Exemplo n.º 1
0
    def __init__(self, width, height, dpi):
        RendererBase.__init__(self)

        self.dpi = dpi
        self.width = width
        self.height = height
        self._renderer = _RendererAgg(int(width), int(height), dpi)
        self._filter_renderers = []

        self._update_methods()
        self.mathtext_parser = MathTextParser('Agg')

        self.bbox = Bbox.from_bounds(0, 0, self.width, self.height)
Exemplo n.º 2
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 def __init__(self, dpi, width, height):
     super(RendererGR, self).__init__()
     self.dpi = dpi
     if __version__[0] >= '2':
         self.nominal_fontsize = 0.001625
         default_dpi = 100
     else:
         self.nominal_fontsize = 0.0013
         default_dpi = 80
     self.width = float(width) * dpi / default_dpi
     self.height = float(height) * dpi / default_dpi
     self.mathtext_parser = MathTextParser('agg')
     self.texmanager = TexManager()
Exemplo n.º 3
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    def updateShape(self):
        try:
            self.bitmapName = './tmp/tex_bmp_' + str(self.uid) + '.png'
            q = MathTextParser('Bitmap')
            q.to_png(self.bitmapName, self.parameter['LaTex'].value)

            self.png = QPixmap(self.bitmapName)

        except:
            print ('>>> ERROR ImageLaTex.updateShape')
            print ('    Syntax Error - chyba pri update/parsovani LaTex retazca alebo renedrovani')
            print ('    obrazku ' + self.bitmapName)
            self.png = QPixmap(self.path + '/img/error_tex_format.png')
Exemplo n.º 4
0
    def __init__(self):
        """
        Initialization
        """
        self.mathtext_parser = MathTextParser('path')
        self.tex_font_map = None

        from matplotlib.cbook import maxdict
        self._ps_fontd = maxdict(50)

        self._texmanager = None

        self._adobe_standard_encoding = None
Exemplo n.º 5
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    def __init__(self, width, height, svgwriter, basename=None):
        self.width = width
        self.height = height
        self._svgwriter = svgwriter

        self._groupd = {}
        if not rcParams['svg.image_inline']:
            assert basename is not None
            self.basename = basename
            self._imaged = {}
        self._clipd = {}
        self._char_defs = {}
        self.mathtext_parser = MathTextParser('SVG')
        svgwriter.write(svgProlog % (width, height, width, height))
Exemplo n.º 6
0
 def __init__(self, dpi):
     self.dpi = dpi
     self.width = 640.0 * dpi / 80
     self.height = 480.0 * dpi / 80
     mwidth, mheight, width, height = gr.inqdspsize()
     if (width / (mwidth / 0.0256) < 200):
         mwidth *= self.width / width
         gr.setwsviewport(0, mwidth, 0, mwidth * 0.75)
     else:
         gr.setwsviewport(0, 0.192, 0, 0.144)
     gr.setwswindow(0, 1, 0, 0.75)
     gr.setviewport(0, 1, 0, 0.75)
     gr.setwindow(0, self.width, 0, self.height)
     self.mathtext_parser = MathTextParser('agg')
     self.texmanager = TexManager()
Exemplo n.º 7
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def render_latex_mpl(text, path, color=(0, 0, 0), dpi=600, output="png"):
    r"""
    Render a LaTeX-formula into an image with matplotlib.

    Parameters
    ----------
    text : string
        String containing the latex-code.
    path : string
        Path to the file to be saved.
    color : tuple, optional
        color of the text given as rgb tuple. Default: ``(0, 0, 0)``
    dpi : int, optional
        Used dpi. Default: 1200
    output : string, optional
        Output format. Default: ``"png"``

    Notes
    -----
    If you get the following error:

        ``RuntimeError: libpng signaled error``

    Try to set the dpi higher. (1200 recomended)

    If big symbols like ``\int`` or ``\sum`` don't show up properly,
    try setting a

        ``\displaystyle``

    infront of them.
    """
    from matplotlib.mathtext import MathTextParser
    from matplotlib.font_manager import FontProperties
    from matplotlib import figure, rc

    # backend_agg supports all of the core output formats
    from matplotlib.backends import backend_agg

    rc("text", usetex=False)
    prop = FontProperties()
    parser = MathTextParser("path")
    width, height, depth, _, _ = parser.parse(text, dpi=72, prop=prop)
    fig = figure.Figure(figsize=(width / 72.0, height / 72.0))
    fig.text(0, depth / height, text, fontproperties=prop, color=color)
    backend_agg.FigureCanvasAgg(fig)
    fig.savefig(path, dpi=dpi, format=output, transparent=True)
Exemplo n.º 8
0
Arquivo: plot.py Projeto: goulu/Goulib
def render(plotables, fmt='svg', **kwargs):
    """renders several Plot objects"""
    import matplotlib.pyplot as plt

