def draw_path(self, gc, path, transform, rgbFace=None): path = transform.transform_path(path) points = path.vertices codes = path.codes bbox = gc.get_clip_rectangle() if bbox is not None: x, y, w, h = bbox.bounds clrt = np.array([x, x + w, y, y + h]) else: clrt = np.array([0, self.width, 0, self.height]) gr.setviewport(*clrt / self.size) gr.setwindow(*clrt) if rgbFace is not None and len(points) > 2: color = gr.inqcolorfromrgb(rgbFace[0], rgbFace[1], rgbFace[2]) gr.settransparency(rgbFace[3]) gr.setcolorrep(color, rgbFace[0], rgbFace[1], rgbFace[2]) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(color) gr.drawpath(points, codes, fill=True) lw = gc.get_linewidth() if lw != 0: rgba = gc.get_rgb()[:4] color = gr.inqcolorfromrgb(rgba[0], rgba[1], rgba[2]) gr.settransparency(rgba[3]) gr.setcolorrep(color, rgba[0], rgba[1], rgba[2]) if isinstance(gc._linestyle, str): gr.setlinetype(linetype[gc._linestyle]) gr.setlinewidth(lw) gr.setlinecolorind(color) gr.drawpath(points, codes, fill=False)
def draw_path(self, gc, path, transform, rgbFace=None): path = transform.transform_path(path) points = path.vertices codes = path.codes bbox = gc.get_clip_rectangle() if bbox is not None and not np.any(np.isnan(bbox.bounds)): x, y, w, h = bbox.bounds clrt = np.array([x, x + w, y, y + h]) else: clrt = np.array([0, self.width, 0, self.height]) gr.setviewport(*clrt / self.size) gr.setwindow(*clrt) if rgbFace is not None and len(points) > 2: color = gr.inqcolorfromrgb(rgbFace[0], rgbFace[1], rgbFace[2]) gr.settransparency(rgbFace[3]) gr.setcolorrep(color, rgbFace[0], rgbFace[1], rgbFace[2]) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(color) gr.drawpath(points, codes, fill=True) lw = gc.get_linewidth() if lw != 0: rgba = gc.get_rgb()[:4] color = gr.inqcolorfromrgb(rgba[0], rgba[1], rgba[2]) gr.settransparency(rgba[3]) gr.setcolorrep(color, rgba[0], rgba[1], rgba[2]) if isinstance(gc._linestyle, str): gr.setlinetype(linetype[gc._linestyle]) gr.setlinewidth(lw) gr.setlinecolorind(color) gr.drawpath(points, codes, fill=False)
def draw_ellipse(ell, alpha=1.0, color=1): gr.setfillintstyle(1) # solid (default is no fill) gr.setfillcolorind(color) gr.settransparency(alpha) gr.setlinewidth(2) # gr.polyline(ell[0, :], ell[1, :]) gr.fillarea(ell[0, :], ell[1, :]) gr.settransparency(1.0)
def _set_viewport(kind, subplot): global _plt metric_width, metric_height, pixel_width, pixel_height = gr.inqdspsize() if 'figsize' in _plt.kwargs: horizontal_pixels_per_inch = pixel_width * 0.0254 / metric_width vertical_pixels_per_inch = pixel_height * 0.0254 / metric_height width = _plt.kwargs['figsize'][0] * horizontal_pixels_per_inch height = _plt.kwargs['figsize'][1] * vertical_pixels_per_inch else: width, height = _plt.kwargs['size'] viewport = [0, 0, 0, 0] vp = subplot[:] if width > height: aspect_ratio = height/width metric_size = metric_width * width / pixel_width gr.setwsviewport(0, metric_size, 0, metric_size*aspect_ratio) gr.setwswindow(0, 1, 0, aspect_ratio) vp[2] *= aspect_ratio vp[3] *= aspect_ratio else: aspect_ratio = width/ height metric_size = metric_height * height / pixel_height gr.setwsviewport(0, metric_size * aspect_ratio, 0, metric_size) gr.setwswindow(0, aspect_ratio, 0, 1) vp[0] *= aspect_ratio vp[1] *= aspect_ratio viewport[0] = vp[0] + 0.125 * (vp[1]-vp[0]) viewport[1] = vp[0] + 0.925 * (vp[1]-vp[0]) viewport[2] = vp[2] + 0.125 * (vp[3]-vp[2]) viewport[3] = vp[2] + 0.925 * (vp[3]-vp[2]) if width > height: viewport[2] += (1 - (subplot[3] - subplot[2])**2) * 0.02 if kind in ('wireframe', 'surface', 'plot3', 'scatter3'): viewport[1] -= 0.0525 if kind in ('contour', 'contourf', 'surface'): viewport[1] -= 0.1 gr.setviewport(*viewport) _plt.kwargs['viewport'] = viewport _plt.kwargs['vp'] = vp _plt.kwargs['ratio'] = aspect_ratio if 'backgroundcolor' in _plt.kwargs: gr.savestate() gr.selntran(0) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(_plt.kwargs['backgroundcolor']) if width > height: gr.fillrect(subplot[0], subplot[1], subplot[2] * aspect_ratio, subplot[3] * aspect_ratio) else: gr.fillrect(subplot[0] * aspect_ratio, subplot[1] * aspect_ratio, subplot[2], subplot[3]) gr.selntran(1) gr.restorestate()
def _draw_legend(): global _plt viewport = _plt.kwargs['viewport'] num_labels = len(_plt.kwargs['labels']) location = _plt.kwargs.get('location', 1) gr.savestate() gr.selntran(0) gr.setscale(0) w = 0 for label in _plt.kwargs['labels']: tbx, tby = gr.inqtextext(0, 0, label) w = max(w, tbx[2]) num_lines = len(_plt.args) h = (num_lines + 1) * 0.03 if location in (8, 9, 10): px = 0.5 * (viewport[0] + viewport[1] - w) elif location in (2, 3, 6): px = viewport[0] + 0.11 else: px = viewport[1] - 0.05 - w if location in (5, 6, 7, 10): py = 0.5 * (viewport[2] + viewport[3] + h) - 0.03 elif location in (3, 4, 8): py = viewport[2] + h else: py = viewport[3] - 0.06 gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(0) gr.fillrect(px - 0.08, px + w + 0.02, py + 0.03, py - 0.03 * num_lines) gr.setlinetype(gr.LINETYPE_SOLID) gr.setlinecolorind(1) gr.setlinewidth(1) gr.drawrect(px - 0.08, px + w + 0.02, py + 0.03, py - 0.03 * num_lines) i = 0 gr.uselinespec(" ") for (x, y, z, c, spec) in _plt.args: gr.savestate() mask = gr.uselinespec(spec) if mask in (0, 1, 3, 4, 5): gr.polyline([px - 0.07, px - 0.01], [py, py]) if mask & 2: gr.polymarker([px - 0.06, px - 0.02], [py, py]) gr.restorestate() gr.settextalign(gr.TEXT_HALIGN_LEFT, gr.TEXT_VALIGN_HALF) if i < num_labels: gr.textext(px, py, _plt.kwargs['labels'][i]) i += 1 py -= 0.03 gr.selntran(1) gr.restorestate()
def draw(self, wsviewport=None): if self.xvalues is not None and self.widths is not None: maxidx = np.argmax(self.xvalues) rangex = (self.xvalues.min(), self.xvalues[maxidx] + self.widths[maxidx]) else: rangex = (0.0, 100.0) if self.yvalues is not None: rangey = gr.adjustrange(0.0, self.yvalues.max()) else: rangey = (0.0, 8.0) if wsviewport is None: gr.setwsviewport(0, self.mwidth, 0, self.mheight) else: gr.setwsviewport(*wsviewport) gr.setwswindow(0, self.sizex, 0, self.sizey) gr.setviewport(0.075 * self.sizex, 0.95 * self.sizex, 0.075 * self.sizey, 0.95 * self.sizey) gr.setwindow(rangex[0], rangex[1], rangey[0], rangey[1]) gr.setcharheight(0.012) gr.setfillintstyle(1) gr.setfillcolorind(0) gr.fillrect(rangex[0], rangex[1], rangey[0], rangey[1]) if self.xvalues is not None and self.yvalues is not None \ and self.widths is not None: gr.setfillintstyle(1) gr.setfillcolorind(2) for i in range(self.xvalues.size): gr.fillrect(self.xvalues[i], self.xvalues[i] + self.widths[i] * 0.8, 0.0, self.yvalues[i]) else: gr.text(0.45 * self.sizex, 0.5 * self.sizey, "no data") gr.setlinecolorind(1) xtick = floor(0.02 * (rangex[1] - rangey[0]) * 100.0) / 100.0 ytick = floor(0.04 * (rangey[1] - rangey[0]) * 50.0) / 50.0 gr.axes(xtick, ytick, rangex[0], rangey[0], 10, 5, 0.0075) gr.axes(xtick, ytick, rangex[1], rangey[1], -10, -5, -0.0075) if self.title is not None: gr.text(0.8 * self.sizex, 0.9 * self.sizey, self.title)
def _draw_legend(): global _plt viewport = _plt.kwargs['viewport'] num_labels = len(_plt.kwargs['labels']) gr.savestate() gr.selntran(0) gr.setscale(0) w = 0 for label in _plt.kwargs['labels']: tbx, tby = gr.inqtextext(0, 0, label) w = max(w, tbx[2]) px = viewport[1] - 0.05 - w py = viewport[3] - 0.06 gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(0) gr.fillrect(px - 0.08, px + w + 0.02, py + 0.03, py - 0.03 * num_labels) gr.setlinetype(1) gr.setlinecolorind(1) gr.setlinewidth(1) gr.drawrect(px - 0.08, px + w + 0.02, py + 0.03, py - 0.03 * num_labels) i = 0 gr.uselinespec(" ") for (x, y, z, c, spec) in _plt.args: gr.savestate() mask = gr.uselinespec(spec) if mask in (0, 1, 3, 4, 5): gr.polyline([px - 0.07, px - 0.01], [py, py]) if mask & 2: gr.polymarker([px - 0.06, px - 0.02], [py, py]) gr.restorestate() gr.settextalign(gr.TEXT_HALIGN_LEFT, gr.TEXT_VALIGN_HALF) if i < num_labels: gr.textext(px, py, _plt.kwargs['labels'][i]) i += 1 py -= 0.03 gr.selntran(1) gr.restorestate()
def draw(self, wsviewport=None): if self.xvalues is not None: rangex = (self.xvalues.min(), self.xvalues.max()) else: rangex = (0, 10) if self.yvalues is not None: rangey = gr.adjustrange(self.yvalues.min(), self.yvalues.max()) else: rangey = (0, 4) if wsviewport is None: gr.setwsviewport(0, self.mwidth, 0, self.mheight) else: gr.setwsviewport(*wsviewport) gr.setwswindow(0, self.sizex, 0, self.sizey) gr.setviewport(0.075 * self.sizex, 0.95 * self.sizex, 0.075 * self.sizey, 0.95 * self.sizey) gr.setwindow(rangex[0], rangex[1], rangey[0], rangey[1]) gr.setcharheight(0.012) gr.setfillintstyle(1) gr.setfillcolorind(0) gr.fillrect(rangex[0], rangex[1], rangey[0], rangey[1]) if self.xvalues is not None and self.yvalues is not None: gr.setlinecolorind(2) gr.polyline(self.xvalues, self.yvalues) else: gr.text(0.4 * self.sizex, 0.5 * self.sizey, "no elements selected") gr.setlinecolorind(1) gr.axes(0.2, 0.2, rangex[0], rangey[0], 5, 5, 0.0075) gr.axes(0.2, 0.2, rangex[1], rangey[1], -5, -5, -0.0075) if self.title is not None: gr.text(0.8 * self.sizex, 0.9 * self.sizey, self.title)
