def plot_conn_comp(conn_comps, cmap=[]):
if len(cmap) == 0:
return shade(hv.Image(rescale(conn_comps)),
normalization='linear',
cmap=fire_cmap)
else:
return shade(hv.Image(rescale(conn_comps)),
normalization='linear',
cmap=cmap)
def plot_decode_image(self,
time=None,
plt_range=None,
x_range=None,
y_range=None):
if time is None:
time = self.posteriors.get_time_start()
if plt_range is None:
plt_range = self.posteriors.get_time_total()
if x_range is None:
x_range = (time, time + plt_range)
if y_range is None:
y_range = self.posteriors.get_pos_range()
self.post_img.extents = (x_range[0], 0, x_range[1],
self.enc_settings.pos_bins[-1])
self.post_img.relabel('posteriors')
rgb = shade(regrid(self.post_img,
aggregator='mean',
dynamic=False,
x_range=x_range,
y_range=y_range,
precompute=True),
cmap=plt.get_cmap('hot'),
normalization='linear',
dynamic=False)
rgb.extents = (x_range[0], 0, x_range[1],
self.enc_settings.pos_bins[-1])
return rgb
def __call__(self, dset, **params):
self.p = ParamOverrides(self, params)
if self.p.vdim is None:
vdim = dset.vdims[0].name
else:
vdim = self.p.vdim
pts = hv.util.Dynamic(dset, operation=skypoints,
streams=[self.p.filter_stream])
if self.p.aggregator == 'mean':
aggregator = ds.mean(vdim)
elif self.p.aggregator == 'std':
aggregator = ds.std(vdim)
elif self.p.aggregator == 'count':
aggregator = ds.count()
decimate_opts = dict(plot={'tools': ['hover',
'box_select']},
style={'alpha': 0,
'size': self.p.decimate_size,
'nonselection_alpha': 0})
decimated = decimate(pts).opts(**decimate_opts)
raster_ = rasterize(pts, aggregator=aggregator)
color_gadget = raster_.opts(cmap=Viridis[256], colorbar=True, alpha=0)
sky_shaded = shade(raster_, cmap=viridis)
plot = dynspread(sky_shaded) * decimated * color_gadget
return plot.options(bgcolor="black", responsive=True, min_height=100)
def test_shade_categorical_images_grid(self):
xs, ys = [0.25, 0.75], [0.25, 0.75]
data = NdOverlay(
{
'A':
Image((xs, ys, [[1, 0], [0, 0]]),
datatype=['grid'],
vdims='z Count'),
'B':
Image((xs, ys, [[0, 0], [1, 0]]),
datatype=['grid'],
vdims='z Count'),
'C':
Image((xs, ys, [[0, 0], [1, 0]]),
datatype=['grid'],
vdims='z Count')
},
kdims=['z'])
shaded = shade(data)
r = [[228, 255], [66, 255]]
g = [[26, 255], [150, 255]]
b = [[28, 255], [129, 255]]
a = [[40, 0], [255, 0]]
expected = RGB((xs, ys, r, g, b, a),
datatype=['grid'],
vdims=RGB.vdims + [Dimension('A', range=(0, 1))])
self.assertEqual(shaded, expected)
def polygons(gdf, label='', geometry='geometry', col=None, agg=ds.any):
"""Return a holoviews plot.
Multiple holoviews plots can be collected in a list and plotted with
hv.Layout(list_of_plots).cols(3).
Parameters
----------
gdf : geopandas.GeoDataFrame
label : str
geometry : geometry column
col : str
Column on which the datashader data aggregation will be done.
The default is `None`.
agg : datashader aggregation function
The default is `ds.any`.
