source: trunk/python/asapplotter.py@ 3025

Last change on this file since 3025 was 3016, checked in by Kana Sugimoto, 10 years ago

New Development: No

JIRA Issue: Yes (CAS-CAS-6564)

Ready for Test: Yes

Interface Changes: No

What Interface Changed:

Test Programs: run sdplot with plottype='azel', zoom-in and out to see if the tick interval is kept proper.

Put in Release Notes: No

Module(s): sdplot, asapplotter

Description: Switched off definition of the manual, fixed tick interval in asapplotter.plotazel(). The tick interval is set automatically by matplotlib.


  • Property svn:eol-style set to native
  • Property svn:keywords set to Author Date Id Revision
File size: 85.5 KB
RevLine 
[1824]1from asap.parameters import rcParams
2from asap.selector import selector
3from asap.scantable import scantable
[1862]4from asap.logging import asaplog, asaplog_post_dec
[1153]5import matplotlib.axes
[1556]6from matplotlib.font_manager import FontProperties
7from matplotlib.text import Text
[2535]8from matplotlib import _pylab_helpers
[1556]9
[1317]10import re
[203]11
[2150]12def new_asaplot(visible=None,**kwargs):
13 """
14 Returns a new asaplot instance based on the backend settings.
15 """
16 if visible == None:
17 visible = rcParams['plotter.gui']
18
19 backend=matplotlib.get_backend()
20 if not visible:
21 from asap.asaplot import asaplot
22 elif backend == 'TkAgg':
23 from asap.asaplotgui import asaplotgui as asaplot
24 elif backend == 'Qt4Agg':
25 from asap.asaplotgui_qt4 import asaplotgui as asaplot
26 elif backend == 'GTkAgg':
27 from asap.asaplotgui_gtk import asaplotgui as asaplot
28 else:
29 from asap.asaplot import asaplot
30 return asaplot(**kwargs)
31
[203]32class asapplotter:
[226]33 """
34 The ASAP plotter.
35 By default the plotter is set up to plot polarisations
36 'colour stacked' and scantables across panels.
[1858]37
38 .. note::
39
[226]40 Currenly it only plots 'spectra' not Tsys or
41 other variables.
[1858]42
[226]43 """
[1563]44 def __init__(self, visible=None , **kwargs):
[734]45 self._visible = rcParams['plotter.gui']
46 if visible is not None:
47 self._visible = visible
[2451]48 self._plotter = None
49 self._inikwg = kwargs
[710]50
[2699]51 ### plot settings
[2698]52 self._colormap = None
53 self._linestyles = None
54 self._fp = FontProperties()
55 self._rows = None
56 self._cols = None
57 self._minmaxx = None
58 self._minmaxy = None
59 self._margins = self.set_margin(refresh=False)
60 self._legendloc = None
[2699]61 ### scantable plot settings
[2704]62 self._plotmode = "spectra"
[554]63 self._panelling = None
64 self._stacking = None
65 self.set_panelling()
66 self.set_stacking()
[2698]67 self._hist = rcParams['plotter.histogram']
[2699]68 ### scantable dependent settings
[203]69 self._data = None
[2698]70 self._abcunit = None
71 self._headtext = {'string': None, 'textobj': None}
72 self._selection = selector()
73 self._usermask = []
74 self._maskselection = None
75 self._offset = None
[607]76 self._lmap = None
[226]77 self._title = None
[257]78 self._ordinate = None
79 self._abcissa = None
[2699]80 ### cursors for page iteration
[1981]81 self._startrow = 0
82 self._ipanel = -1
83 self._panelrows = []
[1023]84
[920]85 def _translate(self, instr):
[1910]86 keys = "s b i p t r".split()
[920]87 if isinstance(instr, str):
88 for key in keys:
89 if instr.lower().startswith(key):
90 return key
91 return None
92
[2535]93 @asaplog_post_dec
[2451]94 def _reload_plotter(self):
95 if self._plotter is not None:
[2535]96 #if not self._plotter.is_dead:
97 # # clear lines and axes
98 # try:
99 # self._plotter.clear()
100 # except: # Can't remove when already killed.
101 # pass
[2451]102 if self.casabar_exists():
103 del self._plotter.figmgr.casabar
104 self._plotter.quit()
105 del self._plotter
[2535]106 asaplog.push('Loading new plotter')
[2451]107 self._plotter = new_asaplot(self._visible,**self._inikwg)
108 self._plotter.figmgr.casabar=self._new_custombar()
109 # just to make sure they're set
110 self._plotter.palette(color=0,colormap=self._colormap,
111 linestyle=0,linestyles=self._linestyles)
112 self._plotter.legend(self._legendloc)
[710]113
[2714]114 ### TODO: it's probably better to define following two methods in
115 ### backend dependent class.
[2173]116 def _new_custombar(self):
[1819]117 backend=matplotlib.get_backend()
[2168]118 if not self._visible:
119 return None
120 elif backend == "TkAgg":
[2155]121 from asap.customgui_tkagg import CustomToolbarTkAgg
[1819]122 return CustomToolbarTkAgg(self)
[2168]123 elif backend == "Qt4Agg":
124 from asap.customgui_qt4agg import CustomToolbarQT4Agg
125 return CustomToolbarQT4Agg(self)
[1995]126 return None
[1819]127
[2147]128 def casabar_exists(self):
129 if not hasattr(self._plotter.figmgr,'casabar'):
130 return False
131 elif self._plotter.figmgr.casabar:
132 return True
133 return False
[2714]134 ### end of TODO
[2147]135
[2453]136 def _assert_plotter(self,action="status",errmsg=None):
[2451]137 """
[2453]138 Check plot window status. Returns True if plot window is alive.
[2451]139 Parameters
[2453]140 action: An action to take if the plotter window is not alive.
141 ['status'|'reload'|'halt']
142 The action 'status' simply returns False if asaplot
143 is not alive. When action='reload', plot window is
144 reloaded and the method returns True. Finally, an
145 error is raised when action='halt'.
[2451]146 errmsg: An error (warning) message to send to the logger,
[2453]147 when plot window is not alive.
[2451]148 """
[2538]149 isAlive = (self._plotter is not None) and self._plotter._alive()
[2535]150 # More tests
[2538]151 #if isAlive:
152 # if self._plotter.figmgr:
153 # figmgr = self._plotter.figmgr
154 # figid = figmgr.num
155 # # Make sure figid=0 is what asapplotter expects.
156 # # It might be already destroied/overridden by matplotlib
157 # # commands or other plotting methods using asaplot.
158 # isAlive = _pylab_helpers.Gcf.has_fignum(figid) and \
159 # (figmgr == \
160 # _pylab_helpers.Gcf.get_fig_manager(figid))
161 # else:
162 # isAlive = False
[2535]163
164 if isAlive:
[2451]165 return True
166 # Plotter is not alive.
167 haltmsg = "Plotter window has not yet been loaded or is closed."
168 if type(errmsg)==str and len(errmsg) > 0:
169 haltmsg = errmsg
170
[2453]171 if action.upper().startswith("R"):
[2451]172 # reload plotter
173 self._reload_plotter()
174 return True
[2453]175 elif action.upper().startswith("H"):
[2451]176 # halt
177 asaplog.push(haltmsg)
178 asaplog.post("ERROR")
179 raise RuntimeError(haltmsg)
180 else:
181 if errmsg:
182 asaplog.push(errmsg)
183 asaplog.post("WARN")
184 return False
185
186
[1572]187 def gca(self):
[2451]188 errmsg = "No axis to retun. Need to plot first."
[2453]189 if not self._assert_plotter(action="status",errmsg=errmsg):
[2451]190 return None
[1572]191 return self._plotter.figure.gca()
192
[1550]193 def refresh(self):
[1572]194 """Do a soft refresh"""
[2451]195 errmsg = "No figure to re-plot. Need to plot first."
[2453]196 self._assert_plotter(action="halt",errmsg=errmsg)
[2451]197
[1550]198 self._plotter.figure.show()
199
[2698]200 def save(self, filename=None, orientation=None, dpi=None):
201 """
202 Save the plot to a file. The known formats are 'png', 'ps', 'eps'.
203 Parameters:
204 filename: The name of the output file. This is optional
205 and autodetects the image format from the file
206 suffix. If non filename is specified a file
207 called 'yyyymmdd_hhmmss.png' is created in the
208 current directory.
209 orientation: optional parameter for postscript only (not eps).
210 'landscape', 'portrait' or None (default) are valid.
211 If None is choosen for 'ps' output, the plot is
212 automatically oriented to fill the page.
213 dpi: The dpi of the output non-ps plot
214 """
215 errmsg = "Cannot save figure. Need to plot first."
216 self._assert_plotter(action="halt",errmsg=errmsg)
217
218 self._plotter.save(filename,orientation,dpi)
219 return
220
[1555]221 def create_mask(self, nwin=1, panel=0, color=None):
[1597]222 """
[1927]223 Interactively define a mask. It retruns a mask that is equivalent to
[1597]224 the one created manually with scantable.create_mask.
225 Parameters:
226 nwin: The number of mask windows to create interactively
227 default is 1.
228 panel: Which panel to use for mask selection. This is useful
229 if different IFs are spread over panels (default 0)
230 """
[2451]231 ## this method relies on already plotted figure
[2453]232 if not self._assert_plotter(action="status") or (self._data is None):
[2451]233 msg = "Cannot create mask interactively on plot. Can only create mask after plotting."