    # extract optional arguments used for rasterization
    printargs, kwargs = itertools2.dictsplit(
        kwargs, ['dpi', 'transparent', 'facecolor', 'background', 'figsize'])

    ylim = kwargs.pop('ylim', None)
    xlim = kwargs.pop('xlim', None)
    title = kwargs.pop('title', None)

    fig, ax = plt.subplots()

    labels = kwargs.pop('labels', [None] * len(plotables))
    # slightly shift the points to make superimposed curves more visible
    offset = kwargs.pop('offset', 0)

    for i, obj in enumerate(plotables):
        if labels[i] is None:
            labels[i] = str(obj)
        if not title:
            try:
                title = obj._repr_latex_()
                # check that title can be used in matplotlib
                from matplotlib.mathtext import MathTextParser
                parser = MathTextParser('path').parse(title)
            except Exception as e:
                title = labels[i]
        ax = obj._plot(ax, label=labels[i], offset=i * offset, **kwargs)

    if ylim:
        plt.ylim(ylim)
    if xlim:
        plt.xlim(xlim)

    ax.set_title(title)

    if len(labels) > 1:
        ax.legend()

    output = io.BytesIO()
    fig.savefig(output, format=fmt, **printargs)
    data = output.getvalue()
    plt.close(fig)
    return data
Exemplo n.º 9
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def math_to_image(s, filename_or_obj, prop=None, dpi=None, format=None):
    """
    Given a math expression, renders it in a closely-clipped bounding
    box to an image file.

    *s*
       A math expression.  The math portion should be enclosed in
       dollar signs.

    *filename_or_obj*
       A filepath or writable file-like object to write the image data
       to.

    *prop*
       If provided, a FontProperties() object describing the size and
       style of the text.

    *dpi*
       Override the output dpi, otherwise use the default associated
       with the output format.

    *format*
       The output format, eg. 'svg', 'pdf', 'ps' or 'png'.  If not
       provided, will be deduced from the filename.
    """
    from matplotlib import figure
    # backend_agg supports all of the core output formats
    from matplotlib.backends import backend_agg
    from matplotlib.font_manager import FontProperties
    from matplotlib.mathtext import MathTextParser

    if prop is None:
        prop = FontProperties()

    parser = MathTextParser('path')
    width, height, depth, _, _ = parser.parse(s, dpi=72, prop=prop)

    fig = figure.Figure(figsize=(width / 72.0, height / 72.0))
    fig.text(0, depth / height, s, fontproperties=prop)
    backend_agg.FigureCanvasAgg(fig)
    fig.savefig(filename_or_obj, dpi=dpi, format=format)

    return depth
Exemplo n.º 10
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    def __init__(self, width, height, dpi):
        if __debug__: verbose.report('RendererAgg.__init__', 'debug-annoying')
        RendererBase.__init__(self)

        self.dpi = dpi
        self.width = width
        self.height = height
        if __debug__: verbose.report('RendererAgg.__init__ width=%s, height=%s'%(width, height), 'debug-annoying')
        self._renderer = _RendererAgg(int(width), int(height), dpi, debug=False)
        self._filter_renderers = []

        if __debug__: verbose.report('RendererAgg.__init__ _RendererAgg done',
                                     'debug-annoying')

        self._update_methods()
        self.mathtext_parser = MathTextParser('Agg')

        self.bbox = Bbox.from_bounds(0, 0, self.width, self.height)
        if __debug__: verbose.report('RendererAgg.__init__ done',
                                     'debug-annoying')
Exemplo n.º 11
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    def __init__(self, width, height, svgwriter, basename=None):
        self.width = width
        self.height = height
        self._svgwriter = svgwriter
        if rcParams['path.simplify']:
            self.simplify = (width, height)
        else:
            self.simplify = None

        self._groupd = {}
        if not rcParams['svg.image_inline']:
            assert basename is not None
            self.basename = basename
            self._imaged = {}
        self._clipd = {}
        self._char_defs = {}
        self._markers = {}
        self._path_collection_id = 0
        self._imaged = {}
        self.mathtext_parser = MathTextParser('SVG')
        svgwriter.write(svgProlog % (width, height, width, height))
Exemplo n.º 12
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 def __init__(self, width, height, ctx, dpi=72):
     self.width = width
     self.height = height
     self.dpi = dpi
     self.ctx = ctx
     self._image_count = 0
     # used to uniquely label each image created in this figure...
     # define the js context
     self.ctx.width = width
     self.ctx.height = height
     #self.ctx.textAlign = "center";
     self.ctx.textBaseline = "alphabetic"
     self.flip = Affine2D().scale(1, -1).translate(0, height)
     self.mathtext_parser = MathTextParser('bitmap')
     self._path_time = 0
     self._text_time = 0
     self._marker_time = 0
     self._sub_time = 0
     self._last_clip = None
     self._last_clip_path = None
     self._clip_count = 0
Exemplo n.º 13
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    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  # the actual dpi we want to rasterize stuff with

        self._groupd = {}
        if not rcParams['svg.image_inline']:
            assert basename is not None
            self.basename = basename
            self._imaged = {}
        self._clipd = OrderedDict()
        self._char_defs = {}
        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)