Returns
-------
shd : holoviews plot
"""
hv.output(backend="matplotlib")
sgdf = spd.GeoDataFrame(gdf)
cvs = ds.Canvas()
if col is not None:
agg = cvs.polygons(sgdf, geometry, agg=agg(col))
else:
agg = cvs.polygons(sgdf, geometry, agg=agg())
shd = hd.shade(hv.Image(agg, label=label))
return shd
def view(self):
points = hv.DynamicMap(hv.Points(df, kdims=['x', 'y']))
raster = rasterize(points,
x_sampling=1,
y_sampling=1,
width=900,
height=600)
return hv.DynamicMap(self.tiles) * shade(
raster, streams=[hv.streams.Params(self, ['cmap'])])
def view(self, **kwargs):
points = hv.DynamicMap(self.points)
agg = rasterize(points,
x_sampling=1,
y_sampling=1,
width=600,
height=400)
stream = hv.streams.Params(self, ['cmap'])
tiles = hv.DynamicMap(self.tiles)
return tiles * shade(agg, streams=[stream])
def test_shade_dt_xaxis_constant_yaxis(self):
df = pd.DataFrame({'y': np.ones(100)}, index=pd.date_range('1980-01-01', periods=100, freq='1T'))
rgb = shade(rasterize(Curve(df), dynamic=False, width=3))
xs = np.array(['1980-01-01T00:16:30.000000', '1980-01-01T00:49:30.000000',
'1980-01-01T01:22:30.000000'], dtype='datetime64[us]')
ys = np.array([])
bounds = (np.datetime64('1980-01-01T00:00:00.000000'), 1.0,
np.datetime64('1980-01-01T01:39:00.000000'), 1.0)
expected = RGB((xs, ys, np.empty((0, 3, 4))), ['index', 'y'],
xdensity=1, ydensity=1, bounds=bounds)
self.assertEqual(rgb, expected)
def one_band(band, time):
xs, ys = dataset[band].sel(time=time)[dims[0]], dataset[band].sel(
time=time)[dims[1]]
b = ds.utils.orient_array(dataset[band].sel(time=time))
a = (np.where(np.logical_or(np.isnan(b), b <= nodata), 0,
255)).astype(np.uint8)
return shade(regrid(
hv.RGB((xs, ys[::-1], b, b, b, a), vdims=list('RGBA'))),
cmap=cmap,
clims=clims,
normalization=norm).redim(x=dims[0],
y=dims[1]).opts(width=width,
height=height)
def test_shade_categorical_images_grid(self):
xs, ys = [0.25, 0.75], [0.25, 0.75]
data = NdOverlay({'A': Image((xs, ys, [[1, 0], [0, 0]]), datatype=['grid'], vdims='z Count'),
'B': Image((xs, ys, [[0, 0], [1, 0]]), datatype=['grid'], vdims='z Count'),
'C': Image((xs, ys, [[0, 0], [1, 0]]), datatype=['grid'], vdims='z Count')},
kdims=['z'])
shaded = shade(data)
r = [[228, 255], [66, 255]]
g = [[26, 255], [150, 255]]
b = [[28, 255], [129, 255]]
a = [[40, 0], [255, 0]]
expected = RGB((xs, ys, r, g, b, a), datatype=['grid'],
vdims=RGB.vdims+[Dimension('A', range=(0, 1))])
self.assertEqual(shaded, expected)
def plot_decode_image(self,
time,
x_range=None,
y_range=None,
plt_range=10):
sel_range = [time, time + plt_range]
if (x_range is None):
x_range = [time, time + plt_range]
if (y_range is None):
y_range = [0, self.enc_settings.pos_bins[-1]]
x_range = list(x_range)
#x_range[0] -= plt_range
#x_range[1] += plt_range
x_range[0] = max(x_range[0], self.posteriors.get_time_start())
x_range[1] = min(x_range[1], self.posteriors.get_time_end())
# post_time = self.posteriors.index.get_level_values('time')
# img_sel = self.posteriors.get_distribution_view().query("(time > @x_range[0]) & (time < @x_range[1])").values.T
# img_sel = np.flip(img_sel, axis=0)
# img = hv.Image(img_sel, bounds=(x_range[0], self.enc_settings.pos_bins[0],
# x_range[1],
# self.enc_settings.pos_bins[-1]),
# kdims=['time (sec)', 'linpos (cm)'], vdims=['probability'],)
# img = img.redim(probability={'range': (0, 0.3)})
# img.extents = (sel_range[0], 0, sel_range[1], self.enc_settings.pos_bins[-1])
self.post_img.extents = (sel_range[0], 0, sel_range[1],
