예제 #1
0
    def expose(self, widget, event):

        cr = widget.window.cairo_create()

        environ["GKS_WSTYPE"] = "142"
        pc = PyCairoContext.from_address(id(cr))
        environ['GKSconid'] = "%lu" % pc.ctx

        cr.move_to(15, 15)
        cr.set_font_size(14)
        cr.show_text("Contour Plot using Gtk ...")

        seed(0)
        xd = uniform(-2, 2, 100)
        yd = uniform(-2, 2, 100)
        zd = xd * np.exp(-xd**2 - yd**2)

        gr.setviewport(0.15, 0.95, 0.1, 0.9)
        gr.setwindow(-2, 2, -2, 2)
        gr.setspace(-0.5, 0.5, 0, 90)
        gr.setmarkersize(1)
        gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
        gr.setcharheight(0.024)
        gr.settextalign(2, 0)
        gr.settextfontprec(3, 0)

        x, y, z = gr.gridit(xd, yd, zd, 200, 200)
        h = np.linspace(-0.5, 0.5, 20)
        gr.surface(x, y, z, 5)
        gr.contour(x, y, h, z, 0)
        gr.polymarker(xd, yd)
        gr.axes(0.25, 0.25, -2, -2, 2, 2, 0.01)

        gr.updatews()
예제 #2
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def draw_landmarks(landmarks):
    if len(landmarks) == 0:
        return
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkersize(2)
    gr.setmarkercolorind(4)  # blue
    gr.polymarker(landmarks[:, 0], landmarks[:, 1])
예제 #3
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def draw_vehicle(x):
    """Draw the vehicle CM as a circle. Draw a line for the vehicle heading.
    x = [x, y, phi]
    """
    gr.setmarkertype(gr.MARKERTYPE_CIRCLE)
    gr.setmarkersize(2)
    gr.setmarkercolorind(1)  # black
    gr.polymarker([x[0]], [x[1]])
    xh = [x[0], x[0] + 5 * np.cos(x[2])]
    yh = [x[1], x[1] + 5 * np.sin(x[2])]
    gr.polyline(xh, yh)
예제 #4
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def draw_particles(xs, weights=None):
    if weights is not None:
        indices = np.argsort(np.array(weights))
        alphas = indices / len(weights)
    else:
        alphas = np.full((len(xs), ), 0.5)
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkercolorind(2)  # red
    gr.setmarkersize(0.75)
    for x, t in zip(xs, alphas):
        gr.settransparency(t)
        gr.polymarker([x[0]], [x[1]])
    gr.settransparency(1.0)
예제 #5
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def pendulum(theta, length, mass):
    l = length[0] + length[1]
    gr.clearws()
    gr.setviewport(0, 1, 0, 1)
    gr.setwindow(-l, l, -l, l)
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkercolorind(86)
    pivot = [0, 0.775]                         # draw pivot point
    gr.fillarea([-0.2, 0.2, 0.2, -0.2], [0.75, 0.75, 0.8, 0.8])
    for i in range(2):
        x = [pivot[0], pivot[0] + sin(theta[i]) * length[i]]
        y = [pivot[1], pivot[1] - cos(theta[i]) * length[i]]
        gr.polyline(x, y)                   # draw rod
        gr.setmarkersize(3 * mass[i])
        gr.polymarker([x[1]], [y[1]])       # draw bob
        pivot = [x[1], y[1]]
    gr.updatews()
    return
예제 #6
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def pendulum(theta, length, mass):
    l = length[0] + length[1]
    gr.clearws()
    gr.setviewport(0, 1, 0, 1)
    gr.setwindow(-l, l, -l, l)
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkercolorind(86)
    pivot = [0, 0.775]  # draw pivot point
    gr.fillarea([-0.2, 0.2, 0.2, -0.2], [0.75, 0.75, 0.8, 0.8])
    for i in range(2):
        x = [pivot[0], pivot[0] + sin(theta[i]) * length[i]]
        y = [pivot[1], pivot[1] - cos(theta[i]) * length[i]]
        gr.polyline(x, y)  # draw rod
        gr.setmarkersize(3 * mass[i])
        gr.polymarker([x[1]], [y[1]])  # draw bob
        pivot = [x[1], y[1]]
    gr.updatews()
    return
예제 #7
0
def pendulum(t, theta, omega, acceleration):
    gr.clearws()
    gr.setviewport(0, 1, 0, 1)