        # Changes starts here for Image Truncation
        # Changed from integer to float to accept decimals
        self._start_id = self.writer.start(
            'svg',
            width='%dpt' % str_width,
            height='%dpt' % str_height,
            viewBox='0 0 %d %d' % (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()
Exemplo n.º 14
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    def __init__(self, width, height, dpi):
        if __debug__: verbose.report('RendererAgg.__init__', 'debug-annoying')
        RendererBase.__init__(self)
        self.dpi = dpi
        self.width = width
        self.height = height
        if __debug__: verbose.report('RendererAgg.__init__ width=%s, height=%s'%(width, height), 'debug-annoying')
        self._renderer = _RendererAgg(int(width), int(height), dpi, debug=False)
        if __debug__: verbose.report('RendererAgg.__init__ _RendererAgg done',
                                     'debug-annoying')
        self.draw_path = self._renderer.draw_path
        self.draw_markers = self._renderer.draw_markers
        self.draw_path_collection = self._renderer.draw_path_collection
        self.draw_quad_mesh = self._renderer.draw_quad_mesh
        self.draw_image = self._renderer.draw_image
        self.copy_from_bbox = self._renderer.copy_from_bbox
        self.restore_region = self._renderer.restore_region
        self.tostring_rgba_minimized = self._renderer.tostring_rgba_minimized
        self.mathtext_parser = MathTextParser('Agg')

        self.bbox = Bbox.from_bounds(0, 0, self.width, self.height)
        if __debug__: verbose.report('RendererAgg.__init__ done',
                                     'debug-annoying')
Exemplo n.º 15
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    def __init__(self, width, height, svgwriter, basename=None):
        self.width = width
        self.height = height
        self._svgwriter = svgwriter

        self._groupd = {}
        if not rcParams['svg.image_inline']:
            assert basename is not None
            self.basename = basename
            self._imaged = {}
        self._clipd = {}
        self._char_defs = {}
        self._markers = {}
        self._path_collection_id = 0
        self._imaged = {}
        self._hatchd = {}
        self._n_gradients = 0
        self.mathtext_parser = MathTextParser('SVG')

        RendererBase.__init__(self)
        self._glyph_map = dict()

        svgwriter.write(svgProlog % (width, height, width, height))
Exemplo n.º 16
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    def __init__(self, width, height, pswriter, dpi=72):
        RendererBase.__init__(self)
        self.width = width
        self.height = height
        self._pswriter = pswriter
        if rcParams['text.usetex']:
            self.textcnt = 0
            self.psfrag = []

        # current renderer state (None=uninitialised)
        self.color = None
        self.linewidth = None
        self.linejoin = None
        self.linecap = None
        self.linedash = None
        self.fontname = None
        self.fontsize = None
        self.hatch = None
        self.image_magnification = dpi / 72.0
        self._clip_paths = {}
        self._path_collection_id = 0

        self.used_characters = {}
        self.mathtext_parser = MathTextParser("PS")
Exemplo n.º 17
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def plot_attention(image,
                   predicted_labels,
                   rf_coords,
                   alignment_history,
                   time=0):
    """Plot the highest attention region for image at time t in the decoding"""
    fig, axes = plt.subplots(2, 1, figsize=(12, 6))
    axes[0].set_title("Highest alignment score")
    axes[0].imshow(np.squeeze(image), cmap='gray')
    rf_coords_flat = np.reshape(rf_coords, (-1, 4))

    idx = alignment_history.argmax(axis=1)
    i, score = idx[time], alignment_history[np.arange(len(alignment_history)),
                                            idx][time]
    bbox = rf_coords_flat[i]
    plot_bbox(axes[0], bbox, score)

    check_parser = MathTextParser('MacOSX')

    kwargs = {
        'x': 0.0,
        'y': 0.5,
        'size': 30,
        'verticalalignment': 'center',
        'horizontalalignment': 'left'
    }

    axes[1].set_title("Prediction so far")
    predicted_formula = "$" + convert_to_formula(
        predicted_labels[0][:time]) + "$"
    try:
        check_parser.parse(predicted_formula)
        axes[1].text(s=predicted_formula, **kwargs)
    except ValueError:
        kwargs['size'] = 15
        axes[1].text(s=predicted_formula[1:-1].replace(' ', ''), **kwargs)
Exemplo n.º 18
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class RendererCairo(RendererBase):
    mathtext_parser = _api.deprecated("3.4")(
        property(lambda self: MathTextParser('Cairo')))

    def __init__(self, dpi):
        self.dpi = dpi
        self.gc = GraphicsContextCairo(renderer=self)
        self.text_ctx = cairo.Context(
           cairo.ImageSurface(cairo.FORMAT_ARGB32, 1, 1))
        super().__init__()

    def set_ctx_from_surface(self, surface):
        self.gc.ctx = cairo.Context(surface)
        # Although it may appear natural to automatically call
        # `self.set_width_height(surface.get_width(), surface.get_height())`
        # here (instead of having the caller do so separately), this would fail
        # for PDF/PS/SVG surfaces, which have no way to report their extents.

    def set_width_height(self, width, height):
        self.width = width
        self.height = height

    def _fill_and_stroke(self, ctx, fill_c, alpha, alpha_overrides):
        if fill_c is not None:
            ctx.save()
            if len(fill_c) == 3 or alpha_overrides:
                ctx.set_source_rgba(fill_c[0], fill_c[1], fill_c[2], alpha)
            else:
                ctx.set_source_rgba(fill_c[0], fill_c[1], fill_c[2], fill_c[3])
            ctx.fill_preserve()
            ctx.restore()
        ctx.stroke()

    def draw_path(self, gc, path, transform, rgbFace=None):
        # docstring inherited
        ctx = gc.ctx
        # Clip the path to the actual rendering extents if it isn't filled.
        clip = (ctx.clip_extents()
                if rgbFace is None and gc.get_hatch() is None
                else None)
        transform = (transform
                     + Affine2D().scale(1, -1).translate(0, self.height))
        ctx.new_path()
        _append_path(ctx, path, transform, clip)
        self._fill_and_stroke(
            ctx, rgbFace, gc.get_alpha(), gc.get_forced_alpha())

    def draw_markers(self, gc, marker_path, marker_trans, path, transform,
                     rgbFace=None):
        # docstring inherited

        ctx = gc.ctx
        ctx.new_path()
        # Create the path for the marker; it needs to be flipped here already!
        _append_path(ctx, marker_path, marker_trans + Affine2D().scale(1, -1))
        marker_path = ctx.copy_path_flat()