234 asaplog.push( msg )
235 asaplog.post( "ERROR" )
[1555]236 return []
[1547]237 outmask = []
[1549]238 self._plotter.subplot(panel)
239 xmin, xmax = self._plotter.axes.get_xlim()
[1548]240 marg = 0.05*(xmax-xmin)
[1549]241 self._plotter.axes.set_xlim(xmin-marg, xmax+marg)
[1550]242 self.refresh()
[1695]243
[1555]244 def cleanup(lines=False, texts=False, refresh=False):
245 if lines:
246 del self._plotter.axes.lines[-1]
247 if texts:
248 del self._plotter.axes.texts[-1]
249 if refresh:
250 self.refresh()
251
252 for w in xrange(nwin):
[1547]253 wpos = []
[1695]254 self.text(0.05,1.0, "Add start boundary",
[1555]255 coords="relative", fontsize=10)
256 point = self._plotter.get_point()
257 cleanup(texts=True)
258 if point is None:
259 continue
260 wpos.append(point[0])
[1695]261 self.axvline(wpos[0], color=color)
[1551]262 self.text(0.05,1.0, "Add end boundary", coords="relative", fontsize=10)
[1555]263 point = self._plotter.get_point()
264 cleanup(texts=True, lines=True)
265 if point is None:
266 self.refresh()
267 continue
268 wpos.append(point[0])
269 self.axvspan(wpos[0], wpos[1], alpha=0.1,
270 edgecolor=color, facecolor=color)
271 ymin, ymax = self._plotter.axes.get_ylim()
[1547]272 outmask.append(wpos)
[1153]273
[1555]274 self._plotter.axes.set_xlim(xmin, xmax)
275 self.refresh()
276 if len(outmask) > 0:
277 return self._data.create_mask(*outmask)
278 return []
279
[2699]280
[2714]281 ### Forwards to methods in matplotlib axes ###
[1153]282 def text(self, *args, **kwargs):
[2453]283 self._assert_plotter(action="reload")
[1547]284 if kwargs.has_key("interactive"):
285 if kwargs.pop("interactive"):
286 pos = self._plotter.get_point()
287 args = tuple(pos)+args
[1153]288 self._axes_callback("text", *args, **kwargs)
[1547]289
[1358]290 text.__doc__ = matplotlib.axes.Axes.text.__doc__
[1559]291
[1153]292 def arrow(self, *args, **kwargs):
[2453]293 self._assert_plotter(action="reload")
[1547]294 if kwargs.has_key("interactive"):
295 if kwargs.pop("interactive"):
296 pos = self._plotter.get_region()
297 dpos = (pos[0][0], pos[0][1],
298 pos[1][0]-pos[0][0],
299 pos[1][1] - pos[0][1])
300 args = dpos + args
[1153]301 self._axes_callback("arrow", *args, **kwargs)
[1547]302
[1358]303 arrow.__doc__ = matplotlib.axes.Axes.arrow.__doc__
[1559]304
305 def annotate(self, text, xy=None, xytext=None, **kwargs):
[2453]306 self._assert_plotter(action="reload")
[1559]307 if kwargs.has_key("interactive"):
308 if kwargs.pop("interactive"):
309 xy = self._plotter.get_point()
310 xytext = self._plotter.get_point()
311 if not kwargs.has_key("arrowprops"):
312 kwargs["arrowprops"] = dict(arrowstyle="->")
313 self._axes_callback("annotate", text, xy, xytext, **kwargs)
314
315 annotate.__doc__ = matplotlib.axes.Axes.annotate.__doc__
316
[1153]317 def axvline(self, *args, **kwargs):
[2453]318 self._assert_plotter(action="reload")
[1547]319 if kwargs.has_key("interactive"):
320 if kwargs.pop("interactive"):
321 pos = self._plotter.get_point()
322 args = (pos[0],)+args
[1153]323 self._axes_callback("axvline", *args, **kwargs)
[1559]324
[1358]325 axvline.__doc__ = matplotlib.axes.Axes.axvline.__doc__
[1547]326
[1153]327 def axhline(self, *args, **kwargs):
[2453]328 self._assert_plotter(action="reload")
[1547]329 if kwargs.has_key("interactive"):
330 if kwargs.pop("interactive"):
331 pos = self._plotter.get_point()
332 args = (pos[1],)+args
[1153]333 self._axes_callback("axhline", *args, **kwargs)
[1559]334
[1358]335 axhline.__doc__ = matplotlib.axes.Axes.axhline.__doc__
[1547]336
[1153]337 def axvspan(self, *args, **kwargs):
[2453]338 self._assert_plotter(action="reload")
[1547]339 if kwargs.has_key("interactive"):
340 if kwargs.pop("interactive"):
341 pos = self._plotter.get_region()
342 dpos = (pos[0][0], pos[1][0])
343 args = dpos + args
[1153]344 self._axes_callback("axvspan", *args, **kwargs)
345 # hack to preventy mpl from redrawing the patch
346 # it seem to convert the patch into lines on every draw.
347 # This doesn't happen in a test script???
[1547]348 #del self._plotter.axes.patches[-1]
349
[1358]350 axvspan.__doc__ = matplotlib.axes.Axes.axvspan.__doc__
[1232]351
[1153]352 def axhspan(self, *args, **kwargs):
[2453]353 self._assert_plotter(action="reload")
[1547]354 if kwargs.has_key("interactive"):
355 if kwargs.pop("interactive"):
356 pos = self._plotter.get_region()
357 dpos = (pos[0][1], pos[1][1])
358 args = dpos + args
[1232]359 self._axes_callback("axhspan", *args, **kwargs)
[1153]360 # hack to preventy mpl from redrawing the patch
361 # it seem to convert the patch into lines on every draw.
362 # This doesn't happen in a test script???
[1547]363 #del self._plotter.axes.patches[-1]
[1559]364
[1358]365 axhspan.__doc__ = matplotlib.axes.Axes.axhspan.__doc__
[1153]366
367 def _axes_callback(self, axesfunc, *args, **kwargs):
[2453]368 self._assert_plotter(action="reload")
[1153]369 panel = 0
370 if kwargs.has_key("panel"):
371 panel = kwargs.pop("panel")
372 coords = None
373 if kwargs.has_key("coords"):
374 coords = kwargs.pop("coords")
375 if coords.lower() == 'world':
376 kwargs["transform"] = self._plotter.axes.transData
377 elif coords.lower() == 'relative':
378 kwargs["transform"] = self._plotter.axes.transAxes
379 self._plotter.subplot(panel)
380 self._plotter.axes.set_autoscale_on(False)
381 getattr(self._plotter.axes, axesfunc)(*args, **kwargs)
382 self._plotter.show(False)
383 self._plotter.axes.set_autoscale_on(True)
384 # end matplotlib.axes fowarding functions
385
[2699]386
387 ### Forwards to matplotlib.Figure.text ###
[2698]388 def figtext(self, *args, **kwargs):
389 """
390 Add text to figure at location x,y (relative 0-1 coords).
391 This method forwards *args and **kwargs to a Matplotlib method,
392 matplotlib.Figure.text.
393 See the method help for detailed information.
394 """
395 self._assert_plotter(action="reload")
396 self._plotter.text(*args, **kwargs)
397 # end matplotlib.Figure.text forwarding function
398
[2699]399
400 ### Set Plot parameters ###
[1862]401 @asaplog_post_dec
[1819]402 def set_data(self, scan, refresh=True):
403 """
[1824]404 Set a scantable to plot.
[1819]405 Parameters:
406 scan: a scantable
407 refresh: True (default) or False. If True, the plot is
[1824]408 replotted based on the new parameter setting(s).
[1819]409 Otherwise,the parameter(s) are set without replotting.
410 Note:
411 The user specified masks and data selections will be reset
412 if a new scantable is set. This method should be called before
[1824]413 setting data selections (set_selection) and/or masks (set_mask).
[1819]414 """
415 from asap import scantable
416 if isinstance(scan, scantable):
[2604]417 if (self._data is not None) and (scan != self._data):
418 del self._data
419 msg = "A new scantable is set to the plotter. "\
[2714]420 "The masks, data selections, and labels are reset."
421 asaplog.push(msg)
[2604]422 self._data = scan
423 # reset
424 self._reset()
[1819]425 else:
426 msg = "Input is not a scantable"
427 raise TypeError(msg)
[1547]428
[1819]429 # ranges become invalid when unit changes
430 if self._abcunit and self._abcunit != self._data.get_unit():
431 self._minmaxx = None
432 self._minmaxy = None
433 self._abcunit = self._data.get_unit()
434 if refresh: self.plot()
435
[1862]436 @asaplog_post_dec
[1819]437 def set_mode(self, stacking=None, panelling=None, refresh=True):
[203]438 """
[377]439 Set the plots look and feel, i.e. what you want to see on the plot.
[203]440 Parameters:
441 stacking: tell the plotter which variable to plot
[1217]442 as line colour overlays (default 'pol')
[203]443 panelling: tell the plotter which variable to plot
444 across multiple panels (default 'scan'
[1819]445 refresh: True (default) or False. If True, the plot is
[1824]446 replotted based on the new parameter setting(s).
[1819]447 Otherwise,the parameter(s) are set without replotting.
[203]448 Note:
449 Valid modes are:
450 'beam' 'Beam' 'b': Beams
451 'if' 'IF' 'i': IFs
452 'pol' 'Pol' 'p': Polarisations
453 'scan' 'Scan' 's': Scans
454 'time' 'Time' 't': Times
[1989]455 'row' 'Row' 'r': Rows
456 When either 'stacking' or 'panelling' is set to 'row',
457 the other parameter setting is ignored.
[203]458 """
[753]459 msg = "Invalid mode"
460 if not self.set_panelling(panelling) or \
461 not self.set_stacking(stacking):
[1859]462 raise TypeError(msg)
[1989]463 #if self._panelling == 'r':
464 # self._stacking = '_r'
465 #if self._stacking == 'r':
466 # self._panelling = '_r'
[1819]467 if refresh and self._data: self.plot(self._data)
[203]468 return
469
[2698]470 def set_stacking(self, what=None):
471 """Set the 'stacking' mode i.e. which type of spectra should be
472 overlayed.
473 """
474 mode = what
475 if mode is None:
476 mode = rcParams['plotter.stacking']
477 md = self._translate(mode)
478 if md:
479 self._stacking = md
480 self._lmap = None
481 # new mode is set. need to reset counters for multi page plotting
482 self._reset_counters()
483 return True
484 return False
485
[554]486 def set_panelling(self, what=None):
[1858]487 """Set the 'panelling' mode i.e. which type of spectra should be
488 spread across different panels.
489 """
490
[554]491 mode = what
492 if mode is None:
493 mode = rcParams['plotter.panelling']
494 md = self._translate(mode)
[203]495 if md:
[554]496 self._panelling = md
[226]497 self._title = None
[2698]498 # new mode is set. need to reset counters for multi page plotting
[1981]499 self._reset_counters()
[203]500 return True
501 return False
502
[1819]503 def set_layout(self,rows=None,cols=None,refresh=True):
[377]504 """
505 Set the multi-panel layout, i.e. how many rows and columns plots
506 are visible.
507 Parameters:
508 rows: The number of rows of plots
509 cols: The number of columns of plots
[1819]510 refresh: True (default) or False. If True, the plot is
[1824]511 replotted based on the new parameter setting(s).
[1819]512 Otherwise,the parameter(s) are set without replotting.
[377]513 Note:
514 If no argument is given, the potter reverts to its auto-plot
515 behaviour.
516 """
517 self._rows = rows
518 self._cols = cols
[2715]519 # new layout is set. need to reset counters for multi page plotting
520 self._reset_counters()
[1819]521 if refresh and self._data: self.plot(self._data)
[377]522 return
523
[1897]524 def set_range(self,xstart=None,xend=None,ystart=None,yend=None,refresh=True, offset=None):
[203]525 """
526 Set the range of interest on the abcissa of the plot
527 Parameters:
[525]528 [x,y]start,[x,y]end: The start and end points of the 'zoom' window
[1819]529 refresh: True (default) or False. If True, the plot is
[1824]530 replotted based on the new parameter setting(s).
[1819]531 Otherwise,the parameter(s) are set without replotting.
[1897]532 offset: shift the abcissa by the given amount. The abcissa label will
533 have '(relative)' appended to it.
