def draw_axes(
x_tick_spacing,
y_tick_spacing,
x_origin,
y_origin,
x_major=5,
y_major=5,
x_title="x",
y_title="y",
):
"""
Parameters
----------
x_tick_spacing, y_tick_spacing : float
Distance between ticks in data units
x_origin, y_origin : float
Location of plot origin in data units
x_major, y_major : int
Every x_major-th tick will be a labeled major tick on the x axis. Same for y.
The ticks in between are unlabeled minor ticks.
"""
gr.setlinewidth(1)
gr.axes(x_tick_spacing, y_tick_spacing, x_origin, y_origin, x_major,
y_major, -0.01)
midway = 0.54
gr.textext(midway, 0.02, "x")
gr.setcharup(-1, 0) # Vertical, end-up
gr.textext(0.05, midway, "y")
gr.setcharup(0, 1) # Back to horizontal
def draw_axes(tick_spacing, xmin, ymin):
gr.axes(tick_spacing, tick_spacing, xmin, ymin, 5, 5, -0.01)
midway = 0.54
gr.textext(midway, 0.02, 'x')
gr.setcharup(-1, 0) # Vertical, end-up
gr.textext(0.05, midway, 'y')
gr.setcharup(0, 1) # Back to horizontal
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()
def _draw_axes(kind, pass_=1):
global _plt
viewport = _plt.kwargs['viewport']
vp = _plt.kwargs['vp']
x_tick, x_org, x_major_count = _plt.kwargs['xaxis']
y_tick, y_org, y_major_count = _plt.kwargs['yaxis']
gr.setlinecolorind(1)
gr.setlinewidth(1)
diag = ((viewport[1]-viewport[0])**2 + (viewport[3]-viewport[2])**2)**0.5
charheight = max(0.018 * diag, 0.012)
gr.setcharheight(charheight)
ticksize = 0.0075 * diag
if kind in ('wireframe', 'surface', 'plot3', 'scatter3', 'trisurf'):
z_tick, z_org, z_major_count = _plt.kwargs['zaxis']
if pass_ == 1:
gr.grid3d(x_tick, 0, z_tick, x_org[0], y_org[1], z_org[0], 2, 0, 2)
gr.grid3d(0, y_tick, 0, x_org[0], y_org[1], z_org[0], 0, 2, 0)
else:
gr.axes3d(x_tick, 0, z_tick, x_org[0], y_org[0], z_org[0], x_major_count, 0, z_major_count, -ticksize)
gr.axes3d(0, y_tick, 0, x_org[1], y_org[0], z_org[0], 0, y_major_count, 0, ticksize)
else:
if kind == 'heatmap':
ticksize = -ticksize
else:
gr.grid(x_tick, y_tick, 0, 0, x_major_count, y_major_count)
gr.axes(x_tick, y_tick, x_org[0], y_org[0], x_major_count, y_major_count, ticksize)
gr.axes(x_tick, y_tick, x_org[1], y_org[1], -x_major_count, -y_major_count, -ticksize)
if 'title' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_TOP)
gr.textext(0.5*(viewport[0] + viewport[1]), vp[3], _plt.kwargs['title'])
gr.restorestate()
if kind in ('wireframe', 'surface', 'plot3', 'scatter3', 'trisurf'):
x_label = _plt.kwargs.get('xlabel', '')
y_label = _plt.kwargs.get('ylabel', '')
z_label = _plt.kwargs.get('zlabel', '')
gr.titles3d(x_label, y_label, z_label)
else:
if 'xlabel' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_BOTTOM)
gr.textext(0.5 * (viewport[0] + viewport[1]), vp[2] + 0.5 * charheight, _plt.kwargs['xlabel'])
gr.restorestate()
if 'ylabel' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_TOP)
gr.setcharup(-1, 0)
gr.textext(vp[0] + 0.5 * charheight, 0.5 * (viewport[2] + viewport[3]), _plt.kwargs['ylabel'])
gr.restorestate()
def _draw_axes(kind, pass_=1):
global _plt
viewport = _plt.kwargs['viewport']
vp = _plt.kwargs['vp']
x_tick, x_org, x_major_count = _plt.kwargs['xaxis']
y_tick, y_org, y_major_count = _plt.kwargs['yaxis']
gr.setlinecolorind(1)
gr.setlinewidth(1)
diag = ((viewport[1]-viewport[0])**2 + (viewport[3]-viewport[2])**2)**0.5
charheight = max(0.018 * diag, 0.012)
gr.setcharheight(charheight)
ticksize = 0.0075 * diag
if kind in ('wireframe', 'surface', 'plot3', 'scatter3', 'trisurf'):