        # Figure out whether the path has a fill
        x1, y1, x2, y2 = ctx.fill_extents()
        if x1 == 0 and y1 == 0 and x2 == 0 and y2 == 0:
            filled = False
            # No fill, just unset this (so we don't try to fill it later on)
            rgbFace = None
        else:
            filled = True

        transform = (transform
                     + Affine2D().scale(1, -1).translate(0, self.height))

        ctx.new_path()
        for i, (vertices, codes) in enumerate(
                path.iter_segments(transform, simplify=False)):
            if len(vertices):
                x, y = vertices[-2:]
                ctx.save()

                # Translate and apply path
                ctx.translate(x, y)
                ctx.append_path(marker_path)

                ctx.restore()

                # Slower code path if there is a fill; we need to draw
                # the fill and stroke for each marker at the same time.
                # Also flush out the drawing every once in a while to
                # prevent the paths from getting way too long.
                if filled or i % 1000 == 0:
                    self._fill_and_stroke(
                        ctx, rgbFace, gc.get_alpha(), gc.get_forced_alpha())

        # Fast path, if there is no fill, draw everything in one step
        if not filled:
            self._fill_and_stroke(
                ctx, rgbFace, gc.get_alpha(), gc.get_forced_alpha())

    def draw_image(self, gc, x, y, im):
        im = cbook._unmultiplied_rgba8888_to_premultiplied_argb32(im[::-1])
        surface = cairo.ImageSurface.create_for_data(
            im.ravel().data, cairo.FORMAT_ARGB32,
            im.shape[1], im.shape[0], im.shape[1] * 4)
        ctx = gc.ctx
        y = self.height - y - im.shape[0]

        ctx.save()
        ctx.set_source_surface(surface, float(x), float(y))
        ctx.paint()
        ctx.restore()

    def draw_text(self, gc, x, y, s, prop, angle, ismath=False, mtext=None):
        # docstring inherited

        # Note: (x, y) are device/display coords, not user-coords, unlike other
        # draw_* methods
        if ismath:
            self._draw_mathtext(gc, x, y, s, prop, angle)

        else:
            ctx = gc.ctx
            ctx.new_path()
            ctx.move_to(x, y)

            ctx.save()
            ctx.select_font_face(*_cairo_font_args_from_font_prop(prop))
            ctx.set_font_size(prop.get_size_in_points() * self.dpi / 72)
            opts = cairo.FontOptions()
            opts.set_antialias(
                cairo.ANTIALIAS_DEFAULT if mpl.rcParams["text.antialiased"]
                else cairo.ANTIALIAS_NONE)
            ctx.set_font_options(opts)
            if angle:
                ctx.rotate(np.deg2rad(-angle))
            ctx.show_text(s)
            ctx.restore()

    def _draw_mathtext(self, gc, x, y, s, prop, angle):
        ctx = gc.ctx
        width, height, descent, glyphs, rects = \
            self._text2path.mathtext_parser.parse(s, self.dpi, prop)

        ctx.save()
        ctx.translate(x, y)
        if angle:
            ctx.rotate(np.deg2rad(-angle))

        for font, fontsize, idx, ox, oy in glyphs:
            ctx.new_path()
            ctx.move_to(ox, -oy)
            ctx.select_font_face(
                *_cairo_font_args_from_font_prop(ttfFontProperty(font)))
            ctx.set_font_size(fontsize * self.dpi / 72)
            ctx.show_text(chr(idx))

        for ox, oy, w, h in rects:
            ctx.new_path()
            ctx.rectangle(ox, -oy, w, -h)
            ctx.set_source_rgb(0, 0, 0)
            ctx.fill_preserve()

        ctx.restore()

    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

        if ismath == 'TeX':
            return super().get_text_width_height_descent(s, prop, ismath)

        if ismath:
            width, height, descent, *_ = \
                self._text2path.mathtext_parser.parse(s, self.dpi, prop)
            return width, height, descent

        ctx = self.text_ctx
        # problem - scale remembers last setting and font can become
        # enormous causing program to crash
        # save/restore prevents the problem
        ctx.save()
        ctx.select_font_face(*_cairo_font_args_from_font_prop(prop))
        # Cairo (says it) uses 1/96 inch user space units, ref: cairo_gstate.c
        # but if /96.0 is used the font is too small
        ctx.set_font_size(prop.get_size_in_points() * self.dpi / 72)

        y_bearing, w, h = ctx.text_extents(s)[1:4]
        ctx.restore()

        return w, h, h + y_bearing

    def new_gc(self):
        # docstring inherited
        self.gc.ctx.save()
        self.gc._alpha = 1
        self.gc._forced_alpha = False  # if True, _alpha overrides A from RGBA
        return self.gc

    def points_to_pixels(self, points):
        # docstring inherited
        return points / 72 * self.dpi
Exemplo n.º 19
0
 def __init__(self):
     self.mathtext_parser = MathTextParser('path')
     self._texmanager = None
Exemplo n.º 20
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    _("Green"): "green",
    _("Red"): "red",
    _("Yellow"): "yellow",
    _("Cyan"): "cyan",
    _("Magenta"): "magenta",
    _("Grey"): "grey",
    _("Orange"): "orange",
}