[203]534 Note:
535 These become non-sensical when the unit changes.
536 use plotter.set_range() without parameters to reset
537
538 """
[1897]539 self._offset = offset
[525]540 if xstart is None and xend is None:
541 self._minmaxx = None
[600]542 else:
543 self._minmaxx = [xstart,xend]
[525]544 if ystart is None and yend is None:
545 self._minmaxy = None
[600]546 else:
[709]547 self._minmaxy = [ystart,yend]
[1819]548 if refresh and self._data: self.plot(self._data)
[203]549 return
[709]550
[1819]551 def set_legend(self, mp=None, fontsize = None, mode = 0, refresh=True):
[203]552 """
553 Specify a mapping for the legend instead of using the default
554 indices:
555 Parameters:
[1101]556 mp: a list of 'strings'. This should have the same length
557 as the number of elements on the legend and then maps
558 to the indeces in order. It is possible to uses latex
559 math expression. These have to be enclosed in r'',
560 e.g. r'$x^{2}$'
561 fontsize: The font size of the label (default None)
562 mode: where to display the legend
563 Any other value for loc else disables the legend:
[1096]564 0: auto
565 1: upper right
566 2: upper left
567 3: lower left
568 4: lower right
569 5: right
570 6: center left
571 7: center right
572 8: lower center
573 9: upper center
574 10: center
[1819]575 refresh: True (default) or False. If True, the plot is
[1824]576 replotted based on the new parameter setting(s).
[1819]577 Otherwise,the parameter(s) are set without replotting.
[203]578
579 Example:
[485]580 If the data has two IFs/rest frequencies with index 0 and 1
[203]581 for CO and SiO:
582 plotter.set_stacking('i')
[710]583 plotter.set_legend(['CO','SiO'])
[203]584 plotter.plot()
[710]585 plotter.set_legend([r'$^{12}CO$', r'SiO'])
[203]586 """
587 self._lmap = mp
[2451]588 #self._plotter.legend(mode)
589 self._legendloc = mode
[1101]590 if isinstance(fontsize, int):
591 from matplotlib import rc as rcp
592 rcp('legend', fontsize=fontsize)
[1819]593 if refresh and self._data: self.plot(self._data)
[226]594 return
595
[1819]596 def set_title(self, title=None, fontsize=None, refresh=True):
[710]597 """
[2451]598 Set the title of sub-plots. If multiple sub-plots are plotted,
[710]599 multiple titles have to be specified.
[1819]600 Parameters:
[2451]601 title: a list of titles of sub-plots.
602 fontsize: a font size of titles (integer)
[1819]603 refresh: True (default) or False. If True, the plot is
[1824]604 replotted based on the new parameter setting(s).
[1819]605 Otherwise,the parameter(s) are set without replotting.
[710]606 Example:
607 # two panels are visible on the plotter
[2451]608 plotter.set_title(['First Panel','Second Panel'])
[710]609 """
[226]610 self._title = title
[1101]611 if isinstance(fontsize, int):
612 from matplotlib import rc as rcp
613 rcp('axes', titlesize=fontsize)
[1819]614 if refresh and self._data: self.plot(self._data)
[226]615 return
616
[1819]617 def set_ordinate(self, ordinate=None, fontsize=None, refresh=True):
[710]618 """
619 Set the y-axis label of the plot. If multiple panels are plotted,
620 multiple labels have to be specified.
[1021]621 Parameters:
622 ordinate: a list of ordinate labels. None (default) let
623 data determine the labels
[2451]624 fontsize: a font size of vertical axis labels (integer)
[1819]625 refresh: True (default) or False. If True, the plot is
[1824]626 replotted based on the new parameter setting(s).
[1819]627 Otherwise,the parameter(s) are set without replotting.
[710]628 Example:
629 # two panels are visible on the plotter
[2451]630 plotter.set_ordinate(['First Y-Axis','Second Y-Axis'])
[710]631 """
[257]632 self._ordinate = ordinate
[1101]633 if isinstance(fontsize, int):
634 from matplotlib import rc as rcp
635 rcp('axes', labelsize=fontsize)
636 rcp('ytick', labelsize=fontsize)
[1819]637 if refresh and self._data: self.plot(self._data)
[257]638 return
639
[1819]640 def set_abcissa(self, abcissa=None, fontsize=None, refresh=True):
[710]641 """
642 Set the x-axis label of the plot. If multiple panels are plotted,
643 multiple labels have to be specified.
[1021]644 Parameters:
645 abcissa: a list of abcissa labels. None (default) let
646 data determine the labels
[2451]647 fontsize: a font size of horizontal axis labels (integer)
[1819]648 refresh: True (default) or False. If True, the plot is
[1824]649 replotted based on the new parameter setting(s).
[1819]650 Otherwise,the parameter(s) are set without replotting.
[710]651 Example:
652 # two panels are visible on the plotter
[2451]653 plotter.set_ordinate(['First X-Axis','Second X-Axis'])
[710]654 """
[257]655 self._abcissa = abcissa
[1101]656 if isinstance(fontsize, int):
657 from matplotlib import rc as rcp
658 rcp('axes', labelsize=fontsize)
659 rcp('xtick', labelsize=fontsize)
[1819]660 if refresh and self._data: self.plot(self._data)
[257]661 return
662
[2700]663 def set_histogram(self, hist=True, linewidth=None, refresh=True):
664 """
665 Enable/Disable histogram-like plotting.
666 Parameters:
667 hist: True (default) or False. The fisrt default
668 is taken from the .asaprc setting
669 plotter.histogram
670 linewidth: a line width
671 refresh: True (default) or False. If True, the plot is
672 replotted based on the new parameter setting(s).
673 Otherwise,the parameter(s) are set without replotting.
674 """
675 self._hist = hist
676 if isinstance(linewidth, float) or isinstance(linewidth, int):
677 from matplotlib import rc as rcp
678 rcp('lines', linewidth=linewidth)
679 if refresh and self._data: self.plot(self._data)
680
[1819]681 def set_colors(self, colmap, refresh=True):
[377]682 """
[1217]683 Set the colours to be used. The plotter will cycle through
684 these colours when lines are overlaid (stacking mode).
[1021]685 Parameters:
[1217]686 colmap: a list of colour names
[1819]687 refresh: True (default) or False. If True, the plot is
[1824]688 replotted based on the new parameter setting(s).
[1819]689 Otherwise,the parameter(s) are set without replotting.
[710]690 Example:
[2451]691 plotter.set_colors('red green blue')
[710]692 # If for example four lines are overlaid e.g I Q U V
693 # 'I' will be 'red', 'Q' will be 'green', U will be 'blue'
694 # and 'V' will be 'red' again.
695 """
[2451]696 #if isinstance(colmap,str):
697 # colmap = colmap.split()
698 #self._plotter.palette(0, colormap=colmap)
699 self._colormap = colmap
[1819]700 if refresh and self._data: self.plot(self._data)
[710]701
[1217]702 # alias for english speakers
703 set_colours = set_colors
704
[1819]705 def set_linestyles(self, linestyles=None, linewidth=None, refresh=True):
[710]706 """
[734]707 Set the linestyles to be used. The plotter will cycle through
708 these linestyles when lines are overlaid (stacking mode) AND
709 only one color has been set.
[710]710 Parameters:
[2451]711 linestyles: a list of linestyles to use.
[710]712 'line', 'dashed', 'dotted', 'dashdot',
713 'dashdotdot' and 'dashdashdot' are
714 possible
[2451]715 linewidth: a line width
[1819]716 refresh: True (default) or False. If True, the plot is
[1824]717 replotted based on the new parameter setting(s).
[1819]718 Otherwise,the parameter(s) are set without replotting.
[710]719 Example:
[2451]720 plotter.set_colors('black')
721 plotter.set_linestyles('line dashed dotted dashdot')
[710]722 # If for example four lines are overlaid e.g I Q U V
723 # 'I' will be 'solid', 'Q' will be 'dashed',
724 # U will be 'dotted' and 'V' will be 'dashdot'.
725 """
[2451]726 #if isinstance(linestyles,str):
727 # linestyles = linestyles.split()
728 #self._plotter.palette(color=0,linestyle=0,linestyles=linestyles)
729 self._linestyles = linestyles
[1101]730 if isinstance(linewidth, float) or isinstance(linewidth, int):
731 from matplotlib import rc as rcp
732 rcp('lines', linewidth=linewidth)
[1819]733 if refresh and self._data: self.plot(self._data)
[710]734
[1819]735 def set_font(self, refresh=True,**kwargs):
[1101]736 """
737 Set font properties.
738 Parameters:
739 family: one of 'sans-serif', 'serif', 'cursive', 'fantasy', 'monospace'
740 style: one of 'normal' (or 'roman'), 'italic' or 'oblique'
741 weight: one of 'normal or 'bold'
742 size: the 'general' font size, individual elements can be adjusted
743 seperately
[1819]744 refresh: True (default) or False. If True, the plot is
[1824]745 replotted based on the new parameter setting(s).
[1819]746 Otherwise,the parameter(s) are set without replotting.
[1101]747 """
748 from matplotlib import rc as rcp
[1547]749 fdict = {}
750 for k,v in kwargs.iteritems():
751 if v:
752 fdict[k] = v
[1556]753 self._fp = FontProperties(**fdict)
[1819]754 if refresh and self._data: self.plot(self._data)
[1101]755
[2037]756 def set_margin(self,margin=[],refresh=True):
[1819]757 """
[2037]758 Set margins between subplots and plot edges.
[1819]759 Parameters:
[2037]760 margin: a list of margins in figure coordinate (0-1),
[1824]761 i.e., fraction of the figure width or height.
[1819]762 The order of elements should be:
763 [left, bottom, right, top, horizontal space btw panels,
[1824]764 vertical space btw panels].
[1819]765 refresh: True (default) or False. If True, the plot is
[1824]766 replotted based on the new parameter setting(s).
[1819]767 Otherwise,the parameter(s) are set without replotting.
768 Note
[2037]769 * When margin is not specified, the values are reset to the defaults
[1819]770 of matplotlib.
[1824]771 * If any element is set to be None, the current value is adopted.
[1819]772 """
[2037]773 if margin == []: self._margins=self._reset_margin()
[1824]774 else:
[2037]775 self._margins=[None]*6
776 self._margins[0:len(margin)]=margin
777 #print "panel margin set to ",self._margins
[1819]778 if refresh and self._data: self.plot(self._data)
779
[2037]780 def _reset_margin(self):
[1819]781 ks=map(lambda x: 'figure.subplot.'+x,
782 ['left','bottom','right','top','hspace','wspace'])
783 return map(matplotlib.rcParams.get,ks)
784
[1259]785 def plot_lines(self, linecat=None, doppler=0.0, deltachan=10, rotate=90.0,
[1146]786 location=None):
787 """
[1158]788 Plot a line catalog.
789 Parameters:
790 linecat: the linecatalog to plot
[1168]791 doppler: the velocity shift to apply to the frequencies
[1158]792 deltachan: the number of channels to include each side of the
793 line to determine a local maximum/minimum
[1927]794 rotate: the rotation (in degrees) for the text label (default 90.0)
[1158]795 location: the location of the line annotation from the 'top',
796 'bottom' or alternate (None - the default)
[1165]797 Notes:
798 If the spectrum is flagged no line will be drawn in that location.
[1146]799 """
[2451]800 errmsg = "Cannot plot spectral lines. Need to plot scantable first."