self.enc_settings.pos_bins[-1])
self.post_img.relabel('posteriors')
rgb = shade(regrid(self.post_img,
aggregator='max',
dynamic=False,
x_range=x_range,
y_range=y_range),
cmap=plt.get_cmap('magma'),
normalization='linear',
dynamic=False)
# rgb = shade(regrid(self.post_img, aggregator='mean', dynamic=False,
# x_range=x_range, y_range=y_range, y_sampling=1, x_sampling=0.001),
# cmap=plt.get_cmap('hot'), normalization='linear', dynamic=False)
rgb.extents = (sel_range[0], 0, sel_range[1],
self.enc_settings.pos_bins[-1])
return rgb
ddf = ddf.persist()
from bokeh.models import WMTSTileSource
url = 'https://server.arcgisonline.com/ArcGIS/rest/services/World_Imagery/MapServer/tile/{Z}/{Y}/{X}.jpg'
wmts = gv.WMTS(WMTSTileSource(url=url))
stream = hv.streams.Stream.define('HourSelect', hour=0)()
points = hv.Points(ddf, kdims=['dropoff_x', 'dropoff_y'])
dmap = hv.util.Dynamic(points, operation=lambda obj, hour: obj.select(hour=hour),
streams=[stream])
# Apply aggregation
aggregated = aggregate(dmap, link_inputs=True)
# Shade the data
shaded = shade(aggregated)
# Define PointerX stream, attach to points and declare DynamicMap for cross-section and VLine
pointer = hv.streams.PointerX(x=ddf.dropoff_x.loc[0].compute().iloc[0], source=points)
section = hv.util.Dynamic(aggregated, operation=lambda obj, x: obj.sample(dropoff_x=x),
streams=[pointer], link_inputs=False)
vline = hv.DynamicMap(lambda x: hv.VLine(x), streams=[pointer])
# Define options
hv.opts("RGB [width=800 height=600 xaxis=None yaxis=None] VLine (color='black' line_width=1)")
hv.opts("Curve [width=100 yaxis=None show_frame=False] (color='black') {+framewise} Layout [shared_axes=False]")
# Combine it all into a complex layout
hvobj = (wmts * shaded * vline) << section
### Pass the HoloViews object to the renderer
def render_to_browser(self, **kwargs):
points = hv.DynamicMap(hv.Points(self.data, kdims=['x', 'y']))
tiles = CartoDark().apply.opts(**self.opts)
agg = rasterize(points, width=1200, height=800)
pn.serve(pn.Row(tiles * shade(agg, cmap=cm[self.color_map])),
title='Datashader MapTiler')
from bokeh.models import WMTSTileSource
url = 'https://server.arcgisonline.com/ArcGIS/rest/services/World_Imagery/MapServer/tile/{Z}/{Y}/{X}.jpg'
wmts = gv.WMTS(WMTSTileSource(url=url))
stream = hv.streams.Stream.define('HourSelect', hour=0)()
points = hv.Points(ddf, kdims=['dropoff_x', 'dropoff_y'])
dmap = hv.util.Dynamic(points,
operation=lambda obj, hour: obj.select(hour=hour),
streams=[stream])
# Apply aggregation
aggregated = aggregate(dmap, link_inputs=True)
# Shade the data
shaded = shade(aggregated)
# Define PointerX stream, attach to points and declare DynamicMap for cross-section and VLine
pointer = hv.streams.PointerX(x=ddf.dropoff_x.loc[0].compute().iloc[0],
source=points)
section = hv.util.Dynamic(aggregated,
operation=lambda obj, x: obj.sample(dropoff_x=x),
streams=[pointer],
link_inputs=False)
vline = hv.DynamicMap(lambda x: hv.VLine(x), streams=[pointer])
# Define options
hv.opts(
"RGB [width=800 height=600 xaxis=None yaxis=None] VLine (color='black' line_width=1)"
)
hv.opts(
def plot_conn_comp(conn_comps):
return shade(hv.Image(rescale(conn_comps)),
normalization='linear',
cmap=fire_cmap)
def plot_raw_image(img):
return shade(hv.Image(rescale(img)), normalization='linear', cmap=gray)
def main(argv):
clock_start = time.time()