# --- latex (optional):  insertion of latex formulas via matplotlib
try:
    from matplotlib import rc
    rc('text', usetex=True)
    from matplotlib.mathtext import MathTextParser
    from matplotlib.image import imsave
    parser = MathTextParser('bitmap')
    LATEX = True
except ImportError:
    LATEX = False


def math_to_image(latex, image_path, **options):
    img = parser.to_rgba(latex, **options)[0]
    imsave(image_path, img)


# --- filebrowser
ZENITY = False

paths = os.environ['PATH'].split(":")
for path in paths:
Exemplo n.º 21
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 def mathtext_parser(self):
     return MathTextParser("PS")
Exemplo n.º 22
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class RendererPS(_backend_pdf_ps.RendererPDFPSBase):
    """
    The renderer handles all the drawing primitives using a graphics
    context instance that controls the colors/styles.
    """

    _afm_font_dir = cbook._get_data_path("fonts/afm")
    _use_afm_rc_name = "ps.useafm"

    mathtext_parser = _api.deprecated("3.4")(
        property(lambda self: MathTextParser("PS")))

    def __init__(self, width, height, pswriter, imagedpi=72):
        # Although postscript itself is dpi independent, we need to inform the
        # image code about a requested dpi to generate high resolution images
        # and them scale them before embedding them.
        super().__init__(width, height)
        self._pswriter = pswriter
        if mpl.rcParams['text.usetex']:
            self.textcnt = 0
            self.psfrag = []
        self.imagedpi = imagedpi

        # current renderer state (None=uninitialised)
        self.color = None
        self.linewidth = None
        self.linejoin = None
        self.linecap = None
        self.linedash = None
        self.fontname = None
        self.fontsize = None
        self._hatches = {}
        self.image_magnification = imagedpi / 72
        self._clip_paths = {}
        self._path_collection_id = 0

        self._character_tracker = _backend_pdf_ps.CharacterTracker()

    def set_color(self, r, g, b, store=True):
        if (r, g, b) != self.color:
            if r == g and r == b:
                self._pswriter.write("%1.3f setgray\n" % r)
            else:
                self._pswriter.write("%1.3f %1.3f %1.3f setrgbcolor\n" %
                                     (r, g, b))
            if store:
                self.color = (r, g, b)

    def set_linewidth(self, linewidth, store=True):
        linewidth = float(linewidth)
        if linewidth != self.linewidth:
            self._pswriter.write("%1.3f setlinewidth\n" % linewidth)
            if store:
                self.linewidth = linewidth

    @staticmethod
    def _linejoin_cmd(linejoin):
        # Support for directly passing integer values is for backcompat.
        linejoin = {
            'miter': 0,
            'round': 1,
            'bevel': 2,
            0: 0,
            1: 1,
            2: 2
        }[linejoin]
        return f"{linejoin:d} setlinejoin\n"

    def set_linejoin(self, linejoin, store=True):
        if linejoin != self.linejoin:
            self._pswriter.write(self._linejoin_cmd(linejoin))
            if store:
                self.linejoin = linejoin

    @staticmethod
    def _linecap_cmd(linecap):
        # Support for directly passing integer values is for backcompat.
        linecap = {
            'butt': 0,
            'round': 1,
            'projecting': 2,
            0: 0,
            1: 1,
            2: 2
        }[linecap]
        return f"{linecap:d} setlinecap\n"

    def set_linecap(self, linecap, store=True):
        if linecap != self.linecap:
            self._pswriter.write(self._linecap_cmd(linecap))
            if store:
                self.linecap = linecap

    def set_linedash(self, offset, seq, store=True):
        if self.linedash is not None:
            oldo, oldseq = self.linedash
            if np.array_equal(seq, oldseq) and oldo == offset:
                return

        if seq is not None and len(seq):
            s = "[%s] %d setdash\n" % (_nums_to_str(*seq), offset)
            self._pswriter.write(s)
        else:
            self._pswriter.write("[] 0 setdash\n")
        if store:
            self.linedash = (offset, seq)

    def set_font(self, fontname, fontsize, store=True):
        if (fontname, fontsize) != (self.fontname, self.fontsize):
            self._pswriter.write(f"/{fontname} {fontsize:1.3f} selectfont\n")
            if store:
                self.fontname = fontname
                self.fontsize = fontsize

    def create_hatch(self, hatch):
        sidelen = 72
        if hatch in self._hatches:
            return self._hatches[hatch]
        name = 'H%d' % len(self._hatches)
        linewidth = mpl.rcParams['hatch.linewidth']
        pageheight = self.height * 72
        self._pswriter.write(f"""\
  << /PatternType 1
     /PaintType 2
     /TilingType 2
     /BBox[0 0 {sidelen:d} {sidelen:d}]
     /XStep {sidelen:d}
     /YStep {sidelen:d}