[2453]801 self._assert_plotter(action="halt",errmsg=errmsg)
[1259]802 if not self._data:
803 raise RuntimeError("No scantable has been plotted yet.")
[1146]804 from asap._asap import linecatalog
[1259]805 if not isinstance(linecat, linecatalog):
806 raise ValueError("'linecat' isn't of type linecatalog.")
807 if not self._data.get_unit().endswith("Hz"):
808 raise RuntimeError("Can only overlay linecatalogs when data is in frequency.")
[1739]809 from numpy import ma
[1146]810 for j in range(len(self._plotter.subplots)):
811 self._plotter.subplot(j)
812 lims = self._plotter.axes.get_xlim()
[1153]813 for row in range(linecat.nrow()):
[1259]814 # get_frequency returns MHz
815 base = { "GHz": 1000.0, "MHz": 1.0, "Hz": 1.0e-6 }
816 restf = linecat.get_frequency(row)/base[self._data.get_unit()]
[1165]817 c = 299792.458
[1174]818 freq = restf*(1.0-doppler/c)
[1146]819 if lims[0] < freq < lims[1]:
820 if location is None:
821 loc = 'bottom'
[1153]822 if row%2: loc='top'
[1146]823 else: loc = location
[1153]824 maxys = []
825 for line in self._plotter.axes.lines:
826 v = line._x
827 asc = v[0] < v[-1]
828
829 idx = None
830 if not asc:
831 if v[len(v)-1] <= freq <= v[0]:
832 i = len(v)-1
833 while i>=0 and v[i] < freq:
834 idx = i
835 i-=1
836 else:
837 if v[0] <= freq <= v[len(v)-1]:
838 i = 0
839 while i<len(v) and v[i] < freq:
840 idx = i
841 i+=1
842 if idx is not None:
843 lower = idx - deltachan
844 upper = idx + deltachan
845 if lower < 0: lower = 0
846 if upper > len(v): upper = len(v)
847 s = slice(lower, upper)
[1167]848 y = line._y[s]
[1165]849 maxy = ma.maximum(y)
850 if isinstance( maxy, float):
851 maxys.append(maxy)
[1164]852 if len(maxys):
853 peak = max(maxys)
[1165]854 if peak > self._plotter.axes.get_ylim()[1]:
855 loc = 'bottom'
[1164]856 else:
857 continue
[1157]858 self._plotter.vline_with_label(freq, peak,
859 linecat.get_name(row),
860 location=loc, rotate=rotate)
[1153]861 self._plotter.show(hardrefresh=False)
[1146]862
[1153]863
[2698]864 def set_selection(self, selection=None, refresh=True, **kw):
[710]865 """
[377]866 Parameters:
[2698]867 selection: a selector object (default unset the selection)
868 refresh: True (default) or False. If True, the plot is
869 replotted based on the new parameter setting(s).
870 Otherwise,the parameter(s) are set without replotting.
[377]871 """
[2698]872 if selection is None:
873 # reset
874 if len(kw) == 0:
875 self._selection = selector()
876 else:
877 # try keywords
878 for k in kw:
879 if k not in selector.fields:
880 raise KeyError("Invalid selection key '%s', valid keys are %s" % (k, selector.fields))
881 self._selection = selector(**kw)
882 elif isinstance(selection, selector):
883 self._selection = selection
884 else:
885 raise TypeError("'selection' is not of type selector")
[709]886
[2698]887 order = self._get_sortstring([self._panelling,self._stacking])
888 if order:
889 self._selection.set_order(order)
890 if refresh and self._data:
891 self.plot()
892
[1862]893 @asaplog_post_dec
[1819]894 def set_mask(self, mask=None, selection=None, refresh=True):
[525]895 """
[734]896 Set a plotting mask for a specific polarization.
[2451]897 This is useful for masking out 'noise' Pangle outside a source.
[734]898 Parameters:
[920]899 mask: a mask from scantable.create_mask
900 selection: the spectra to apply the mask to.
[1819]901 refresh: True (default) or False. If True, the plot is
[1824]902 replotted based on the new parameter setting(s).
[1819]903 Otherwise,the parameter(s) are set without replotting.
[734]904 Example:
[920]905 select = selector()
[2451]906 select.setpolstrings('Pangle')
[920]907 plotter.set_mask(mymask, select)
[734]908 """
[710]909 if not self._data:
[920]910 msg = "Can only set mask after a first call to plot()"
[1859]911 raise RuntimeError(msg)
[2714]912 if (mask is not None) and len(mask):
[920]913 if isinstance(mask, list) or isinstance(mask, tuple):
914 self._usermask = array(mask)
[710]915 else:
[920]916 self._usermask = mask
917 if mask is None and selection is None:
918 self._usermask = []
919 self._maskselection = None
920 if isinstance(selection, selector):
[947]921 self._maskselection = {'b': selection.get_beams(),
922 's': selection.get_scans(),
923 'i': selection.get_ifs(),
924 'p': selection.get_pols(),
[920]925 't': [] }
[710]926 else:
[920]927 self._maskselection = None
[1819]928 if refresh: self.plot(self._data)
[710]929
[709]930
[2699]931 ### Reset methods ###
[710]932 def _reset(self):
[2714]933 """Reset method called when new data is set"""
934 # reset selections and masks
935 self.set_selection(None, False)
936 self.set_mask(None, None, False)
937 # reset offset
[1897]938 self._offset = None
[2714]939 # reset header
[2051]940 self._reset_header()
[2714]941 # reset labels
942 self._lmap = None # related to stack
943 self.set_title(None, None, False)
944 self.set_ordinate(None, None, False)
945 self.set_abcissa(None, None, False)
[920]946
[2051]947 def _reset_header(self):
[2053]948 self._headtext={'string': None, 'textobj': None}
[2051]949
[2697]950 def _reset_counter(self):
951 self._startrow = 0
952 self._ipanel = -1
[2715]953 self._panelrows = []
[2697]954 self._reset_header()
955 if self.casabar_exists():
956 self._plotter.figmgr.casabar.set_pagecounter(1)
957
[2698]958 def _reset_counters(self):
959 self._startrow = 0
960 self._ipanel = -1
961 self._panelrows = []
962
[2699]963
964 ### Actual scantable plot methods ###
[2698]965 @asaplog_post_dec
966 def plot(self, scan=None):
967 """
968 Plot a scantable.
969 Parameters:
970 scan: a scantable
971 Note:
972 If a scantable was specified in a previous call
973 to plot, no argument has to be given to 'replot'
974 NO checking is done that the abcissas of the scantable
975 are consistent e.g. all 'channel' or all 'velocity' etc.
976 """
[2704]977 self._plotmode = "spectra"
[2698]978 if not self._data and not scan:
979 msg = "Input is not a scantable"
980 raise TypeError(msg)
981
982 self._assert_plotter(action="reload")
983 self._plotter.hold()
984 self._reset_counter()
985 #self._plotter.clear()
986 if scan:
987 self.set_data(scan, refresh=False)
988 self._plotter.palette(color=0,colormap=self._colormap,
989 linestyle=0,linestyles=self._linestyles)
990 self._plotter.legend(self._legendloc)
991 self._plot(self._data)
992 if self._minmaxy is not None:
993 self._plotter.set_limits(ylim=self._minmaxy)
994 if self.casabar_exists(): self._plotter.figmgr.casabar.enable_button()
995 self._plotter.release()
996 self._plotter.tidy()
997 self._plotter.show(hardrefresh=False)
998 return
999
[920]1000 def _plot(self, scan):
[947]1001 savesel = scan.get_selection()
1002 sel = savesel + self._selection
[1910]1003 order = self._get_sortstring([self._panelling,self._stacking])
1004 if order:
1005 sel.set_order(order)
[947]1006 scan.set_selection(sel)
[920]1007 d = {'b': scan.getbeam, 's': scan.getscan,
[1949]1008 'i': scan.getif, 'p': scan.getpol, 't': scan.get_time,
[1989]1009 'r': int}#, '_r': int}
[920]1010
[2650]1011 polmodes = dict(zip(sel.get_pols(), sel.get_poltypes()))
[1148]1012 # this returns either a tuple of numbers or a length (ncycles)
1013 # convert this into lengths
1014 n0,nstack0 = self._get_selected_n(scan)
1015 if isinstance(n0, int): n = n0
[1175]1016 else: n = len(n0)
[1148]1017 if isinstance(nstack0, int): nstack = nstack0
[1175]1018 else: nstack = len(nstack0)
[1989]1019 # In case of row stacking
1020 rowstack = False
1021 titlemode = self._panelling
1022 if self._stacking == "r" and self._panelling != "r":
1023 rowstack = True
1024 titlemode = '_r'
[1913]1025 nptot = n
[1582]1026 maxpanel, maxstack = 16,16
[1913]1027 if nstack > maxstack:
1028 msg ="Scan to be overlayed contains more than %d selections.\n" \
1029 "Selecting first %d selections..." % (maxstack, maxstack)
[920]1030 asaplog.push(msg)
[1861]1031 asaplog.post('WARN')
[998]1032 nstack = min(nstack,maxstack)
[2038]1033 #n = min(n-self._ipanel-1,maxpanel)
1034 n = n-self._ipanel-1
[2697]1035 # the number of panels in this page
1036 if self._rows and self._cols:
1037 n = min(n,self._rows*self._cols)
1038 else:
1039 n = min(n,maxpanel)
[2011]1040
[2697]1041 firstpage = (self._ipanel < 0)
1042 #ganged = False
1043 ganged = rcParams['plotter.ganged']
1044 if self._panelling == 'i':
1045 ganged = False
[2715]1046 if (not firstpage) and \
1047 self._plotter._subplotsOk(self._rows, self._cols, n):
1048 # Not the first page and subplot number is ok.