import os, wave, pyaudio import numpy import gr SAMPLES = 2048 wf = wave.open(os.path.join(os.path.dirname(os.path.realpath(__file__)), 'Monty_Python.wav'), 'rb') pa = pyaudio.PyAudio() stream = pa.open(format=pa.get_format_from_width(wf.getsampwidth()), channels=wf.getnchannels(), rate=wf.getframerate(), output=True) gr.setwindow(0, SAMPLES, -30000, 30000) gr.setviewport(0.05, 0.95, 0.05, 0.95) gr.setlinecolorind(218) gr.setfillintstyle(1) gr.setfillcolorind(208) data = wf.readframes(SAMPLES) while data != '' and len(data) == SAMPLES * wf.getsampwidth(): stream.write(data) amplitudes = numpy.fromstring(data, dtype=numpy.short) power = abs(numpy.fft.fft(amplitudes / 512.0))[:SAMPLES/2:2] - 30000 gr.clearws() gr.fillrect(0, SAMPLES, -30000, 30000) gr.grid(40, 1200, 0, 0, 5, 5) gr.polyline(range(SAMPLES)[0::4], amplitudes[0::4]) gr.polyline(range(SAMPLES)[0::4], power) gr.updatews()
SAMPLES = 2048 wf = wave.open( os.path.join(os.path.dirname(os.path.realpath(__file__)), 'Monty_Python.wav'), 'rb') pa = pyaudio.PyAudio() stream = pa.open(format=pa.get_format_from_width(wf.getsampwidth()), channels=wf.getnchannels(), rate=wf.getframerate(), output=True) gr.setwindow(0, SAMPLES, -30000, 30000) gr.setviewport(0.05, 0.95, 0.05, 0.95) gr.setlinecolorind(218) gr.setfillintstyle(1) gr.setfillcolorind(208) data = wf.readframes(SAMPLES) while data != '' and len(data) == SAMPLES * wf.getsampwidth(): stream.write(data) amplitudes = numpy.fromstring(data, dtype=numpy.short) power = abs(scipy.fftpack.fft(amplitudes / 512.0))[:SAMPLES / 2:2] - 30000 gr.clearws() gr.fillrect(0, SAMPLES, -30000, 30000) gr.grid(40, 1200, 0, 0, 5, 5) gr.polyline(range(SAMPLES)[0::4], amplitudes[0::4]) gr.polyline(range(SAMPLES)[0::4], power) gr.updatews()
def _set_viewport(kind, subplot): global _plt metric_width, metric_height, pixel_width, pixel_height = gr.inqdspsize() if 'figsize' in _plt.kwargs: horizontal_pixels_per_inch = pixel_width * 0.0254 / metric_width vertical_pixels_per_inch = pixel_height * 0.0254 / metric_height width = _plt.kwargs['figsize'][0] * horizontal_pixels_per_inch height = _plt.kwargs['figsize'][1] * vertical_pixels_per_inch else: dpi = pixel_width / metric_width * 0.0254 if dpi > 200: width, height = tuple(x * dpi / 100 for x in _plt.kwargs['size']) else: width, height = _plt.kwargs['size'] viewport = [0, 0, 0, 0] vp = subplot[:] if width > height: aspect_ratio = height/width metric_size = metric_width * width / pixel_width gr.setwsviewport(0, metric_size, 0, metric_size*aspect_ratio) gr.setwswindow(0, 1, 0, aspect_ratio) vp[2] *= aspect_ratio vp[3] *= aspect_ratio else: aspect_ratio = width/ height metric_size = metric_height * height / pixel_height gr.setwsviewport(0, metric_size * aspect_ratio, 0, metric_size) gr.setwswindow(0, aspect_ratio, 0, 1) vp[0] *= aspect_ratio vp[1] *= aspect_ratio viewport[0] = vp[0] + 0.125 * (vp[1]-vp[0]) viewport[1] = vp[0] + 0.925 * (vp[1]-vp[0]) viewport[2] = vp[2] + 0.125 * (vp[3]-vp[2]) viewport[3] = vp[2] + 0.925 * (vp[3]-vp[2]) if width > height: viewport[2] += (1 - (subplot[3] - subplot[2])**2) * 0.02 if kind in ('wireframe', 'surface', 'plot3', 'scatter3', 'trisurf'): viewport[1] -= 0.0525 if kind