    x = [0.5, 0.5 + np.sin(theta) * 0.4]
    y = [0.8, 0.8 - np.cos(theta) * 0.4]
    # draw pivot point
    gr.fillarea([0.46, 0.54, 0.54, 0.46], [0.79, 0.79, 0.81, 0.81]),

    gr.setlinecolorind(1)
    gr.setlinewidth(2)
    gr.polyline(x, y)  # draw rod
    gr.setmarkersize(5)
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkercolorind(86)
    gr.polymarker([x[1]], [y[1]])  # draw bob
    gr.setlinecolorind(4)
    V = 0.05 * omega  # show angular velocity
    gr.drawarrow(x[1], y[1], x[1] + V * np.cos(theta),
                 y[1] + V * np.sin(theta))
    gr.setlinecolorind(2)
    A = 0.05 * acceleration  # show angular acceleration
    gr.drawarrow(x[1], y[1], x[1] + A * np.sin(theta),
                 y[1] + A * np.cos(theta))

    gr.settextfontprec(2, gr.TEXT_PRECISION_STRING)
    gr.setcharheight(0.032)
    gr.settextcolorind(1)
    gr.textext(0.05, 0.95, 'Damped Pendulum')
    gr.setcharheight(0.040)
    gr.mathtex(0.4, 0.22, '\\omega=\\dot{\\theta}')
    gr.mathtex(0.4, 0.1,
               '\\dot{\\omega}=-\\gamma\\omega-\\frac{g}{l}sin(\\theta)')
    gr.setcharheight(0.028)
    gr.textext(0.05, 0.22, 't:%7.2f' % t)
    gr.textext(0.05, 0.16, '\\theta:%7.2f' % (theta / np.pi * 180))
    gr.settextcolorind(4)
    gr.textext(0.05, 0.10, '\\omega:%7.2f' % omega)
    gr.settextcolorind(2)
    gr.textext(0.05, 0.04, 'y_{A}:%6.2f' % acceleration)

    gr.updatews()
예제 #8
0
def pendulum(t, theta, omega, acceleration):
    gr.clearws()
    gr.setviewport(0, 1, 0, 1)

    x = [0.5, 0.5 + sin(theta) * 0.4]
    y = [0.8, 0.8 - cos(theta) * 0.4]
    # draw pivot point
    gr.fillarea([0.46, 0.54, 0.54, 0.46], [0.79, 0.79, 0.81, 0.81]),

    gr.setlinecolorind(1)
    gr.setlinewidth(2)
    gr.polyline(x, y)               # draw rod
    gr.setmarkersize(5)
    gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
    gr.setmarkercolorind(86)
    gr.polymarker([x[1]], [y[1]])   # draw bob
    gr.setlinecolorind(4)
    V = 0.05 * omega                # show angular velocity
    gr.drawarrow(x[1], y[1], x[1] + V*cos(theta), y[1] + V*sin(theta))
    gr.setlinecolorind(2)
    A = 0.05 * acceleration         # show angular acceleration
    gr.drawarrow(x[1], y[1], x[1] + A*sin(theta), y[1] + A*cos(theta))

    gr.settextfontprec(2, gr.TEXT_PRECISION_STRING)
    gr.setcharheight(0.032)
    gr.settextcolorind(1)
    gr.textext(0.05, 0.95, 'Damped Pendulum')
    gr.setcharheight(0.040)
    gr.mathtex(0.4, 0.22, '\\omega=\\dot{\\theta}')
    gr.mathtex(0.4, 0.1, '\\dot{\\omega}=-\\gamma\\omega-\\frac{g}{l}sin(\\theta)')
    gr.setcharheight(0.028)
    gr.textext(0.05, 0.22, 't:%7.2f' % t)
    gr.textext(0.05, 0.16, '\\theta:%7.2f' % (theta / pi * 180))
    gr.settextcolorind(4)
    gr.textext(0.05, 0.10, '\\omega:%7.2f' % omega)
    gr.settextcolorind(2)
    gr.textext(0.05, 0.04, 'y_{A}:%6.2f' % acceleration)

    gr.updatews()
예제 #9
0
파일: griddata.py 프로젝트: vleo/gr
"""
Create a contour plot of irregular distributed data
"""