1049 # Just clear the axis
[2697]1050 nx = self._plotter.cols
1051 ipaxx = n - nx - 1 #the max panel id to supress x-label
1052 for ip in xrange(len(self._plotter.subplots)):
1053 self._plotter.subplot(ip)
1054 self._plotter.clear()
1055 self._plotter.axes.set_visible((ip<n))
1056 if ganged:
1057 self._plotter.axes.xaxis.label.set_visible((ip > ipaxx))
1058 if ip <= ipaxx:
1059 map(lambda x: x.set_visible(False), \
1060 self._plotter.axes.get_xticklabels())
1061 self._plotter.axes.yaxis.label.set_visible((ip % nx)==0)
1062 if ip % nx:
1063 map(lambda y: y.set_visible(False), \
1064 self._plotter.axes.get_yticklabels())
1065 elif (n > 1 and self._rows and self._cols):
[920]1066 self._plotter.set_panels(rows=self._rows,cols=self._cols,
[2650]1067 nplots=n,margin=self._margins,
1068 ganged=ganged)
[920]1069 else:
[2697]1070 self._plotter.set_panels(rows=n,cols=0,nplots=n,
1071 margin=self._margins,ganged=ganged)
[1913]1072 #r = 0
[1981]1073 r = self._startrow
[920]1074 nr = scan.nrow()
1075 a0,b0 = -1,-1
1076 allxlim = []
[1018]1077 allylim = []
[1981]1078 #newpanel=True
1079 newpanel=False
[920]1080 panelcount,stackcount = 0,0
[1981]1081 # If this is not the first page
1082 if r > 0:
1083 # panelling value of the prev page
1084 a0 = d[self._panelling](r-1)
1085 # set the initial stackcount large not to plot
1086 # the start row automatically
1087 stackcount = nstack
1088
[1002]1089 while r < nr:
[920]1090 a = d[self._panelling](r)
1091 b = d[self._stacking](r)
1092 if a > a0 and panelcount < n:
1093 if n > 1:
1094 self._plotter.subplot(panelcount)
1095 self._plotter.palette(0)
1096 #title
1097 xlab = self._abcissa and self._abcissa[panelcount] \
1098 or scan._getabcissalabel()
[1897]1099 if self._offset and not self._abcissa:
1100 xlab += " (relative)"
[920]1101 ylab = self._ordinate and self._ordinate[panelcount] \
1102 or scan._get_ordinate_label()
[1547]1103 self._plotter.set_axes('xlabel', xlab)
1104 self._plotter.set_axes('ylabel', ylab)
[1989]1105 #lbl = self._get_label(scan, r, self._panelling, self._title)
1106 lbl = self._get_label(scan, r, titlemode, self._title)
[920]1107 if isinstance(lbl, list) or isinstance(lbl, tuple):
1108 if 0 <= panelcount < len(lbl):
1109 lbl = lbl[panelcount]
1110 else:
1111 # get default label
[1989]1112 #lbl = self._get_label(scan, r, self._panelling, None)
1113 lbl = self._get_label(scan, r, titlemode, None)
[920]1114 self._plotter.set_axes('title',lbl)
1115 newpanel = True
[1913]1116 stackcount = 0
[920]1117 panelcount += 1
[1981]1118 # save the start row to plot this panel for future revisit.
1119 if self._panelling != 'r' and \
1120 len(self._panelrows) < self._ipanel+1+panelcount:
1121 self._panelrows += [r]
1122
[1944]1123 #if (b > b0 or newpanel) and stackcount < nstack:
[2650]1124 if stackcount < nstack and (newpanel or \
1125 rowstack or (a == a0 and b > b0)):
[920]1126 y = []
1127 if len(polmodes):
1128 y = scan._getspectrum(r, polmodes[scan.getpol(r)])
1129 else:
1130 y = scan._getspectrum(r)
[1995]1131 # flag application
1132 mr = scan._getflagrow(r)
[1739]1133 from numpy import ma, array
[1995]1134 if mr:
1135 y = ma.masked_array(y,mask=mr)
1136 else:
1137 m = scan._getmask(r)
1138 from numpy import logical_not, logical_and
1139 if self._maskselection and len(self._usermask) == len(m):
[2277]1140 if d[self._stacking](r) in self._maskselection[self._stacking]:
[1995]1141 m = logical_and(m, self._usermask)
[2277]1142 y = ma.masked_array(y,mask=logical_not(array(m,copy=False)))
[1995]1143
[1897]1144 x = array(scan._getabcissa(r))
1145 if self._offset:
1146 x += self._offset
[920]1147 if self._minmaxx is not None:
1148 s,e = self._slice_indeces(x)
1149 x = x[s:e]
1150 y = y[s:e]
[1096]1151 if len(x) > 1024 and rcParams['plotter.decimate']:
1152 fac = len(x)/1024
[920]1153 x = x[::fac]
1154 y = y[::fac]
1155 llbl = self._get_label(scan, r, self._stacking, self._lmap)
1156 if isinstance(llbl, list) or isinstance(llbl, tuple):
1157 if 0 <= stackcount < len(llbl):
1158 # use user label
1159 llbl = llbl[stackcount]
1160 else:
1161 # get default label
1162 llbl = self._get_label(scan, r, self._stacking, None)
1163 self._plotter.set_line(label=llbl)
[1023]1164 plotit = self._plotter.plot
1165 if self._hist: plotit = self._plotter.hist
[1995]1166 if len(x) > 0 and not mr:
[1146]1167 plotit(x,y)
1168 xlim= self._minmaxx or [min(x),max(x)]
1169 allxlim += xlim
1170 ylim= self._minmaxy or [ma.minimum(y),ma.maximum(y)]
1171 allylim += ylim
[1819]1172 else:
1173 xlim = self._minmaxx or []
1174 allxlim += xlim
1175 ylim= self._minmaxy or []
1176 allylim += ylim
[920]1177 stackcount += 1
[1981]1178 a0=a
1179 b0=b
[920]1180 # last in colour stack -> autoscale x
[1819]1181 if stackcount == nstack and len(allxlim) > 0:
[920]1182 allxlim.sort()
[1819]1183 self._plotter.subplots[panelcount-1]['axes'].set_xlim([allxlim[0],allxlim[-1]])
[1989]1184 if ganged:
1185 allxlim = [allxlim[0],allxlim[-1]]
1186 else:
1187 # clear
1188 allxlim =[]
[920]1189
1190 newpanel = False
[1981]1191 #a0=a
1192 #b0=b
[920]1193 # ignore following rows
[1981]1194 if (panelcount == n and stackcount == nstack) or (r == nr-1):
[1018]1195 # last panel -> autoscale y if ganged
[1989]1196 #if rcParams['plotter.ganged'] and len(allylim) > 0:
1197 if ganged and len(allylim) > 0:
[1018]1198 allylim.sort()
1199 self._plotter.set_limits(ylim=[allylim[0],allylim[-1]])
[998]1200 break
[920]1201 r+=1 # next row
[1981]1202
1203 # save the current counter for multi-page plotting
1204 self._startrow = r+1
1205 self._ipanel += panelcount
[2147]1206 if self.casabar_exists():
[1981]1207 if self._ipanel >= nptot-1:
[1913]1208 self._plotter.figmgr.casabar.disable_next()
1209 else:
1210 self._plotter.figmgr.casabar.enable_next()
[1981]1211 if self._ipanel + 1 - panelcount > 0:
1212 self._plotter.figmgr.casabar.enable_prev()
1213 else:
1214 self._plotter.figmgr.casabar.disable_prev()
1215
[947]1216 #reset the selector to the scantable's original
1217 scan.set_selection(savesel)
[1824]1218
[1819]1219 #temporary switch-off for older matplotlib
1220 #if self._fp is not None:
[2698]1221 if self._fp is not None and \
1222 getattr(self._plotter.figure,'findobj',False):
[1556]1223 for o in self._plotter.figure.findobj(Text):
[2697]1224 if not self._headtext['textobj'] or \
1225 not (o in self._headtext['textobj']):
1226 o.set_fontproperties(self._fp)
[920]1227
[1910]1228 def _get_sortstring(self, lorders):
1229 d0 = {'s': 'SCANNO', 'b': 'BEAMNO', 'i':'IFNO',
1230 'p': 'POLNO', 'c': 'CYCLENO', 't' : 'TIME', 'r':None, '_r':None }
[1944]1231 if not (type(lorders) == list) and not (type(lorders) == tuple):
[1910]1232 return None
1233 if len(lorders) > 0:
1234 lsorts = []
1235 for order in lorders:
[1989]1236 if order == "r":
1237 # don't sort if row panelling/stacking
1238 return None
[1910]1239 ssort = d0[order]
1240 if ssort:
1241 lsorts.append(ssort)
1242 return lsorts
1243 return None
1244
[920]1245 def _get_selected_n(self, scan):
[1148]1246 d1 = {'b': scan.getbeamnos, 's': scan.getscannos,
[1910]1247 'i': scan.getifnos, 'p': scan.getpolnos, 't': scan.ncycle,
[1989]1248 'r': scan.nrow}#, '_r': False}
[1148]1249 d2 = { 'b': self._selection.get_beams(),
1250 's': self._selection.get_scans(),
1251 'i': self._selection.get_ifs(),
1252 'p': self._selection.get_pols(),
[1910]1253 't': self._selection.get_cycles(),
[1989]1254 'r': False}#, '_r': 1}
[920]1255 n = d2[self._panelling] or d1[self._panelling]()
1256 nstack = d2[self._stacking] or d1[self._stacking]()
[1989]1257 # handle row panelling/stacking
1258 if self._panelling == 'r':
1259 nstack = 1
1260 elif self._stacking == 'r':
1261 n = 1
[920]1262 return n,nstack
1263
1264 def _get_label(self, scan, row, mode, userlabel=None):
[1153]1265 if isinstance(userlabel, list) and len(userlabel) == 0:
1266 userlabel = " "
[947]1267 pms = dict(zip(self._selection.get_pols(),self._selection.get_poltypes()))
[920]1268 if len(pms):
1269 poleval = scan._getpollabel(scan.getpol(row),pms[scan.getpol(row)])
1270 else:
1271 poleval = scan._getpollabel(scan.getpol(row),scan.poltype())
1272 d = {'b': "Beam "+str(scan.getbeam(row)),
[1819]1273 #'s': scan._getsourcename(row),
1274 's': "Scan "+str(scan.getscan(row))+\
1275 " ("+str(scan._getsourcename(row))+")",
[920]1276 'i': "IF"+str(scan.getif(row)),
[964]1277 'p': poleval,
[1910]1278 't': str(scan.get_time(row)),
1279 'r': "row "+str(row),
[1913]1280 #'_r': str(scan.get_time(row))+",\nIF"+str(scan.getif(row))+", "+poleval+", Beam"+str(scan.getbeam(row)) }
1281 '_r': "" }
[920]1282 return userlabel or d[mode]
[1153]1283
[2700]1284 def _slice_indeces(self, data):
1285 mn = self._minmaxx[0]
1286 mx = self._minmaxx[1]
1287 asc = data[0] < data[-1]
1288 start=0
1289 end = len(data)-1
1290 inc = 1
1291 if not asc:
1292 start = len(data)-1
1293 end = 0
1294 inc = -1
1295 # find min index
1296 #while start > 0 and data[start] < mn:
1297 # start+= inc
1298 minind=start
1299 for ind in xrange(start,end+inc,inc):
1300 if data[ind] > mn: break
1301 minind=ind
1302 # find max index
1303 #while end > 0 and data[end] > mx:
1304 # end-=inc
1305 #if end > 0: end +=1
1306 maxind=end
1307 for ind in xrange(end,start-inc,-inc):
1308 if data[ind] < mx: break