     /PaintProc {{
        pop
        {linewidth:f} setlinewidth
{self._convert_path(
    Path.hatch(hatch), Affine2D().scale(sidelen), simplify=False)}
        gsave
        fill
        grestore
        stroke
     }} bind
   >>
   matrix
   0.0 {pageheight:f} translate
   makepattern
   /{name} exch def
""")
        self._hatches[hatch] = name
        return name

    def get_image_magnification(self):
        """
        Get the factor by which to magnify images passed to draw_image.
        Allows a backend to have images at a different resolution to other
        artists.
        """
        return self.image_magnification

    def _convert_path(self, path, transform, clip=False, simplify=None):
        if clip:
            clip = (0.0, 0.0, self.width * 72.0, self.height * 72.0)
        else:
            clip = None
        return _path.convert_to_string(path, transform, clip, simplify, None,
                                       6, [b"m", b"l", b"", b"c", b"cl"],
                                       True).decode("ascii")

    def _get_clip_cmd(self, gc):
        clip = []
        rect = gc.get_clip_rectangle()
        if rect is not None:
            clip.append("%s clipbox\n" % _nums_to_str(*rect.size, *rect.p0))
        path, trf = gc.get_clip_path()
        if path is not None:
            key = (path, id(trf))
            custom_clip_cmd = self._clip_paths.get(key)
            if custom_clip_cmd is None:
                custom_clip_cmd = "c%x" % len(self._clip_paths)
                self._pswriter.write(f"""\
/{custom_clip_cmd} {{
{self._convert_path(path, trf, simplify=False)}
clip
newpath
}} bind def
""")
                self._clip_paths[key] = custom_clip_cmd
            clip.append(f"{custom_clip_cmd}\n")
        return "".join(clip)

    def draw_image(self, gc, x, y, im, transform=None):
        # docstring inherited

        h, w = im.shape[:2]
        imagecmd = "false 3 colorimage"
        data = im[::-1, :, :3]  # Vertically flipped rgb values.
        # data.tobytes().hex() has no spaces, so can be linewrapped by simply
        # splitting data every nchars. It's equivalent to textwrap.fill only
        # much faster.
        nchars = 128
        data = data.tobytes().hex()
        hexlines = "\n".join([
            data[n * nchars:(n + 1) * nchars]
            for n in range(math.ceil(len(data) / nchars))
        ])

        if transform is None:
            matrix = "1 0 0 1 0 0"
            xscale = w / self.image_magnification
            yscale = h / self.image_magnification
        else:
            matrix = " ".join(map(str, transform.frozen().to_values()))
            xscale = 1.0
            yscale = 1.0

        self._pswriter.write(f"""\
gsave
{self._get_clip_cmd(gc)}
{x:f} {y:f} translate
[{matrix}] concat
{xscale:f} {yscale:f} scale
/DataString {w:d} string def
{w:d} {h:d} 8 [ {w:d} 0 0 -{h:d} 0 {h:d} ]
{{
currentfile DataString readhexstring pop
}} bind {imagecmd}
{hexlines}
grestore
""")

    def draw_path(self, gc, path, transform, rgbFace=None):
        # docstring inherited
        clip = rgbFace is None and gc.get_hatch_path() is None
        simplify = path.should_simplify and clip
        ps = self._convert_path(path, transform, clip=clip, simplify=simplify)
        self._draw_ps(ps, gc, rgbFace)

    def draw_markers(self,
                     gc,
                     marker_path,
                     marker_trans,
                     path,
                     trans,
                     rgbFace=None):
        # docstring inherited

        if debugPS:
            self._pswriter.write('% draw_markers \n')

        ps_color = (None if _is_transparent(rgbFace) else '%1.3f setgray' %
                    rgbFace[0] if rgbFace[0] == rgbFace[1] == rgbFace[2] else
                    '%1.3f %1.3f %1.3f setrgbcolor' % rgbFace[:3])

        # construct the generic marker command:

        # don't want the translate to be global
        ps_cmd = ['/o {', 'gsave', 'newpath', 'translate']

        lw = gc.get_linewidth()
        alpha = (gc.get_alpha() if gc.get_forced_alpha()
                 or len(gc.get_rgb()) == 3 else gc.get_rgb()[3])
        stroke = lw > 0 and alpha > 0
        if stroke:
            ps_cmd.append('%.1f setlinewidth' % lw)
            ps_cmd.append(self._linejoin_cmd(gc.get_joinstyle()))
            ps_cmd.append(self._linecap_cmd(gc.get_capstyle()))

        ps_cmd.append(
            self._convert_path(marker_path, marker_trans, simplify=False))

        if rgbFace:
            if stroke:
                ps_cmd.append('gsave')
            if ps_color:
                ps_cmd.extend([ps_color, 'fill'])
            if stroke:
                ps_cmd.append('grestore')

        if stroke:
            ps_cmd.append('stroke')
        ps_cmd.extend(['grestore', '} bind def'])

        for vertices, code in path.iter_segments(trans,
                                                 clip=(0, 0, self.width * 72,
                                                       self.height * 72),
                                                 simplify=False):
            if len(vertices):
                x, y = vertices[-2:]
                ps_cmd.append("%g %g o" % (x, y))

        ps = '\n'.join(ps_cmd)
        self._draw_ps(ps, gc, rgbFace, fill=False, stroke=False)