# Command line options
parser = ArgumentParser(description='Rapid Measurement Set plotting with xarray-ms and datashader. Version {0:s}'.format(__version__))
parser.add_argument('ms',
help='Measurement set')
parser.add_argument("-v", "--version", action='version',
version='{:s} version {:s}'.format(parser.prog, __version__))
parser.add_argument('--xaxis', dest='xaxis',
help='[t]ime (default), [f]requency, [c]hannels, [u], [uv]distance, [r]eal, [a]mplitude', default='t')
parser.add_argument('--yaxis', dest='yaxis',
help='[a]mplitude (default), [p]hase, [r]eal, [i]maginary, [v]', default='a')
parser.add_argument('--col', dest='col',
help='Measurement Set column to plot (default = DATA)', default='DATA')
parser.add_argument('--field', dest='myfields',
help='Field ID(s) to plot (comma separated list, default = all)', default='all')
parser.add_argument('--spws', dest='myspws',
help='Spectral windows (DDIDs) to plot (comma separated list, default = all)', default='all')
parser.add_argument('--corr', dest='corr',
help='Correlation index to plot (default = 0)', default=0)
parser.add_argument('--noflags', dest='noflags',
help='Plot flagged data (default = False)', action='store_true', default=False)
parser.add_argument('--noconj', dest='noconj',
help='Do not show conjugate points in u,v plots (default = plot conjugates)', action='store_true', default=False)
parser.add_argument('--xmin', dest='xmin',
help='Minimum x-axis value (default = data min)', default='')
parser.add_argument('--xmax', dest='xmax',
help='Maximum x-axis value (default = data max)', default='')
parser.add_argument('--ymin', dest='ymin',
help='Minimum y-axis value (default = data min)', default='')
parser.add_argument('--ymax', dest='ymax',
help='Maximum y-axis value (default = data max)', default='')
parser.add_argument('--xcanvas', dest='xcanvas',
help='Canvas x-size in pixels (default = 1280)', default=1280)
parser.add_argument('--ycanvas', dest='ycanvas',
help='Canvas y-size in pixels (default = 800)', default=900)
parser.add_argument('--norm', dest='normalize',
help='Pixel scale normalization: eq_hist (default), cbrt, log, linear', default='eq_hist')
parser.add_argument('--cmap', dest='mycmap',
help='Colorcet map to use (default = bkr)', default='bkr')
parser.add_argument('--bgcol', dest='bgcol',
help='RGB hex code for background colour (default = FFFFFF)', default='FFFFFF')
parser.add_argument('--fontsize', dest='fontsize',
help='Font size for all text elements (default = 20)', default=20)
parser.add_argument('--png', dest='pngname',
help='PNG name (default = something verbose)', default='')
parser.add_argument('--stamp', dest='dostamp',
help='Add timestamp to default PNG name', action='store_true', default=False)
# Assign inputs
options = parser.parse_args(argv)
xaxis = options.xaxis.lower()
yaxis = options.yaxis.lower()
col = options.col.upper()
myfields = options.myfields
corr = int(options.corr)
myspws = options.myspws
noflags = options.noflags
noconj = options.noconj
xmin = options.xmin
xmax = options.xmax
ymin = options.ymin
ymax = options.ymax
xcanvas = int(options.xcanvas)
ycanvas = int(options.ycanvas)
normalize = options.normalize
mycmap = options.mycmap
bgcol = '#'+options.bgcol.lstrip('#')
fontsize = options.fontsize
pngname = options.pngname
dostamp = options.dostamp
# Trap no MS
myms = options.ms.rstrip('/')
# Check for allowed axes
allowed = ['a', 'p', 'r', 'i', 't', 'f', 'c', 'uv', 'u', 'v']