in ('contour', 'contourf', 'surface', 'trisurf', 'heatmap', 'hexbin'): viewport[1] -= 0.1 gr.setviewport(*viewport) _plt.kwargs['viewport'] = viewport _plt.kwargs['vp'] = vp _plt.kwargs['ratio'] = aspect_ratio if 'backgroundcolor' in _plt.kwargs: gr.savestate() gr.selntran(0) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.setfillcolorind(_plt.kwargs['backgroundcolor']) if width > height: gr.fillrect(subplot[0], subplot[1], subplot[2] * aspect_ratio, subplot[3] * aspect_ratio) else: gr.fillrect(subplot[0] * aspect_ratio, subplot[1] * aspect_ratio, subplot[2], subplot[3]) gr.selntran(1) gr.restorestate() if kind == 'polar': x_min, x_max, y_min, y_max = viewport x_center = 0.5 * (x_min + x_max) y_center = 0.5 * (y_min + y_max) r = 0.5 * min(x_max - x_min, y_max - y_min) gr.setviewport(x_center - r, x_center + r, y_center - r, y_center + r)
def _plot_data(**kwargs): global _plt _plt.kwargs.update(kwargs) if not _plt.args: return kind = _plt.kwargs.get('kind', 'line') if _plt.kwargs['clear']: gr.clearws() if kind in ('imshow', 'isosurface'): _set_viewport(kind, _plt.kwargs['subplot']) elif not _plt.kwargs['ax']: _set_viewport(kind, _plt.kwargs['subplot']) _set_window(kind) if kind == 'polar': _draw_polar_axes() else: _draw_axes(kind) gr.setcolormap(_plt.kwargs.get('colormap', gr.COLORMAP_COOLWARM)) gr.uselinespec(" ") for x, y, z, c, spec in _plt.args: gr.savestate() if 'alpha' in _plt.kwargs: gr.settransparency(_plt.kwargs['alpha']) if kind == 'line': mask = gr.uselinespec(spec) if mask in (0, 1, 3, 4, 5): gr.polyline(x, y) if mask & 2: gr.polymarker(x, y) elif kind == 'scatter': gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) if z is not None or c is not None: if c is not None: c_min = c.min() c_ptp = c.ptp() for i in range(len(x)): if z is not None: gr.setmarkersize(z[i] / 100.0) if c is not None: c_index = 1000 + int(255 * (c[i]-c_min)/c_ptp) gr.setmarkercolorind(c_index) gr.polymarker([x[i]], [y[i]]) else: gr.polymarker(x, y) elif kind == 'stem': gr.setlinecolorind(1) gr.polyline(_plt.kwargs['window'][:2], [0, 0]) gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) gr.uselinespec(spec) for xi, yi in zip(x, y): gr.polyline([xi, xi], [0, yi]) gr.polymarker(x, y) elif kind == 'hist': y_min = _plt.kwargs['window'][2] for i in range(1, len(y)+1): gr.setfillcolorind(989) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.fillrect(x[i-1], x[i], y_min, y[i-1]) gr.setfillcolorind(1) gr.setfillintstyle(gr.INTSTYLE_HOLLOW) gr.fillrect(x[i-1], x[i], y_min, y[i-1]) elif kind == 'contour': z_min, z_max = _plt.kwargs['zrange'] gr.setspace(z_min, z_max, 0, 90) h = [z_min + i/19*(z_max-z_min) for i in range(20)] if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) gr.contour(x, y, h, z, 1000) _colorbar(0, 20) elif kind == 'contourf': z_min, z_max = _plt.kwargs['zrange'] gr.setspace(z_min, z_max, 0, 90) if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = (200, 200) if _plt.kwargs['scale'] & gr.OPTION_Z_LOG != 0: z = np.log(z) gr.surface(x, y, z, gr.OPTION_CELL_ARRAY) _colorbar() elif kind == 