1309 maxind=ind
1310 start=minind
1311 end=maxind
1312 if start > end:
1313 return end,start+1
1314 elif start < end:
1315 return start,end+1
1316 else:
1317 return start,end
1318
[2988]1319 def _get_date_axis_setup(self, dates):
1320 """
1321 Returns proper axis title and formatters for a list of dates
1322 Input
1323 dates : a list of datetime objects returned by,
1324 e.g. scantable.get_time(asdatetime=True)
1325 Output
1326 a set of
1327 * date axis title string
1328 * formatter of date axis
1329 * major axis locator
1330 * minor axis locator
1331 """
1332 from matplotlib import pylab as PL
1333 from matplotlib.dates import DateFormatter
1334 from matplotlib.dates import HourLocator, MinuteLocator,SecondLocator, DayLocator
1335 t = PL.date2num(dates)
1336 tdel = max(t) - min(t) # interval in day
1337 dstr = dates[0].strftime('%Y/%m/%d')
1338 if tdel > 1.0: # >1day
1339 dstr2 = dates[len(dates)-1].strftime('%Y/%m/%d')
1340 dstr = dstr + " - " + dstr2
1341 majloc = DayLocator()
1342 minloc = HourLocator(range(0,23,12))
1343 timefmt = DateFormatter("%b%d")
1344 elif tdel > 24./60.: # 9.6h - 1day
1345 timefmt = DateFormatter('%H:%M')
1346 majloc = HourLocator()
1347 minloc = MinuteLocator(range(0,60,30))
1348 elif tdel > 2./24.: # 2h-9.6h
1349 timefmt = DateFormatter('%H:%M')
1350 majloc = HourLocator()
1351 minloc = MinuteLocator(range(0,60,10))
1352 elif tdel> 10./24./60.: # 10min-2h
1353 timefmt = DateFormatter('%H:%M')
1354 majloc = MinuteLocator(range(0,60,10))
1355 minloc = MinuteLocator()
1356 else: # <10min
1357 timefmt = DateFormatter('%H:%M')
1358 majloc = MinuteLocator()
1359 minloc = SecondLocator(30)
1360 return (dstr, timefmt, majloc, minloc)
1361
[1819]1362 def plotazel(self, scan=None, outfile=None):
[1391]1363 """
[1696]1364 plot azimuth and elevation versus time of a scantable
[1391]1365 """
[2704]1366 self._plotmode = "azel"
[1923]1367 visible = rcParams['plotter.gui']
[1696]1368 from matplotlib import pylab as PL
[2586]1369 from pytz import timezone
[1391]1370 from matplotlib.ticker import MultipleLocator
[2953]1371 from numpy import array, pi, ma
[2704]1372 if self._plotter and (PL.gcf() == self._plotter.figure):
[2699]1373 # the current figure is ASAP plotter. Use mpl plotter
1374 figids = PL.get_fignums()
[2704]1375 PL.figure(max(figids[-1],1))
1376
[1923]1377 if not visible or not self._visible:
1378 PL.ioff()
1379 from matplotlib.backends.backend_agg import FigureCanvasAgg
1380 PL.gcf().canvas.switch_backends(FigureCanvasAgg)
[1819]1381 self._data = scan
[1556]1382 dates = self._data.get_time(asdatetime=True)
[2953]1383 # for flag handling
1384 mask = [ self._data._is_all_chan_flagged(i) for i in range(self._data.nrow())]
[1391]1385 t = PL.date2num(dates)
1386 tz = timezone('UTC')
1387 PL.cla()
1388 PL.ioff()
1389 PL.clf()
[2037]1390 # Adjust subplot margins
[2576]1391 if not self._margins or len(self._margins) != 6:
[2037]1392 self.set_margin(refresh=False)
1393 lef, bot, rig, top, wsp, hsp = self._margins
[1819]1394 PL.gcf().subplots_adjust(left=lef,bottom=bot,right=rig,top=top,
1395 wspace=wsp,hspace=hsp)
[1824]1396
[2977]1397 tdel = max(t) - min(t) # interval in day
[1391]1398 ax = PL.subplot(2,1,1)
[2953]1399 el = ma.masked_array(array(self._data.get_elevation())*180./pi, mask)
[1391]1400 PL.ylabel('El [deg.]')
[2988]1401 (dstr, timefmt, majloc, minloc) = self._get_date_axis_setup(dates)
1402
[1391]1403 PL.title(dstr)
[1819]1404 if tdel == 0.0:
1405 th = (t - PL.floor(t))*24.0
1406 PL.plot(th,el,'o',markersize=2, markerfacecolor='b', markeredgecolor='b')
1407 else:
1408 PL.plot_date(t,el,'o', markersize=2, markerfacecolor='b', markeredgecolor='b',tz=tz)
[3016]1409 #ax.xaxis.set_major_formatter(timefmt)
1410 #ax.xaxis.set_major_locator(majloc)
1411 #ax.xaxis.set_minor_locator(minloc)
[1391]1412 ax.yaxis.grid(True)
[1819]1413 ax.set_ylim(0,90)
[3016]1414 #yloc = MultipleLocator(30)
1415 #ax.yaxis.set_major_locator(yloc)
[1391]1416 if tdel > 1.0:
1417 labels = ax.get_xticklabels()
1418 # PL.setp(labels, fontsize=10, rotation=45)
1419 PL.setp(labels, fontsize=10)
[1819]1420
[1391]1421 # Az plot
[2953]1422 az = ma.masked_array(array(self._data.get_azimuth())*180./pi, mask)
[1391]1423 if min(az) < 0:
1424 for irow in range(len(az)):
1425 if az[irow] < 0: az[irow] += 360.0
1426
[1819]1427 ax2 = PL.subplot(2,1,2)
1428 #PL.xlabel('Time (UT [hour])')
1429 PL.ylabel('Az [deg.]')
1430 if tdel == 0.0:
1431 PL.plot(th,az,'o',markersize=2, markeredgecolor='b',markerfacecolor='b')
1432 else:
1433 PL.plot_date(t,az,'o', markersize=2,markeredgecolor='b',markerfacecolor='b',tz=tz)
[3016]1434 #ax2.xaxis.set_major_formatter(timefmt)
1435 #ax2.xaxis.set_major_locator(majloc)
1436 #ax2.xaxis.set_minor_locator(minloc)
[1819]1437 ax2.set_ylim(0,360)
[1696]1438 ax2.yaxis.grid(True)
[1819]1439 #hfmt = DateFormatter('%H')
1440 #hloc = HourLocator()
[3016]1441 #yloc = MultipleLocator(60)
1442 #ax2.yaxis.set_major_locator(yloc)
[1819]1443 if tdel > 1.0:
1444 labels = ax2.get_xticklabels()
1445 PL.setp(labels, fontsize=10)
[3016]1446 # PL.xlabel('Time (UT [day])')
1447 #else:
1448 # PL.xlabel('Time (UT [hour])')
1449 PL.xlabel('Time (UT)')
[1819]1450
[1391]1451 PL.ion()
1452 PL.draw()
[2416]1453 if matplotlib.get_backend() == 'Qt4Agg': PL.gcf().show()
[2576]1454 if (outfile is not None):
1455 PL.savefig(outfile)
[1391]1456
[2693]1457
1458 def plotpointing2(self, scan=None, colorby='', showline=False, projection=''):
1459 """
1460 plot telescope pointings
1461 Parameters:
[2990]1462 scan : input scantable instance
[2693]1463 colorby : change color by either
1464 'type'(source type)|'scan'|'if'|'pol'|'beam'
1465 showline : show dotted line
1466 projection : projection type either
1467 ''(no projection [deg])|'coord'(not implemented)
1468 """
[2704]1469 self._plotmode = "pointing"
[2953]1470 from numpy import array, pi, ma
[2693]1471 from asap import scantable
1472 # check for scantable
1473 if isinstance(scan, scantable):
1474 if self._data is not None:
1475 if scan != self._data:
1476 self._data = scan
1477 # reset
1478 self._reset()
1479 else:
1480 self._data = scan
1481 self._reset()
1482 if not self._data:
1483 msg = "Input is not a scantable"
1484 raise TypeError(msg)
1485 # check for color mode
1486 validtypes=['type','scan','if','pol', 'beam']
1487 stype = None
1488 if (colorby in validtypes):
1489 stype = colorby[0]
1490 elif len(colorby) > 0:
1491 msg = "Invalid choice of 'colorby' (choices: %s)" % str(validtypes)
1492 raise ValueError(msg)
1493 self._assert_plotter(action="reload")
1494 self._plotter.hold()
[2697]1495 self._reset_counter()
[2694]1496 if self.casabar_exists():
1497 self._plotter.figmgr.casabar.disable_button()
[2693]1498 # for now, only one plot
1499 self._plotter.set_panels(rows=1,cols=1)
1500 # first panel
1501 self._plotter.subplot(0)
1502 # first color and linestyles
1503 self._plotter.palette(0)
1504 self.gca().set_aspect('equal')
1505 basesel = scan.get_selection()
[2694]1506 attrback = self._plotter.get_line()
1507 marker = "o"
[2693]1508 if showline:
1509 basesel.set_order(["TIME"])
1510 scan.set_selection(basesel)
1511 if not (stype in ["t", "s"]):
[2694]1512 marker += ":"
1513 self._plotter.set_line(markersize=3, markeredgewidth=0)
1514
[2693]1515 if not stype:
1516 selIds = [""] # cheating
1517 sellab = "all points"
1518 elif stype == 't':
1519 selIds = range(15)
1520 sellab = "src type "
1521 else:
1522 selIds = getattr(self._data,'get'+colorby+'nos')()
1523 sellab = colorby.upper()
1524 selFunc = "set_"+colorby+"s"
1525 for idx in selIds:
1526 sel = selector() + basesel
1527 if stype:
1528 bid = getattr(basesel,'get_'+colorby+"s")()
1529 if (len(bid) > 0) and (not idx in bid):
1530 # base selection doesn't contain idx
1531 # Note summation of selector is logical sum if
1532 continue
1533 getattr(sel, selFunc)([idx])
1534 if not sel.is_empty():
1535 try:
1536 self._data.set_selection(sel)
1537 except RuntimeError, instance:
1538 if stype == 't' and str(instance).startswith("Selection contains no data."):
1539 continue
1540 else:
1541 self._data.set_selection(basesel)
1542 raise RuntimeError, instance
1543 if self._data.nrow() == 0:
1544 self._data.set_selection(basesel)
1545 continue
[2795]1546 #print "Plotting direction of %s = %s" % (colorby, str(idx))
[2694]1547 # getting data to plot
[2693]1548 dir = array(self._data.get_directionval()).transpose()
[2953]1549 # for flag handling
1550 mask = [ self._data._is_all_chan_flagged(i) for i in range(self._data.nrow())]
[2693]1551 ra = dir[0]*180./pi
[2953]1552 dec = ma.masked_array(dir[1]*180./pi, mask)
[2694]1553 # actual plot
[2693]1554 self._plotter.set_line(label=(sellab+str(idx)))
1555 self._plotter.plot(ra,dec,marker)
1556
1557 # restore original selection
1558 self._data.set_selection(basesel)
1559 # need to plot scan pattern explicitly
1560 if showline and (stype in ["t", "s"]):
1561 dir = array(self._data.get_directionval()).transpose()
1562 ra = dir[0]*180./pi
1563 dec = dir[1]*180./pi
1564 self._plotter.set_line(label="scan pattern")
1565 self._plotter.plot(ra,dec,":")
[2694]1566 # set color for only this line
1567 self._plotter.lines[-1][0].set_color("gray")
1568
[2693]1569 xlab = 'RA [deg.]'