    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 + 2) * uses_per_path
        # cost of definition+use is
        #     (len_path + 3) + 3 * 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 + 3 * uses_per_path + 3 < (len_path + 2) * 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)

        path_codes = []
        for i, (path, transform) in enumerate(
                self._iter_collection_raw_paths(master_transform, paths,
                                                all_transforms)):
            name = 'p%x_%x' % (self._path_collection_id, i)
            path_bytes = self._convert_path(path, transform, simplify=False)
            self._pswriter.write(f"""\
/{name} {{
newpath
translate
{path_bytes}
}} bind def
""")
            path_codes.append(name)

        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):
            ps = "%g %g %s" % (xo, yo, path_id)
            self._draw_ps(ps, gc0, rgbFace)

        self._path_collection_id += 1

    def draw_tex(self, gc, x, y, s, prop, angle, *, mtext=None):
        # docstring inherited
        if not hasattr(self, "psfrag"):
            _log.warning(
                "The PS backend determines usetex status solely based on "
                "rcParams['text.usetex'] and does not support having "
                "usetex=True only for some elements; this element will thus "
                "be rendered as if usetex=False.")
            self.draw_text(gc, x, y, s, prop, angle, False, mtext)
            return

        w, h, bl = self.get_text_width_height_descent(s, prop, ismath="TeX")
        fontsize = prop.get_size_in_points()
        thetext = 'psmarker%d' % self.textcnt
        color = '%1.3f,%1.3f,%1.3f' % gc.get_rgb()[:3]
        fontcmd = {
            'sans-serif': r'{\sffamily %s}',
            'monospace': r'{\ttfamily %s}'
        }.get(mpl.rcParams['font.family'][0], r'{\rmfamily %s}')
        s = fontcmd % s
        tex = r'\color[rgb]{%s} %s' % (color, s)

        # Stick to the bottom alignment.
        pos = _nums_to_str(x, y - bl)
        self.psfrag.append(r'\psfrag{%s}[bl][bl][1][%f]{\fontsize{%f}{%f}%s}' %
                           (thetext, angle, fontsize, fontsize * 1.25, tex))

        self._pswriter.write(f"""\
gsave
{pos} moveto
({thetext})
show
grestore
""")
        self.textcnt += 1

    def draw_text(self, gc, x, y, s, prop, angle, ismath=False, mtext=None):
        # docstring inherited

        if debugPS:
            self._pswriter.write("% text\n")

        if _is_transparent(gc.get_rgb()):
            return  # Special handling for fully transparent.

        if ismath == 'TeX':
            return self.draw_tex(gc, x, y, s, prop, angle)

        if ismath:
            return self.draw_mathtext(gc, x, y, s, prop, angle)

        if mpl.rcParams['ps.useafm']:
            font = self._get_font_afm(prop)
            scale = 0.001 * prop.get_size_in_points()

            thisx = 0
            last_name = None  # kerns returns 0 for None.
            xs_names = []
            for c in s:
                name = uni2type1.get(ord(c), f"uni{ord(c):04X}")
                try:
                    width = font.get_width_from_char_name(name)
                except KeyError:
                    name = 'question'
                    width = font.get_width_char('?')
                kern = font.get_kern_dist_from_name(last_name, name)
                last_name = name
                thisx += kern * scale
                xs_names.append((thisx, name))
                thisx += width * scale

        else:
            font = self._get_font_ttf(prop)
            font.set_text(s, 0, flags=LOAD_NO_HINTING)
            self._character_tracker.track(font, s)
            xs_names = [(item.x, font.get_glyph_name(item.glyph_idx))
                        for item in _text_helpers.layout(s, font)]

        self.set_color(*gc.get_rgb())
        ps_name = (font.postscript_name.encode("ascii",
                                               "replace").decode("ascii"))
        self.set_font(ps_name, prop.get_size_in_points())
        thetext = "\n".join(f"{x:f} 0 m /{name:s} glyphshow"
                            for x, name in xs_names)
        self._pswriter.write(f"""\
gsave
{self._get_clip_cmd(gc)}
{x:f} {y:f} translate
{angle:f} rotate
{thetext}
grestore
""")

    def draw_mathtext(self, gc, x, y, s, prop, angle):
        """Draw the math text using matplotlib.mathtext."""
        if debugPS:
            self._pswriter.write("% mathtext\n")

        width, height, descent, glyphs, rects = \
            self._text2path.mathtext_parser.parse(
                s, 72, prop,
                _force_standard_ps_fonts=mpl.rcParams["ps.useafm"])
        self.set_color(*gc.get_rgb())
        self._pswriter.write(f"gsave\n"
                             f"{x:f} {y:f} translate\n"
                             f"{angle:f} rotate\n")
        lastfont = None
        for font, fontsize, num, ox, oy in glyphs:
            self._character_tracker.track(font, chr(num))
            if (font.postscript_name, fontsize) != lastfont:
                lastfont = font.postscript_name, fontsize
                self._pswriter.write(
                    f"/{font.postscript_name} {fontsize} selectfont\n")
            symbol_name = (font.get_name_char(chr(num)) if isinstance(
                font, AFM) else font.get_glyph_name(font.get_char_index(num)))
            self._pswriter.write(f"{ox:f} {oy:f} moveto\n"
                                 f"/{symbol_name} glyphshow\n")
        for ox, oy, w, h in rects:
            self._pswriter.write(f"{ox} {oy} {w} {h} rectfill\n")
        self._pswriter.write("grestore\n")