from numpy.random import uniform, seed
import numpy as np
import gr

seed(0)
xd = uniform(-2, 2, 100)
yd = uniform(-2, 2, 100)
zd = xd * np.exp(-xd ** 2 - yd ** 2)

gr.setviewport(0.1, 0.95, 0.1, 0.95)
gr.setwindow(-2, 2, -2, 2)
gr.setspace(-0.5, 0.5, 0, 90)
gr.setmarkersize(1)
gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
gr.setcharheight(0.024)
gr.settextalign(2, 0)
gr.settextfontprec(3, 0)

x, y, z = gr.gridit(xd, yd, zd, 200, 200)
h = np.linspace(-0.5, 0.5, 20)
gr.surface(x, y, z, 5)
gr.contour(x, y, h, z, 0)
gr.polymarker(xd, yd)
gr.axes(0.25, 0.25, -2, -2, 2, 2, 0.01)

gr.updatews()
예제 #10
0
파일: mlab.py 프로젝트: j-fu/gr
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()
예제 #11
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#!/usr/bin/env python
"""
Create a contour plot of irregular distributed data
"""

import numpy as np
import gr

np.random.seed(0)
xd = np.random.uniform(-2, 2, 100)
yd = np.random.uniform(-2, 2, 100)
zd = xd * np.exp(-xd**2 - yd**2)

gr.setviewport(0.1, 0.95, 0.1, 0.95)
gr.setwindow(-2, 2, -2, 2)
gr.setspace(-0.5, 0.5, 0, 90)
gr.setmarkersize(1)
gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
gr.setcharheight(0.024)
gr.settextalign(2, 0)
gr.settextfontprec(3, 0)

x, y, z = gr.gridit(xd, yd, zd, 200, 200)
h = np.linspace(-0.5, 0.5, 20)
gr.surface(x, y, z, 5)
gr.contour(x, y, h, z, 0)
gr.polymarker(xd, yd)
gr.axes(0.25, 0.25, -2, -2, 2, 2, 0.01)

gr.updatews()
예제 #12
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 def drawGR(self):
     gr.setmarkersize(self.GR_MARKER_SIZE)
     MaskedPlotCurve.drawGR(self)
     for dep in self.dependent:
         if dep.visible:
             dep.drawGR()
예제 #13
0
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()
예제 #14
0
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()
예제 #15
0
파일: particles.py 프로젝트: j-fu/gr
    return a

np.random.seed(0)
a = np.empty([2, N, 2], dtype=float)
a[0, :] = -0.5 + np.random.random((N, 2))      # positions
a[1, :] = -0.5 + np.random.random((N, 2))      # velocities
a[0, :] *= (4 - 2*size)
dt = 1. / 30

step_numba = jit('f8[:,:,:](f8, f8, f8[:,:,:])')(step)

gr.setwindow(-2, 2, -2, 2)
gr.setviewport(0, 1, 0, 1)
gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
gr.setmarkersize(1.0)

start = time.time()
t0 = start

n = 0
t = 0
worker = 'CPython'

while t < 6:

    if t > 3:
        if worker == 'CPython':
            t0 = now
            n = 0
        a = step_numba(dt, size, a)
예제 #16
0
파일: __init__.py 프로젝트: ess-dmsc/nicos
 def changeMarkerSize(self, size):
     gr.setmarkersize(size)
예제 #17
0
파일: plots.py 프로젝트: ess-dmsc/nicos
 def drawGR(self):
     gr.setmarkersize(self._markersize)
     PlotCurve.drawGR(self)
예제 #18
0
    return a


np.random.seed(0)
a = np.empty([2, N, 2], dtype=float)
a[0, :] = -0.5 + np.random.random((N, 2))  # positions
a[1, :] = -0.5 + np.random.random((N, 2))  # velocities
a[0, :] *= (4 - 2 * size)
dt = 1. / 30

step_numba = jit('f8[:,:,:](f8, f8, f8[:,:,:])')(step)

gr.setwindow(-2, 2, -2, 2)
gr.setviewport(0, 1, 0, 1)
gr.setmarkertype(gr.MARKERTYPE_SOLID_CIRCLE)
gr.setmarkersize(1.0)

start = time.time()
t0 = start

n = 0
t = 0
worker = 'CPython'

while t < 6:

    if t > 3:
        if worker == 'CPython':
            t0 = now
            n = 0
        a = step_numba(dt, size, a)