if xaxis not in allowed or yaxis not in allowed:
raise ValueError('xaxis "%s" is unknown. Please check requested axes' % xaxis)
xfullname, xunits = sms.fullname(xaxis)
yfullname, yunits = sms.fullname(yaxis)
log.info('Plotting %s vs %s' % (yfullname, xfullname))
log.info('Correlation index %d' % corr)
# Get MS metadata
chan_freqs = sms.get_chan_freqs(myms)
field_ids, field_names = sms.get_field_names(myms)
# Sort out field selection(s)
if myfields == 'all':
fields = field_ids
# fields = []
# for group in msdata:
# fields.append(group.FIELD_ID)
# fields = numpy.unique(fields)
else:
fields = list(map(int, myfields.split(',')))
sms.blank()
log.info('FIELD_ID NAME')
for i in fields:
log.info('%-10s %-16s' % (i, field_names[i]))
# Sort out SPW selection(s)
if myspws == 'all':
spws = numpy.arange(len(chan_freqs))
else:
spws = list(map(int, myspws.split(',')))
sms.blank()
log.info('SPW_ID NCHAN ')
for i in spws:
nchan = len(chan_freqs.values[i])
log.info('%-10s %-16s' % (i, nchan))
sms.blank()
# Construct TaQL string based on FIELD and SPW selections
field_taq = []
for fld in fields:
field_taq.append('FIELD_ID=='+str(fld))
spw_taq = []
for spw in spws:
spw_taq.append('DATA_DESC_ID=='+str(spw))
mytaql = '('+' || '.join(field_taq)+') && ('+' || '.join(spw_taq)+')'
# Read the selected data
log.info('Reading %s' % (myms))
log.info('%s column' % (col))
msdata = xms.xds_from_ms(
myms, columns=[col, 'TIME', 'FLAG', 'FIELD_ID', 'UVW'], taql_where=mytaql)
# Replace xarray data with a,p,r,i in situ
log.info('Rearranging the deck chairs')
for i in range(0, len(msdata)):
msdata[i] = msdata[i].rename({col: 'VISDATA'})
# Initialise arrays for plot data
ydata = numpy.array(())
xdata = numpy.array(())
flags = numpy.array(())
# Get plot data into a pair of numpy arrays
for group in msdata:
nrows = group.VISDATA.values.shape[0]
nchan = group.VISDATA.values.shape[1]
fld = group.FIELD_ID
ddid = group.DATA_DESC_ID
if fld in fields and ddid in spws:
chans = chan_freqs.values[ddid]
flags = numpy.append(flags, group.FLAG.values[:, :, corr])
if xaxis == 'uv' or xaxis == 'u' or yaxis == 'v':
uu = group.UVW.values[:, 0]
vv = group.UVW.values[:, 1]
chans_wavel = sms.freq_to_wavel(chans)
uu_wavel = numpy.ravel(
uu / numpy.transpose(numpy.array([chans_wavel, ]*len(uu))))
vv_wavel = numpy.ravel(
vv / numpy.transpose(numpy.array([chans_wavel, ]*len(vv))))
uvdist_wavel = ((uu_wavel**2.0)+(vv_wavel**2.0))**0.5
if yaxis == 'a':
ydata = numpy.append(ydata, numpy.abs(
group.VISDATA.values[:, :, corr]))
elif yaxis == 'p':
ydata = numpy.append(ydata, numpy.angle(
group.VISDATA.values[:, :, corr]))
elif yaxis == 'r':
ydata = numpy.append(ydata, numpy.real(
group.VISDATA.values[:, :, corr]))
elif yaxis == 'i':
ydata = numpy.append(ydata, numpy.imag(
group.VISDATA.values[:, :, corr]))
elif yaxis == 'v':
ydata = numpy.append(ydata, vv_wavel)
if xaxis == 'f':
xdata = numpy.append(xdata, numpy.tile(chans, nrows))
elif xaxis == 'c':
xdata = numpy.append(xdata, numpy.tile(
numpy.arange(nchan), nrows))
elif xaxis == 't':
# Add t = t - t[0] and make it relative
xdata = numpy.append(
xdata, numpy.repeat(group.TIME.values, nchan))
elif xaxis == 'uv':
xdata = numpy.append(xdata, uvdist_wavel)
elif xaxis == 'r':
xdata = numpy.append(xdata, numpy.real(
group.VISDATA.values[:, :, corr]))
elif xaxis == 'u':
xdata = numpy.append(xdata, uu_wavel)
elif xaxis == 'a':
xdata = numpy.append(xdata, numpy.abs(