'hexbin': nbins = _plt.kwargs.get('nbins', 40) cntmax = gr.hexbin(x, y, nbins) if cntmax > 0: _plt.kwargs['zrange'] = (0, cntmax) _colorbar() elif kind == 'heatmap': x_min, x_max, y_min, y_max = _plt.kwargs['window'] width, height = z.shape cmap = _colormap() icmap = np.zeros(256, np.uint32) for i in range(256): r, g, b, a = cmap[i] icmap[i] = (int(r*255) << 0) + (int(g*255) << 8) + (int(b*255) << 16) + (int(a*255) << 24) z_range = np.ptp(z) if z_range > 0: data = (z - np.min(z)) / z_range * 255 else: data = np.zeros((width, height)) rgba = np.zeros((width, height), np.uint32) for x in range(width): for y in range(height): rgba[x, y] = icmap[int(data[x, y])] gr.drawimage(x_min, x_max, y_min, y_max, width, height, rgba) _colorbar() elif kind == 'wireframe': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 50, 50) gr.setfillcolorind(0) z.shape = np.prod(z.shape) gr.surface(x, y, z, gr.OPTION_FILLED_MESH) _draw_axes(kind, 2) elif kind == 'surface': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) if _plt.kwargs.get('accelerate', True): gr3.clear() gr3.surface(x, y, z, gr.OPTION_COLORED_MESH) else: gr.surface(x, y, z, gr.OPTION_COLORED_MESH) _draw_axes(kind, 2) _colorbar(0.05) elif kind == 'plot3': gr.polyline3d(x, y, z) _draw_axes(kind, 2) elif kind == 'scatter3': gr.polymarker3d(x, y, z) _draw_axes(kind, 2) elif kind == 'imshow': _plot_img(z) elif kind == 'isosurface': _plot_iso(z) elif kind == 'polar': gr.uselinespec(spec) _plot_polar(x, y) elif kind == 'trisurf': gr.trisurface(x, y, z) _draw_axes(kind, 2) _colorbar(0.05) gr.restorestate() if kind in ('line', 'scatter', 'stem') and 'labels' in _plt.kwargs: _draw_legend() if _plt.kwargs['update']: gr.updatews() if gr.isinline(): return gr.show()
def _plot_data(**kwargs): global _plt _plt.kwargs.update(kwargs) if not _plt.args: return kind = _plt.kwargs.get('kind', 'line') if _plt.kwargs['clear']: gr.clearws() if kind in ('imshow', 'isosurface'): _set_viewport(kind, _plt.kwargs['subplot']) elif not _plt.kwargs['ax']: _set_viewport(kind, _plt.kwargs['subplot']) _set_window(kind) _draw_axes(kind) gr.setcolormap(_plt.kwargs.get('colormap', gr.COLORMAP_COOLWARM)) gr.uselinespec(" ") for x, y, z, c, spec in _plt.args: gr.savestate() if 'alpha' in _plt.kwargs: gr.settransparency(_plt.kwargs['alpha']) if kind == 'line': mask = gr.uselinespec(spec) if mask in (0, 1, 3, 4, 5): gr.polyline(x, y) if mask & 2: gr.polymarker(x, y) elif kind == 'scatter': gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) if z is not None or c is not None: if c is not None: c_min = c.min() c_ptp = c.ptp() for i in range(len(x)): if z is not None: gr.setmarkersize(z[i] / 100.0) if c is not None: c_index = 1000 + int(255 * (c[i]-c_min)/c_ptp) gr.setmarkercolorind(c_index) gr.polymarker([x[i]], [y[i]]) else: gr.polymarker(x, y) elif kind == 'stem': gr.setlinecolorind(1) gr.polyline(_plt.kwargs['window'][:2], [0, 0]) gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) gr.uselinespec(spec) for xi, yi in zip(x, y): gr.polyline([xi, xi], [0, yi]) gr.polymarker(x, y) elif kind == 