
prop, s, glyph_map=glyph_map, return_new_glyphs_only=True)
else:
_glyphs = text2path.get_glyphs_mathtext(
prop, s, glyph_map=glyph_map, return_new_glyphs_only=True)
glyph_info, glyph_map_new, rects = _glyphs
# We store the character glyphs w/o flipping. Instead, the
# coordinate will be flipped when these characters are used.
if glyph_map_new:
writer.start('defs')
for char_id, glyph_path in glyph_map_new.items():
char_id = self._adjust_char_id(char_id)
# Some characters are blank
if not len(glyph_path[0]):
path_data = ""
else:
path = Path(*glyph_path)
path_data = self._convert_path(path, simplify=False)
writer.element('path', id=char_id, d=path_data)
writer.end('defs')
glyph_map.update(glyph_map_new)
attrib = {}
font_scale = fontsize / text2path.FONT_SCALE
attrib['style'] = generate_css(style)
attrib['transform'] = generate_transform([
('translate', (x, y)),
('rotate', (-angle,)),
('scale', (font_scale, -font_scale))])
writer.start('g', attrib=attrib)
for char_id, xposition, yposition, scale in glyph_info:
char_id = self._adjust_char_id(char_id)
writer.element(
'use',
transform=generate_transform([
('translate', (xposition, yposition)),
('scale', (scale,)),
]),
attrib={'xlink:href': '#%s' % char_id})
for verts, codes in rects:
path = Path(verts, codes)
path_data = self._convert_path(path, simplify=False)
writer.element('path', d=path_data)
writer.end('g')
def _draw_text_as_text(self, gc, x, y, s, prop, angle, ismath, mtext=None):
writer = self.writer
color = rgb2hex(gc.get_rgb())
style = {}
if color != '#000000':
style['fill'] = color
alpha = gc.get_alpha() if gc.get_forced_alpha() else gc.get_rgb()[3]
if alpha != 1:
style['opacity'] = short_float_fmt(alpha)
if not ismath:
font = self._get_font(prop)
font.set_text(s, 0.0, flags=LOAD_NO_HINTING)
fontsize = prop.get_size_in_points()
fontfamily = font.family_name
fontstyle = prop.get_style()
attrib = {}
# Must add "px" to workaround a Firefox bug
style['font-size'] = short_float_fmt(fontsize) + 'px'
style['font-family'] = str(fontfamily)
style['font-style'] = prop.get_style().lower()
style['font-weight'] = str(prop.get_weight()).lower()
attrib['style'] = generate_css(style)
if mtext and (angle == 0 or mtext.get_rotation_mode() == "anchor"):
# If text anchoring can be supported, get the original
# coordinates and add alignment information.
# Get anchor coordinates.
transform = mtext.get_transform()
ax, ay = transform.transform_point(mtext.get_position())
ay = self.height - ay
# Don't do vertical anchor alignment. Most applications do not
# support 'alignment-baseline' yet. Apply the vertical layout
# to the anchor point manually for now.
angle_rad = np.deg2rad(angle)
dir_vert = np.array([np.sin(angle_rad), np.cos(angle_rad)])
v_offset = np.dot(dir_vert, [(x - ax), (y - ay)])
ax = ax + v_offset * dir_vert[0]
ay = ay + v_offset * dir_vert[1]
ha_mpl_to_svg = {'left': 'start', 'right': 'end',
'center': 'middle'}
style['text-anchor'] = ha_mpl_to_svg[mtext.get_ha()]
attrib['x'] = short_float_fmt(ax)
attrib['y'] = short_float_fmt(ay)
attrib['style'] = generate_css(style)
attrib['transform'] = "rotate(%s, %s, %s)" % (
short_float_fmt(-angle),
short_float_fmt(ax),
short_float_fmt(ay))
writer.element('text', s, attrib=attrib)
else:
attrib['transform'] = generate_transform([
('translate', (x, y)),
('rotate', (-angle,))])
writer.element('text', s, attrib=attrib)
else:
writer.comment(s)
width, height, descent, svg_elements, used_characters = \
self.mathtext_parser.parse(s, 72, prop)
svg_glyphs = svg_elements.svg_glyphs
svg_rects = svg_elements.svg_rects
attrib = {}
attrib['style'] = generate_css(style)
attrib['transform'] = generate_transform([
('translate', (x, y)),
('rotate', (-angle,))])
# Apply attributes to 'g', not 'text', because we likely have some
# rectangles as well with the same style and transformation.
writer.start('g', attrib=attrib)
writer.start('text')
# Sort the characters by font, and output one tspan for each.
spans = OrderedDict()
for font, fontsize, thetext, new_x, new_y, metrics in svg_glyphs:
style = generate_css({
'font-size': short_float_fmt(fontsize) + 'px',
'font-family': font.family_name,
'font-style': font.style_name.lower(),
'font-weight': font.style_name.lower()})
if thetext == 32:
thetext = 0xa0 # non-breaking space
spans.setdefault(style, []).append((new_x, -new_y, thetext))
for style, chars in spans.items():
chars.sort()
if len({y for x, y, t in chars}) == 1: # Are all y's the same?