group.VISDATA.values[:, :, corr]))
# Drop flagged data if required
if not noflags:
bool_flags = list(map(bool, flags))
masked_ydata = numpy.ma.masked_array(data=ydata, mask=bool_flags)
masked_xdata = numpy.ma.masked_array(data=xdata, mask=bool_flags)
ydata = masked_ydata.compressed()
xdata = masked_xdata.compressed()
# Plot the conjugate points for a u,v plot if requested
# This is done at this stage so we don't have to worry about the flags
if not noconj and xaxis == 'u' and yaxis == 'v':
xdata = numpy.append(xdata, xdata*-1.0)
ydata = numpy.append(ydata, ydata*-1.0)
# Drop data out of plot range(s)
if xmin != '':
xmin = float(xmin)
masked_xdata = numpy.ma.masked_less(xdata, xmin)
masked_ydata = numpy.ma.masked_array(
data=ydata, mask=masked_xdata.mask)
ydata = masked_ydata.compressed()
xdata = masked_xdata.compressed()
if xmax != '':
xmax = float(xmax)
masked_xdata = numpy.ma.masked_greater(xdata, xmax)
masked_ydata = numpy.ma.masked_array(
data=ydata, mask=masked_xdata.mask)
ydata = masked_ydata.compressed()
xdata = masked_xdata.compressed()
if ymin != '':
ymin = float(ymin)
masked_ydata = numpy.ma.masked_less(ydata, ymin)
masked_xdata = numpy.ma.masked_array(
data=xdata, mask=masked_ydata.mask)
ydata = masked_ydata.compressed()
xdata = masked_xdata.compressed()
if ymax != '':
ymax = float(ymax)
masked_ydata = numpy.ma.masked_greater(ydata, ymax)
masked_xdata = numpy.ma.masked_array(
data=xdata, mask=masked_ydata.mask)
ydata = masked_ydata.compressed()
xdata = masked_xdata.compressed()
# Put plotdata into pandas data frame
# This should be possible with xarray directly, but for freq plots we need a corner turn
log.info('Making Pandas dataframe')
dists = {'plotdata': pd.DataFrame(odict([(xaxis, xdata), (yaxis, ydata)]))}
df = pd.concat(dists, ignore_index=True)
# Run datashader on the pandas df
log.info('Running datashader')
canvas = ds.Canvas(xcanvas, ycanvas)
agg = canvas.points(df, xaxis, yaxis)
img = hd.shade(hv.Image(agg), cmap=getattr(
colorcet, mycmap), normalization=normalize)
# Set plot limits based on data extent or user values for axis labels
data_xmin = numpy.min(agg.coords[xaxis].values)
data_ymin = numpy.min(agg.coords[yaxis].values)
data_xmax = numpy.max(agg.coords[xaxis].values)
data_ymax = numpy.max(agg.coords[yaxis].values)
if ymin == '':
ymin = data_ymin
else:
ymin = float(ymin)
if ymax == '':
ymax = data_ymax
else:
ymax = float(ymax)
if xmin == '':
xmin = data_xmin
else:
xmin = float(xmin)
if xmax == '':
xmax = data_xmax
else:
xmax = float(xmax)
# Setup plot labels and PNG name
ylabel = yfullname+' '+yunits
xlabel = xfullname+' '+xunits
title = myms+' '+col+' (correlation '+str(corr)+')'
if pngname == '':
pngname = 'plot_'+myms.split('/')[-1]+'_'+col+'_'
pngname += 'SPW-' + \
myspws.replace(',', '-')+'_FIELD-'+myfields.replace(',', '-')+'_'
pngname += yfullname+'_vs_'+xfullname+'_'+'corr'+str(corr)
if dostamp:
pngname += '_'+sms.stamp()
pngname += '.png'
# Render the plot
log.info('Rendering plot')
sms.make_plot(img.data,
data_xmin,
data_xmax,
data_ymin,
data_ymax,
xmin,
xmax,
ymin,
ymax,
xlabel,
ylabel,
title,
pngname,
bgcol,
fontsize,
figx=xcanvas/60,
figy=ycanvas/60)
# Stop the clock
clock_stop = time.time()
elapsed = str(round((clock_stop-clock_start), 2))
log.info('Done. Elapsed time: %s seconds.' % (elapsed))
panel2 = gv.WMTS(WMTSTileSource(url=panel2_url))
stream = hv.streams.Stream.define('HourSelect', hour=0)()