1570 ylab = 'Declination [deg.]'
1571 self._plotter.set_axes('xlabel', xlab)
1572 self._plotter.set_axes('ylabel', ylab)
1573 self._plotter.set_axes('title', 'Telescope pointings')
1574 if stype: self._plotter.legend(self._legendloc)
1575 else: self._plotter.legend(None)
1576 # reverse x-axis
1577 xmin, xmax = self.gca().get_xlim()
[2989]1578 ymin, ymax = self.gca().get_ylim()
1579 # expand plotrange if xmin==xmax or ymin==ymax
1580 if abs(ymax-ymin) < 1.e-3: #~4arcsec
1581 delx = 0.5*abs(xmax - xmin)
1582 if delx < 5.e-4:
1583 dxy = 5.e-4 #~2arcsec
1584 (ymin, ymax) = (ymin-dxy, ymax+dxy)
1585 (xmin, xmax) = (xmin-dxy, xmax+dxy)
1586 (ymin, ymax) = (ymin-delx, ymax+delx)
1587 elif abs(xmax-xmin) < 1.e-3:
1588 dely = 0.5*abs(ymax - ymin)
1589 (xmin, xmax) = (xmin-dely, xmax+dely)
1590 self._plotter.set_limits(xlim=[xmax,xmin], ylim=[ymin, ymax])
[2693]1591
1592 self._plotter.release()
1593 self._plotter.show(hardrefresh=False)
[2694]1594 # reset line settings
1595 self._plotter.set_line(**attrback)
[2693]1596 return
1597
[1819]1598 def plotpointing(self, scan=None, outfile=None):
[1391]1599 """
1600 plot telescope pointings
1601 """
[1923]1602 visible = rcParams['plotter.gui']
[1696]1603 from matplotlib import pylab as PL
[1819]1604 from numpy import array, pi
[2704]1605 if self._plotter and (PL.gcf() == self._plotter.figure):
[2699]1606 # the current figure is ASAP plotter. Use mpl plotter
1607 figids = PL.get_fignums()
[2704]1608 PL.figure(max(figids[-1],1))
1609
[1923]1610 if not visible or not self._visible:
1611 PL.ioff()
1612 from matplotlib.backends.backend_agg import FigureCanvasAgg
1613 PL.gcf().canvas.switch_backends(FigureCanvasAgg)
[1819]1614 self._data = scan
[1391]1615 dir = array(self._data.get_directionval()).transpose()
1616 ra = dir[0]*180./pi
1617 dec = dir[1]*180./pi
1618 PL.cla()
[1819]1619 #PL.ioff()
[1391]1620 PL.clf()
[2037]1621 # Adjust subplot margins
[2576]1622 if not self._margins or len(self._margins) != 6:
[2037]1623 self.set_margin(refresh=False)
1624 lef, bot, rig, top, wsp, hsp = self._margins
[1819]1625 PL.gcf().subplots_adjust(left=lef,bottom=bot,right=rig,top=top,
1626 wspace=wsp,hspace=hsp)
1627 ax = PL.gca()
1628 #ax = PL.axes([0.1,0.1,0.8,0.8])
1629 #ax = PL.axes([0.1,0.1,0.8,0.8])
[1391]1630 ax.set_aspect('equal')
[1696]1631 PL.plot(ra, dec, 'b,')
[1391]1632 PL.xlabel('RA [deg.]')
1633 PL.ylabel('Declination [deg.]')
1634 PL.title('Telescope pointings')
1635 [xmin,xmax,ymin,ymax] = PL.axis()
1636 PL.axis([xmax,xmin,ymin,ymax])
[2416]1637 PL.ion()
[1391]1638 PL.draw()
[2416]1639 if matplotlib.get_backend() == 'Qt4Agg': PL.gcf().show()
[2576]1640 if (outfile is not None):
1641 PL.savefig(outfile)
[1819]1642
1643 # plot total power data
1644 # plotting in time is not yet implemented..
[1862]1645 @asaplog_post_dec
[2990]1646 def plottp(self, scan=None, colorby=''):
1647 """
1648 Plot averaged spectra (total power) in time or in row ID (colorby='')
1649 Parameters:
1650 scan : input scantable instance
1651 colorby : change color by either
1652 'type'(source type)|'scan'|'if'|'pol'|'beam'|''
1653 """
[2704]1654 self._plotmode = "totalpower"
[1819]1655 from asap import scantable
1656 if not self._data and not scan:
1657 msg = "Input is not a scantable"
1658 raise TypeError(msg)
1659 if isinstance(scan, scantable):
1660 if self._data is not None:
1661 if scan != self._data:
1662 self._data = scan
1663 # reset
1664 self._reset()
1665 else:
1666 self._data = scan
1667 self._reset()
1668 # ranges become invalid when abcissa changes?
1669 #if self._abcunit and self._abcunit != self._data.get_unit():
1670 # self._minmaxx = None
1671 # self._minmaxy = None
1672 # self._abcunit = self._data.get_unit()
1673
[2693]1674 self._assert_plotter(action="reload")
1675 self._plotter.hold()
1676 self._plotter.clear()
[2037]1677 # Adjust subplot margins
[2576]1678 if not self._margins or len(self._margins) !=6:
1679 self.set_margin(refresh=False)
[2037]1680 lef, bot, rig, top, wsp, hsp = self._margins
[1819]1681 self._plotter.figure.subplots_adjust(
1682 left=lef,bottom=bot,right=rig,top=top,wspace=wsp,hspace=hsp)
[2147]1683 if self.casabar_exists(): self._plotter.figmgr.casabar.disable_button()
[2990]1684 if len(colorby) == 0:
1685 self._plottp(self._data)
1686 else:
[2991]1687 self._plottp_in_time(self._data,colorby)
[1819]1688 if self._minmaxy is not None:
1689 self._plotter.set_limits(ylim=self._minmaxy)
1690 self._plotter.release()
1691 self._plotter.tidy()
1692 self._plotter.show(hardrefresh=False)
1693 return
1694
[2991]1695 def _plottp_in_time(self,scan,colorby):
[2990]1696 """
1697 private method for plotting total power data in time
[2991]1698 Parameters:
1699 scan : input scantable instance
1700 colorby : change color by either
1701 'type'(source type)|'scan'|'if'|'pol'|'beam'
[2990]1702 """
1703 from numpy import ma, array, arange, logical_not
1704 r=0
1705 nr = scan.nrow()
1706 a0,b0 = -1,-1
1707 allxlim = []
1708 allylim = []
1709 y=[]
1710 self._plotter.set_panels()
1711 self._plotter.palette(0)
1712 # check of overlay settings
[2992]1713 time_types = ['type','scan'] # time dependent meta-data
1714 misc_types = ['if','pol','beam'] # time independent meta-data
1715 validtypes=time_types + misc_types
[2990]1716 stype = None
[2991]1717 col_msg = "Invalid choice of 'colorby' (choices: %s)" % str(validtypes)
[2992]1718 colorby = colorby.lower()
[2990]1719 if (colorby in validtypes):
1720 stype = colorby[0]
1721 elif len(colorby) > 0:
[2991]1722 raise ValueError(col_msg)
[2990]1723 if not stype:
[2991]1724 raise ValueError(col_msg)
[2992]1725 # Selection and sort order
1726 basesel = scan.get_selection()
1727 if colorby in misc_types: misc_types.pop(misc_types.index(colorby))
1728 sel_lbl = ""
1729 for meta in misc_types:
1730 idx = getattr(scan,'get'+meta+'nos')()
1731 if len(idx) > 1: getattr(basesel, 'set_'+meta+'s')([idx[0]])
1732 sel_lbl += ("%s%d, " % (meta.upper(), idx[0]))
1733 sel_lbl = sel_lbl.rstrip(', ')
1734 scan.set_selection(basesel)
1735 if len(sel_lbl) > 0:
1736 asaplog.push("Selection contains multiple IFs/Pols/Beams. Plotting the first ones: %s" % sel_lbl)
1737 asaplog.post("WARN")
1738 if stype == 't':
[2990]1739 selIds = range(15)
1740 sellab = "src type "
1741 else:
1742 selIds = getattr(scan,'get'+colorby+'nos')()
1743 sellab = colorby.upper()
1744 selFunc = "set_"+colorby+"s"
[2992]1745 basesel.set_order(["TIME"])
1746 # define axes labels
1747 xlab = self._abcissa or 'Time (UTC)'
1748 ylab = self._ordinate or scan._get_ordinate_label()
1749 self._plotter.set_axes('xlabel',xlab)
1750 self._plotter.set_axes('ylabel',ylab)
1751 # define the panel title
1752 if len(sel_lbl) > 0: lbl = sel_lbl
1753 else: lbl = self._get_label(scan, r, 's', self._title)
1754 if isinstance(lbl, list) or isinstance(lbl, tuple):
1755 # get default label
1756 lbl = self._get_label(scan, r, self._panelling, None)
1757 self._plotter.set_axes('title',lbl)
1758 # linestyle
1759 lstyle = '' if colorby in time_types else ':'
[2990]1760 alldates = []
1761 for idx in selIds:
1762 sel = selector() + basesel
[2991]1763 bid = getattr(basesel,'get_'+colorby+"s")()
1764 if (len(bid) > 0) and (not idx in bid):
1765 # base selection doesn't contain idx
1766 # Note summation of selector is logical sum if
1767 continue
1768 getattr(sel, selFunc)([idx])
[2990]1769 if not sel.is_empty():
1770 try:
1771 scan.set_selection(sel)
1772 except RuntimeError, instance:
1773 if stype == 't' and str(instance).startswith("Selection contains no data."):
1774 continue
1775 else:
1776 scan.set_selection(basesel)
1777 raise RuntimeError, instance
1778 if scan.nrow() == 0:
1779 scan.set_selection(basesel)
1780 continue
1781 y=array(scan._get_column(scan._getspectrum,-1))
1782 m = array(scan._get_column(scan._getmask,-1))
1783 y = ma.masked_array(y,mask=logical_not(array(m,copy=False)))
1784 # try to handle spectral data somewhat...
[2991]1785 try:
1786 l,m = y.shape
1787 except ValueError, e:
[2992]1788 raise ValueError(str(e)+" This error usually occurs when you select multiple spws with different number of channels. Try selecting single spw and retry.")