z_tick, z_org, z_major_count = _plt.kwargs['zaxis']
if pass_ == 1:
gr.grid3d(x_tick, 0, z_tick, x_org[0], y_org[0], z_org[0], 2, 0, 2)
gr.grid3d(0, y_tick, 0, x_org[1], y_org[0], z_org[0], 0, 2, 0)
else:
gr.axes3d(x_tick, 0, z_tick, x_org[0], y_org[0], z_org[0], x_major_count, 0, z_major_count, -ticksize)
gr.axes3d(0, y_tick, 0, x_org[1], y_org[0], z_org[0], 0, y_major_count, 0, ticksize)
else:
if kind == 'heatmap':
ticksize = -ticksize
else:
gr.grid(x_tick, y_tick, 0, 0, x_major_count, y_major_count)
gr.axes(x_tick, y_tick, x_org[0], y_org[0], x_major_count, y_major_count, ticksize)
gr.axes(x_tick, y_tick, x_org[1], y_org[1], -x_major_count, -y_major_count, -ticksize)
if 'title' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_TOP)
gr.textext(0.5*(viewport[0] + viewport[1]), vp[3], _plt.kwargs['title'])
gr.restorestate()
if kind in ('wireframe', 'surface', 'plot3', 'scatter3', 'trisurf'):
x_label = _plt.kwargs.get('xlabel', '')
y_label = _plt.kwargs.get('ylabel', '')
z_label = _plt.kwargs.get('zlabel', '')
gr.titles3d(x_label, y_label, z_label)
else:
if 'xlabel' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_BOTTOM)
gr.textext(0.5 * (viewport[0] + viewport[1]), vp[2] + 0.5 * charheight, _plt.kwargs['xlabel'])
gr.restorestate()
if 'ylabel' in _plt.kwargs:
gr.savestate()
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_TOP)
gr.setcharup(-1, 0)
gr.textext(vp[0] + 0.5 * charheight, 0.5 * (viewport[2] + viewport[3]), _plt.kwargs['ylabel'])
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(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(self):
if not self._draw_graphics:
return
x = range(0, 128)
y = range(0, 128)
z = readfile(os.path.join(os.path.dirname(os.path.realpath(__file__)), "kws.dat"), separator="$")
zrange = max(z) - min(z)
h = [min(z) + i * 0.025 * zrange for i in range(0, 40)]
gr.setviewport(0.075, 0.95, 0.075, 0.95)
gr.setwindow(1, 128, 1, 128)
gr.setspace(min(z), max(z), 0, 90)
gr.setcharheight(0.018)
gr.setcolormap(-3)
gr.surface(x, y, z, 5)
gr.contour(x, y, h, z, -1)
gr.axes(5, 5, 1, 1, 2, 2, 0.0075)
def draw(self):
if not self._draw_graphics:
return
x = range(0, 128)
y = range(0, 128)
z = readfile(os.path.join(os.path.dirname(os.path.realpath(__file__)),
"kws.dat"), separator='$')
zrange = max(z) - min(z)
h = [min(z) + i * 0.025 * zrange for i in range(0, 40)]
gr.setviewport(0.075, 0.95, 0.075, 0.95)
gr.setwindow(1, 128, 1, 128)
gr.setspace(min(z), max(z), 0, 90)
gr.setcharheight(0.018)
gr.setcolormap(-3)
gr.surface(x, y, z, 5)
gr.contour(x, y, h, z, -1)
gr.axes(5, 5, 1, 1, 2, 2, 0.0075)
def _colorbar(off=0.0, colors=256):
global _plt
gr.savestate()
viewport = _plt.kwargs['viewport']
zmin, zmax = _plt.kwargs['zrange']
gr.setwindow(0, 1, zmin, zmax)
gr.setviewport(viewport[1] + 0.02 + off, viewport[1] + 0.05 + off,
viewport[2], viewport[3])
l = [1000+int(255*i/(colors-1)) for i in range(colors)]
gr.cellarray(0, 1, zmax, zmin, 1, colors, l)
diag = ((viewport[1] - viewport[0])**2 + (viewport[3] - viewport[2])**2)**0.5
charheight = max(0.016 * diag, 0.012)
gr.setcharheight(charheight)
if _plt.kwargs['scale'] & gr.OPTION_Z_LOG:
gr.setscale(gr.OPTION_Y_LOG)
gr.axes(0, 2, 1, zmin, 0, 1, 0.005)
else:
ztick = 0.5 * gr.tick(zmin, zmax)
gr.axes(0, ztick, 1, zmin, 0, 1, 0.005)
gr.restorestate()
def _colorbar(off=0.0, colors=256):
global _plt
gr.savestate()
viewport = _plt.kwargs['viewport']
zmin, zmax = _plt.kwargs['zrange']
gr.setwindow(0, 1, zmin, zmax)