points = hv.Points(ddf, kdims=['dropoff_x', 'dropoff_y'])
dmap = hv.util.Dynamic(
points,
operation=lambda obj, hour: obj.select(dropoff_hour=hour),
streams=[stream])
# Apply aggregation
aggregated = aggregate(dmap,
link_inputs=True,
streams=[hv.streams.RangeXY],
width=400,
height=400)
shaded = shade(aggregated, link_inputs=True)
# Define PointerX stream, attach to points and declare DynamicMap for cross-section and VLine
pointer = hv.streams.PointerX(x=ddf.dropoff_x.loc[0].compute().iloc[0],
source=points)
section = hv.util.Dynamic(aggregated,
operation=lambda obj, x: obj.sample(dropoff_x=x),
streams=[pointer],
link_inputs=False).relabel('')
vline = hv.DynamicMap(lambda x: hv.VLine(x), streams=[pointer])
# Define options
hv.opts(
"RGB [width=600 height=600 xaxis=None yaxis=None fontsize={'title': '14pt'}] VLine (color='white' line_width=2)"
)
hv.opts(
def filter_count(agg, min_count, **kwargs):
if min_count:
agg = deepcopy(agg)
agg.data.Count.data[agg.data.Count.data < min_count] = 0
return agg
def hline_fn(min_count, **kwargs):
return hv.VLine(min_count)
def tiles_fn(alpha, **kwargs):
return tiles.opts(style=dict(alpha=alpha))
explorer = OSMExplorer(name="OpenStreetMap GPS Explorer")
tile = hv.DynamicMap(tiles_fn, streams=[explorer])
agg = aggregate(hv.Points(df))
filtered = hv.util.Dynamic(agg, operation=filter_count, streams=[explorer])
shaded = shade(filtered, streams=[explorer])
hline = hv.DynamicMap(hline_fn, streams=[explorer])
explorer.output = (tile * shaded) << histogram(agg, log=True) * hline
doc = parambokeh.Widgets(explorer,
view_position='right',
callback=explorer.event,
mode='server')
# Apply aggregation
aggregated = aggregate(dmap,
link_inputs=True,
streams=[hv.streams.RangeXY],
width=1200,
height=600)
# Shade the data
class ColormapPicker(hv.streams.Stream):
colormap = param.ObjectSelector(default=cm_n["fire"],
objects=cm_n.values())
cmap_picker = ColormapPicker(rename={'colormap': 'cmap'}, name='')
shaded = shade(aggregated, link_inputs=True, streams=[cmap_picker])
# Define PointerX stream, attach to points and declare DynamicMap for cross-section and VLine
pointer = hv.streams.PointerX(x=ddf.dropoff_x.loc[0].compute().iloc[0],
source=points)
section = hv.util.Dynamic(aggregated,
operation=lambda obj, x: obj.sample(dropoff_x=x),
streams=[pointer],
link_inputs=False).relabel('')
vline = hv.DynamicMap(lambda x: hv.VLine(x), streams=[pointer])
# Define options
hv.opts(
"RGB [width=1200 height=600 xaxis=None yaxis=None fontsize={'title': '14pt'}] VLine (color='white' line_width=2)"
)
hv.opts(
child_reshaped = np.reshape(reshape_values, parent.data.shape)
plot_data = pd.DataFrame({
"hs":
parent.data.reshape(parent.rows * parent.cols),
"lpmf":
child_reshaped.reshape(parent.rows * parent.cols)
})
plot_data[plot_data == parent.no_data] = np.nan
plot_data = plot_data[~np.any(np.isnan(plot_data), axis=1)]
cvs = ds.Canvas(plot_width=400, plot_height=400)
agg = cvs.points(plot_data, "hs", "lpmf", ds.count())
hd.datashade(plot_data)
hd.shade(hv.Image(agg))
hv.RGB(np.array(tf.shade(agg).to_pil()))
tf.Image(tf.shade(agg))
import holoviews as hv
hv.extension('bokeh')
from bokeh.plotting import figure, output_file, show
output_file('test_bokeh.html')
p = figure(plot_width=400, plot_height=400)
p.vbar(x=[1, 2, 3], width=0.5, bottom=0, top=[1.2, 2.5, 3.6], color='red')
plot = plot_data.hvplot(kind='scatter', x='hs', y='lpmf', datashade=True)
show(hv.render(plot))
show(p)