'hist': y_min = _plt.kwargs['window'][2] for i in range(1, len(y)): gr.setfillcolorind(989) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.fillrect(x[i-1], x[i], y_min, y[i]) gr.setfillcolorind(1) gr.setfillintstyle(gr.INTSTYLE_HOLLOW) gr.fillrect(x[i-1], x[i], y_min, y[i]) elif kind == 'contour': z_min, z_max = _plt.kwargs['zrange'] gr.setspace(z_min, z_max, 0, 90) h = [z_min + i/19*(z_max-z_min) for i in range(20)] if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) gr.contour(x, y, h, z, 1000) _colorbar(0, 20) elif kind == 'contourf': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = (200, 200) if _plt.kwargs['scale'] & gr.OPTION_Z_LOG != 0: z = np.log(z) width, height = z.shape data = np.array(1000+(z-z.min()) / z.ptp() * 255, np.int32) x_min, x_max = _plt.kwargs['xrange'] y_min, y_max = _plt.kwargs['yrange'] gr.cellarray(x_min, x_max, y_max, y_min, width, height, data) _colorbar() elif kind == 'wireframe': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 50, 50) gr.setfillcolorind(0) z.shape = np.prod(z.shape) gr.surface(x, y, z, gr.OPTION_FILLED_MESH) _draw_axes(kind, 2) elif kind == 'surface': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) if _plt.kwargs.get('accelerate', True): gr3.surface(x, y, z, gr.OPTION_COLORED_MESH) else: gr.surface(x, y, z, gr.OPTION_COLORED_MESH) _draw_axes(kind, 2) _colorbar(0.05) elif kind == 'plot3': gr.polyline3d(x, y, z) _draw_axes(kind, 2) elif kind == 'scatter3': gr.polymarker3d(x, y, z) _draw_axes(kind, 2) elif kind == 'imshow': _plot_img(z) elif kind == 'isosurface': _plot_iso(z) gr.restorestate() if kind in ('line', 'scatter', 'stem') and 'labels' in _plt.kwargs: _draw_legend() if _plt.kwargs['update']: gr.updatews() if gr.isinline(): return gr.show()
def _plot_data(**kwargs): global _plt _plt.kwargs.update(kwargs) if not _plt.args: return kind = _plt.kwargs.get('kind', 'line') if _plt.kwargs['clear']: gr.clearws() if kind in ('imshow', 'isosurface'): _set_viewport(kind, _plt.kwargs['subplot']) elif not _plt.kwargs['ax']: _set_viewport(kind, _plt.kwargs['subplot']) _set_window(kind) if kind == 'polar': _draw_polar_axes() else: _draw_axes(kind) if 'cmap' in _plt.kwargs: warnings.warn('The parameter "cmap" has been replaced by "colormap". The value of "cmap" will be ignored.', stacklevel=3) colormap = _plt.kwargs.get('colormap', gr.COLORMAP_VIRIDIS) if colormap is not None: gr.setcolormap(colormap) gr.uselinespec(" ") for x, y, z, c, spec in _plt.args: gr.savestate() if 'alpha' in _plt.kwargs: gr.settransparency(_plt.kwargs['alpha']) if kind == 'line': mask = gr.uselinespec(spec) if mask in (0, 1, 3, 4, 5): gr.polyline(x, y) if mask & 2: gr.polymarker(x, y) elif kind == 'scatter': gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) if z is not None or c is not None: if c is not None: c_min = c.min() c_ptp = c.ptp() for i in range(len(x)): if z is not None: gr.setmarkersize(z[i] / 100.0) if c is not None: c_index = 1000 + int(255 * (c[i]-c_min)/c_ptp) gr.setmarkercolorind(c_index) gr.polymarker([x[i]], [y[i]]) else: gr.polymarker(x, y) elif