ys = str(chars[0][1])
else:
ys = ' '.join(str(c[1]) for c in chars)
attrib = {
'style': style,
'x': ' '.join(short_float_fmt(c[0]) for c in chars),
'y': ys
}
writer.element(
'tspan',
''.join(chr(c[2]) for c in chars),
attrib=attrib)
writer.end('text')
if len(svg_rects):
for x, y, width, height in svg_rects:
writer.element(
'rect',
x=short_float_fmt(x),
y=short_float_fmt(-y + height),
width=short_float_fmt(width),
height=short_float_fmt(height)
)
writer.end('g')
def draw_tex(self, gc, x, y, s, prop, angle, ismath='TeX!', mtext=None):
# docstring inherited
self._draw_text_as_path(gc, x, y, s, prop, angle, ismath="TeX")
def draw_text(self, gc, x, y, s, prop, angle, ismath=False, mtext=None):
# docstring inherited
clipid = self._get_clip(gc)
if clipid is not None:
# Cannot apply clip-path directly to the text, because
# is has a transformation
self.writer.start(
'g', attrib={'clip-path': 'url(#%s)' % clipid})
if gc.get_url() is not None:
self.writer.start('a', {'xlink:href': gc.get_url()})
if rcParams['svg.fonttype'] == 'path':
self._draw_text_as_path(gc, x, y, s, prop, angle, ismath, mtext)
else:
self._draw_text_as_text(gc, x, y, s, prop, angle, ismath, mtext)
if gc.get_url() is not None:
self.writer.end('a')
if clipid is not None:
self.writer.end('g')
def flipy(self):
# docstring inherited
return True
def get_canvas_width_height(self):
# docstring inherited
return self.width, self.height
def get_text_width_height_descent(self, s, prop, ismath):
# docstring inherited
return self._text2path.get_text_width_height_descent(s, prop, ismath)
class FigureCanvasSVG(FigureCanvasBase):
filetypes = {'svg': 'Scalable Vector Graphics',
'svgz': 'Scalable Vector Graphics'}
fixed_dpi = 72
def print_svg(self, filename, *args, **kwargs):
with cbook.open_file_cm(filename, "w", encoding="utf-8") as fh:
filename = getattr(fh, 'name', '')
if not isinstance(filename, str):
filename = ''
if cbook.file_requires_unicode(fh):
detach = False
else:
fh = io.TextIOWrapper(fh, 'utf-8')
detach = True
result = self._print_svg(filename, fh, **kwargs)
# Detach underlying stream from wrapper so that it remains open in
# the caller.
if detach:
fh.detach()
return result
def print_svgz(self, filename, *args, **kwargs):
with cbook.open_file_cm(filename, "wb") as fh, \
gzip.GzipFile(mode='w', fileobj=fh) as gzipwriter:
return self.print_svg(gzipwriter)
def _print_svg(
self, filename, fh, *, dpi=72, bbox_inches_restore=None, **kwargs):
self.figure.set_dpi(72.0)
width, height = self.figure.get_size_inches()
w, h = width * 72, height * 72
renderer = MixedModeRenderer(
self.figure, width, height, dpi,
RendererSVG(w, h, fh, filename, dpi),
bbox_inches_restore=bbox_inches_restore)
self.figure.draw(renderer)
renderer.finalize()
def get_default_filetype(self):
return 'svg'
FigureManagerSVG = FigureManagerBase
svgProlog = """\
<?xml version="1.0" encoding="utf-8" standalone="no"?>
<!DOCTYPE svg PUBLIC "-//W3C//DTD SVG 1.1//EN"
"http://www.w3.org/Graphics/SVG/1.1/DTD/svg11.dtd">
<!-- Created with matplotlib (https://matplotlib.org/) -->
"""
@_Backend.export
class _BackendSVG(_Backend):
FigureCanvas = FigureCanvasSVG
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