gr.setviewport(viewport[1] + 0.02 + off, viewport[1] + 0.05 + off,
viewport[2], viewport[3])
l = [1000+int(255*i/(colors-1)) for i in range(colors)]
gr.cellarray(0, 1, zmax, zmin, 1, colors, l)
diag = ((viewport[1] - viewport[0])**2 + (viewport[3] - viewport[2])**2)**0.5
charheight = max(0.016 * diag, 0.012)
gr.setcharheight(charheight)
if _plt.kwargs['scale'] & gr.OPTION_Z_LOG:
gr.setscale(gr.OPTION_Y_LOG)
gr.axes(0, 2, 1, zmin, 0, 1, 0.005)
else:
ztick = 0.5 * gr.tick(zmin, zmax)
gr.axes(0, ztick, 1, zmin, 0, 1, 0.005)
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)
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)
from __future__ import print_function
from __future__ import unicode_literals
import sys
import os
import numpy as np
import gr
sys.path.insert(0, os.path.abspath('../src'))
from statistics.rdf import Kernels
x = np.linspace(-1.25, 1.25, 500)
for name in dir(Kernels):
if name.startswith('_') or name == 'bandwidth':
continue
kernel = getattr(Kernels, name)
y = kernel(x)
gr.beginprint(name.lower()+'.svg')
gr.clearws()
gr.setwsviewport(0, 0.1, 0, 0.06)
gr.setviewport(0, 1, 0, 1)
gr.setwindow(-1.25, 1.25, -0.25, 1.25)
gr.grid(0.1, 0.1, 0, 0, 5, 5)
gr.axes(0.1, 0.1, 0, 0, 5, 5, -0.01)
gr.setlinewidth(2)
gr.setlinecolorind(2)
gr.polyline(x, y)
gr.setlinecolorind(1)
gr.setlinewidth(1)
gr.updatews()
gr.endprint()
""" 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()
gr.setscale(1)
start = time.time()
while time.time() - start < 10:
try:
power = get_spectrum()
peakind = signal.find_peaks_cwt(power, numpy.array([5]))
except (IOError):
continue
gr.clearws()
gr.setlinewidth(1)
gr.setlinecolorind(1)
gr.grid(1, 5, 50, 0, 1, 2)
gr.axes(1, 5, 50, 0, 1, 2, -0.008)
gr.setcharheight(0.020)
gr.text(0.15, 0.965, '100Hz')
gr.text(0.47, 0.965, '1kHz')
gr.text(0.79, 0.965, '10kHz')
gr.setlinecolorind(4)
gr.polyline(f[1:], power[1:])
for p in peakind:
if power[p] > 10:
gr.setlinewidth(2)
gr.setlinecolorind(2)
xe, ye = parabolic(f[p], power, p)
print(xe, ye)
gr.polyline([xe] * 2, [0, ye])
gr.updatews()
gr.setregenflags(gr.MPL_POSTPONE_UPDATE)
for t in range(100):
plt.cla()
fig = plt.subplot(133)
fig.xaxis.set_ticks([-100, 0, 100])
fig.yaxis.set_ticks([])
plt.ylim([0, 1000])
plt.hist(angles[t], 20, normed=0, facecolor='g', alpha=0.5)
plt.show()
gr.setviewport(0, 0.7, 0, 0.7)
gr.setwindow(0.1, 0.9, 0.05, 0.85)
mogli.draw(molecules[t],
bonds_param=1.15,
camera=((60, 0, 0), (0, 0, 0), (0, 1, 0)))
gr.settextalign(gr.TEXT_HALIGN_CENTER, gr.TEXT_VALIGN_HALF)
gr.text(0.35, 0.7,
'700K (%.1f ps) # of bonds: %d' % (t / 10.0, len(angles[t])))
lens.append(len(angles[t]))
if t > 0:
gr.setwindow(0, 10, 3500, 5000)
gr.setviewport(0.1, 0.6, 0.05, 0.1)
gr.axes(1, 0, 0, 3500, 2, 0, 0.005)
gr.polyline(np.arange(t + 1) / 10.0, lens)
gr.updatews()
#!/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()
gr.setscale(1)
start = time.time()
while time.time() - start < 10:
try:
power = get_spectrum()
peakind = signal.find_peaks_cwt(power, np.array([5]))
except (IOError):
continue
gr.clearws()
gr.setlinewidth(1)
gr.setlinecolorind(1)
gr.grid(1, 5, 50, 0, 1, 2)
gr.axes(1, 5, 50, 0, 1, 2, -0.008)
gr.setcharheight(0.020)
gr.text(0.15, 0.965, '100Hz')
gr.text(0.47, 0.965, '1kHz')
gr.text(0.79, 0.965, '10kHz')
gr.setlinecolorind(4)
gr.polyline(f[1:], power[1:])
for p in peakind:
if power[p] > 10:
gr.setlinewidth(2)
gr.setlinecolorind(2)
xe, ye = parabolic(f[p], power, p)
print(xe, ye)
gr.polyline([xe] * 2, [0, ye])
gr.updatews()