    def draw_gouraud_triangle(self, gc, points, colors, trans):
        self.draw_gouraud_triangles(gc, points.reshape((1, 3, 2)),
                                    colors.reshape((1, 3, 4)), trans)

    def draw_gouraud_triangles(self, gc, points, colors, trans):
        assert len(points) == len(colors)
        assert points.ndim == 3
        assert points.shape[1] == 3
        assert points.shape[2] == 2
        assert colors.ndim == 3
        assert colors.shape[1] == 3
        assert colors.shape[2] == 4

        shape = points.shape
        flat_points = points.reshape((shape[0] * shape[1], 2))
        flat_points = trans.transform(flat_points)
        flat_colors = colors.reshape((shape[0] * shape[1], 4))
        points_min = np.min(flat_points, axis=0) - (1 << 12)
        points_max = np.max(flat_points, axis=0) + (1 << 12)
        factor = np.ceil((2**32 - 1) / (points_max - points_min))

        xmin, ymin = points_min
        xmax, ymax = points_max

        streamarr = np.empty(shape[0] * shape[1],
                             dtype=[('flags', 'u1'), ('points', '2>u4'),
                                    ('colors', '3u1')])
        streamarr['flags'] = 0
        streamarr['points'] = (flat_points - points_min) * factor
        streamarr['colors'] = flat_colors[:, :3] * 255.0
        stream = quote_ps_string(streamarr.tobytes())

        self._pswriter.write(f"""\
gsave
<< /ShadingType 4
   /ColorSpace [/DeviceRGB]
   /BitsPerCoordinate 32
   /BitsPerComponent 8
   /BitsPerFlag 8
   /AntiAlias true
   /Decode [ {xmin:f} {xmax:f} {ymin:f} {ymax:f} 0 1 0 1 0 1 ]
   /DataSource ({stream})
>>
shfill
grestore
""")

    def _draw_ps(self, ps, gc, rgbFace, fill=True, stroke=True, command=None):
        """
        Emit the PostScript snippet 'ps' with all the attributes from 'gc'
        applied.  'ps' must consist of PostScript commands to construct a path.

        The fill and/or stroke kwargs can be set to False if the
        'ps' string already includes filling and/or stroking, in
        which case _draw_ps is just supplying properties and
        clipping.
        """
        # local variable eliminates all repeated attribute lookups
        write = self._pswriter.write
        if debugPS and command:
            write("% " + command + "\n")
        mightstroke = (gc.get_linewidth() > 0
                       and not _is_transparent(gc.get_rgb()))
        if not mightstroke:
            stroke = False
        if _is_transparent(rgbFace):
            fill = False
        hatch = gc.get_hatch()

        if mightstroke:
            self.set_linewidth(gc.get_linewidth())
            self.set_linejoin(gc.get_joinstyle())
            self.set_linecap(gc.get_capstyle())
            self.set_linedash(*gc.get_dashes())
            self.set_color(*gc.get_rgb()[:3])
        write('gsave\n')

        write(self._get_clip_cmd(gc))

        # Jochen, is the strip necessary? - this could be a honking big string
        write(ps.strip())
        write("\n")

        if fill:
            if stroke or hatch:
                write("gsave\n")
            self.set_color(*rgbFace[:3], store=False)
            write("fill\n")
            if stroke or hatch:
                write("grestore\n")

        if hatch:
            hatch_name = self.create_hatch(hatch)
            write("gsave\n")
            write("%f %f %f " % gc.get_hatch_color()[:3])
            write("%s setpattern fill grestore\n" % hatch_name)

        if stroke:
            write("stroke\n")

        write("grestore\n")
Exemplo n.º 23
0
 def mathtext_parser(self):
     return MathTextParser('SVG')
Exemplo n.º 24
0
matplotlib.use("WxAgg")
from numpy import arange, sin, pi, cos, log
from matplotlib.backends.backend_wxagg import FigureCanvasWxAgg as FigureCanvas
from matplotlib.backends.backend_wx import NavigationToolbar2Wx
from matplotlib.figure import Figure

import wx

IS_GTK = 'wxGTK' in wx.PlatformInfo
IS_WIN = 'wxMSW' in wx.PlatformInfo
IS_MAC = 'wxMac' in wx.PlatformInfo

############################################################
# This is where the "magic" happens.
from matplotlib.mathtext import MathTextParser
mathtext_parser = MathTextParser("Bitmap")


def mathtext_to_wxbitmap(s):
    ftimage, depth = mathtext_parser.parse(s, 150)
    return wx.BitmapFromBufferRGBA(ftimage.get_width(), ftimage.get_height(),
                                   ftimage.as_rgba_str())


############################################################

functions = [(r'$\sin(2 \pi x)$', lambda x: sin(2 * pi * x)),
             (r'$\frac{4}{3}\pi x^3$', lambda x: (4.0 / 3.0) * pi * x**3),
             (r'$\cos(2 \pi x)$', lambda x: cos(2 * pi * x)),
             (r'$\log(x)$', lambda x: log(x))]
Exemplo n.º 25
0
 def mathtext_parser(self):
     return MathTextParser('Cairo')