kind == 'stem': gr.setlinecolorind(1) gr.polyline(_plt.kwargs['window'][:2], [0, 0]) gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE) gr.uselinespec(spec) for xi, yi in zip(x, y): gr.polyline([xi, xi], [0, yi]) gr.polymarker(x, y) elif kind == 'hist': y_min = _plt.kwargs['window'][2] for i in range(1, len(y)+1): gr.setfillcolorind(989) gr.setfillintstyle(gr.INTSTYLE_SOLID) gr.fillrect(x[i-1], x[i], y_min, y[i-1]) gr.setfillcolorind(1) gr.setfillintstyle(gr.INTSTYLE_HOLLOW) gr.fillrect(x[i-1], x[i], y_min, y[i-1]) elif kind == 'contour': z_min, z_max = _plt.kwargs['zrange'] gr.setspace(z_min, z_max, 0, 90) h = [z_min + i/19*(z_max-z_min) for i in range(20)] if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) gr.contour(x, y, h, z, 1000) _colorbar(0, 20) elif kind == 'contourf': z_min, z_max = _plt.kwargs['zrange'] gr.setspace(z_min, z_max, 0, 90) scale = _plt.kwargs['scale'] gr.setscale(scale) if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = (200, 200) gr.surface(x, y, z, gr.OPTION_CELL_ARRAY) _colorbar() elif kind == 'hexbin': nbins = _plt.kwargs.get('nbins', 40) cntmax = gr.hexbin(x, y, nbins) if cntmax > 0: _plt.kwargs['zrange'] = (0, cntmax) _colorbar() elif kind == 'heatmap': x_min, x_max, y_min, y_max = _plt.kwargs['window'] width, height = z.shape cmap = _colormap() icmap = np.zeros(256, np.uint32) for i in range(256): r, g, b, a = cmap[i] icmap[i] = (int(r*255) << 0) + (int(g*255) << 8) + (int(b*255) << 16) + (int(a*255) << 24) z_min, z_max = _plt.kwargs.get('zlim', (np.min(z), np.max(z))) if z_max < z_min: z_max, z_min = z_min, z_max if z_max > z_min: data = (z - z_min) / (z_max - z_min) * 255 else: data = np.zeros((width, height)) rgba = np.zeros((width, height), np.uint32) for x in range(width): for y in range(height): rgba[x, y] = icmap[int(data[x, y])] gr.drawimage(x_min, x_max, y_min, y_max, width, height, rgba) _colorbar() elif kind == 'wireframe': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 50, 50) gr.setfillcolorind(0) z.shape = np.prod(z.shape) gr.surface(x, y, z, gr.OPTION_FILLED_MESH) _draw_axes(kind, 2) elif kind == 'surface': if x.shape == y.shape == z.shape: x, y, z = gr.gridit(x, y, z, 200, 200) z.shape = np.prod(z.shape) if _plt.kwargs.get('accelerate', True): gr3.clear() gr3.surface(x, y, z, gr.OPTION_COLORED_MESH) else: gr.surface(x, y, z, gr.OPTION_COLORED_MESH) _draw_axes(kind, 2) _colorbar(0.05) elif kind == 'plot3': gr.polyline3d(x, y, z) _draw_axes(kind, 2) elif kind == 'scatter3': gr.polymarker3d(x, y, z) _draw_axes(kind, 2) elif kind == 'imshow': _plot_img(z) elif kind == 'isosurface': _plot_iso(z) elif kind == 'polar': gr.uselinespec(spec) _plot_polar(x, y) elif kind == 'trisurf': gr.trisurface(x, y, z) _draw_axes(kind, 2) _colorbar(0.05) elif kind == 'tricont': zmin, zmax = _plt.kwargs['zrange'] levels = np.linspace(zmin, zmax, 20) gr.tricontour(x, y, z, levels) gr.restorestate() if kind in ('line', 'scatter', 'stem') and 'labels' in _plt.kwargs: _draw_legend() if _plt.kwargs['update']: gr.updatews() if gr.isinline(): return gr.show()