[2990]1789 if m > 1:
1790 y=y.mean(axis=1)
1791 # flag handling
1792 m = [ scan._is_all_chan_flagged(i) for i in range(scan.nrow()) ]
1793 y = ma.masked_array(y,mask=m)
1794 if len(y) == 0: continue
[2992]1795 # line label
1796 llbl=sellab+str(idx)
[2991]1797 from matplotlib.dates import date2num
1798 from pytz import timezone
1799 dates = self._data.get_time(asdatetime=True)
1800 alldates += list(dates)
1801 x = date2num(dates)
1802 tz = timezone('UTC')
[2992]1803 # get color
1804 lc = self._plotter.colormap[self._plotter.color]
1805 self._plotter.palette( (self._plotter.color+1) % len(self._plotter.colormap) )
1806 # actual plotting
1807 self._plotter.axes.plot_date(x,y,tz=tz,label=llbl,linestyle=lstyle,color=lc,
1808 marker='o',markersize=3,markeredgewidth=0)
[2991]1809
[2990]1810 # legend and axis formatting
[2991]1811 (dstr, timefmt, majloc, minloc) = self._get_date_axis_setup(alldates)
1812 ax = self.gca()
1813 ax.xaxis.set_major_formatter(timefmt)
1814 ax.xaxis.set_major_locator(majloc)
1815 ax.xaxis.set_minor_locator(minloc)
[2992]1816 self._plotter.axes.legend(loc=self._legendloc)
[2990]1817
[1819]1818 def _plottp(self,scan):
1819 """
1820 private method for plotting total power data
1821 """
1822 from numpy import ma, array, arange, logical_not
1823 r=0
1824 nr = scan.nrow()
1825 a0,b0 = -1,-1
1826 allxlim = []
1827 allylim = []
1828 y=[]
1829 self._plotter.set_panels()
1830 self._plotter.palette(0)
1831 #title
1832 #xlab = self._abcissa and self._abcissa[panelcount] \
1833 # or scan._getabcissalabel()
1834 #ylab = self._ordinate and self._ordinate[panelcount] \
1835 # or scan._get_ordinate_label()
1836 xlab = self._abcissa or 'row number' #or Time
1837 ylab = self._ordinate or scan._get_ordinate_label()
1838 self._plotter.set_axes('xlabel',xlab)
1839 self._plotter.set_axes('ylabel',ylab)
1840 lbl = self._get_label(scan, r, 's', self._title)
1841 if isinstance(lbl, list) or isinstance(lbl, tuple):
1842 # if 0 <= panelcount < len(lbl):
1843 # lbl = lbl[panelcount]
1844 # else:
1845 # get default label
1846 lbl = self._get_label(scan, r, self._panelling, None)
1847 self._plotter.set_axes('title',lbl)
1848 y=array(scan._get_column(scan._getspectrum,-1))
1849 m = array(scan._get_column(scan._getmask,-1))
1850 y = ma.masked_array(y,mask=logical_not(array(m,copy=False)))
1851 x = arange(len(y))
1852 # try to handle spectral data somewhat...
[2992]1853 try:
1854 l,m = y.shape
1855 except ValueError, e:
1856 raise ValueError(str(e)+" This error usually occurs when you select multiple spws with different number of channels. Try selecting single spw and retry.")
[1819]1857 if m > 1:
1858 y=y.mean(axis=1)
[2953]1859 # flag handling
1860 m = [ scan._is_all_chan_flagged(i) for i in range(scan.nrow()) ]
1861 y = ma.masked_array(y,mask=m)
[1819]1862 plotit = self._plotter.plot
1863 llbl = self._get_label(scan, r, self._stacking, None)
1864 self._plotter.set_line(label=llbl)
1865 if len(x) > 0:
1866 plotit(x,y)
1867
1868
1869 # printing header information
[1862]1870 @asaplog_post_dec
[2053]1871 def print_header(self, plot=True, fontsize=9, logger=False, selstr='', extrastr=''):
[1819]1872 """
1873 print data (scantable) header on the plot and/or logger.
[2056]1874 To plot the header on the plot, this method should be called after
1875 plotting spectra by the method, asapplotter.plot.
[1819]1876 Parameters:
[1824]1877 plot: whether or not print header info on the plot.
[2053]1878 fontsize: header font size (valid only plot=True)
[1819]1879 logger: whether or not print header info on the logger.
1880 selstr: additional selection string (not verified)
[2053]1881 extrastr: additional string to print at the beginning (not verified)
[1819]1882 """
[1859]1883 if not plot and not logger:
1884 return
1885 if not self._data:
1886 raise RuntimeError("No scantable has been set yet.")
[1824]1887 # Now header will be printed on plot and/or logger.
1888 # Get header information and format it.
[2112]1889 ssum=self._data._list_header()
[1819]1890 # Print Observation header to the upper-left corner of plot
[2290]1891 headstr=[ssum[0:ssum.find('Obs. Type:')]]
1892 headstr.append(ssum[ssum.find('Obs. Type:'):ssum.find('Flux Unit:')])
[2053]1893 if extrastr != '':
1894 headstr[0]=extrastr+'\n'+headstr[0]
1895 self._headtext['extrastr'] = extrastr
[2112]1896 if selstr != '':
1897 selstr += '\n'
1898 self._headtext['selstr'] = selstr
[2944]1899 #ssel=(selstr+self._data.get_selection().__str__()+self._selection.__str__() or 'none')
[2945]1900 curr_selstr = selstr+self._data.get_selection().__str__() or "none"
1901 ssel=(curr_selstr+"\n" +self._selection.__str__())
[2927]1902 headstr.append('\n\n***Selections***\n'+ssel.replace('$','\$'))
[1824]1903
[2051]1904 if plot:
[2451]1905 errmsg = "Can plot header only after the first call to plot()."
[2453]1906 self._assert_plotter(action="halt",errmsg=errmsg)
[1819]1907 self._plotter.hold()
[2053]1908 self._header_plot(headstr,fontsize=fontsize)
[2697]1909 #import time
1910 #self._plotter.figure.text(0.99,0.01,
1911 # time.strftime("%a %d %b %Y %H:%M:%S %Z"),
1912 # horizontalalignment='right',
1913 # verticalalignment='bottom',fontsize=8)
[1819]1914 self._plotter.release()
1915 if logger:
[2053]1916 selstr = "Selections: "+ssel
[1819]1917 asaplog.push("----------------\n Plot Summary\n----------------")
[2053]1918 asaplog.push(extrastr)
[2290]1919 asaplog.push(ssum[0:ssum.find('Selection:')]\
[2112]1920 + selstr)
[2053]1921 self._headtext['string'] = headstr
1922 del ssel, ssum, headstr
[2051]1923
[2053]1924 def _header_plot(self, texts, fontsize=9):
1925 self._headtext['textobj']=[]
1926 nstcol=len(texts)
1927 for i in range(nstcol):
1928 self._headtext['textobj'].append(
1929 self._plotter.figure.text(0.03+float(i)/nstcol,0.98,
1930 texts[i],
1931 horizontalalignment='left',
1932 verticalalignment='top',
1933 fontsize=fontsize))
1934
1935 def clear_header(self):
1936 if not self._headtext['textobj']:
1937 asaplog.push("No header has been plotted. Exit without any operation")
1938 asaplog.post("WARN")
[2453]1939 elif self._assert_plotter(action="status"):
[2053]1940 self._plotter.hold()
1941 for textobj in self._headtext['textobj']:
1942 #if textobj.get_text() in self._headstring:
1943 try:
1944 textobj.remove()
1945 except NotImplementedError:
1946 self._plotter.figure.texts.pop(self._plotter.figure.texts.index(textobj))
1947 self._plotter.release()
1948 self._reset_header()
[2576]1949
1950 # plot spectra by pointing
1951 @asaplog_post_dec
[2717]1952 def plotgrid(self, scan=None,center="",spacing=[],rows=None,cols=None):
[2576]1953 """
1954 Plot spectra based on direction.
1955
1956 Parameters:
1957 scan: a scantable to plot
[2717]1958 center: the grid center direction (a string)
[2576]1959 (default) the center of map region
[2717]1960 (example) 'J2000 19h30m00s -25d00m00s'
[2576]1961 spacing: a list of horizontal (R.A.) and vertical (Dec.)
[2717]1962 spacing.
[2576]1963 (default) Calculated by the extent of map region and
[2717]1964 (example) ['1arcmin', '1arcmin']
[2576]1965 the number of rows and cols to cover
1966 rows: number of panels (grid points) in horizontal direction
1967 cols: number of panels (grid points) in vertical direction
1968
1969 Note:
1970 - Only the first IFNO, POLNO, and BEAM in the scantable will be
1971 plotted.
1972 - This method doesn't re-grid and average spectra in scantable. Use
1973 asapgrid module to re-grid spectra before plotting with this method.
1974 Only the first spectrum is plotted in case there are multiple
1975 spectra which belong to a grid.
1976 """
[2704]1977 self._plotmode = "grid"
[2576]1978 from asap import scantable
[2607]1979 from numpy import array, ma, cos
[2576]1980 if not self._data and not scan:
1981 msg = "No scantable is specified to plot"
1982 raise TypeError(msg)
[2604]1983 if scan:
1984 self.set_data(scan, refresh=False)
1985 del scan
1986
[2576]1987 # Rows and cols
[2717]1988 if (self._rows is None):
1989 rows = max(1, rows)
1990 if (self._cols is None):
1991 cols = max(1, cols)
1992 self.set_layout(rows,cols,False)
[2576]1993
[2717]1994 # Select the first IF, POL, and BEAM for plotting
[2576]1995 ntotpl = self._rows * self._cols
1996 ifs = self._data.getifnos()
1997 if len(ifs) > 1:
1998 msg = "Found multiple IFs in scantable. Only the first IF (IFNO=%d) will be plotted." % ifs[0]
1999 asaplog.post()
2000 asaplog.push(msg)
2001 asaplog.post("WARN")
2002 pols = self._data.getpolnos()
2003 if len(pols) > 1:
2004 msg = "Found multiple POLs in scantable. Only the first POL (POLNO=%d) will be plotted." % pols[0]
2005 asaplog.post()
2006 asaplog.push(msg)
2007 asaplog.post("WARN")
2008 beams = self._data.getbeamnos()
2009 if len(beams) > 1:
2010 msg = "Found multiple BEAMs in scantable. Only the first BEAM (BEAMNO=%d) will be plotted." % beams[0]
2011 asaplog.post()
2012 asaplog.push(msg)
2013 asaplog.post("WARN")
2014 self._data.set_selection(ifs=[ifs[0]],pols=[pols[0]],beams=[beams[0]])
2015 if self._data.nrow() > ntotpl:
2016 msg = "Scantable is finely sampled than plotting grids. "\
2017 + "Only the first spectrum is plotted in each grid."
2018 asaplog.post()
2019 asaplog.push(msg)
2020 asaplog.post("WARN")
[2717]2021
2022 # Prepare plotter
[2576]2023 self._assert_plotter(action="reload")
2024 self._plotter.hold()
[2697]2025 self._reset_counter()
[2604]2026 self._plotter.legend()
[2691]2027
[2576]2028 # Adjust subplot margins
2029 if not self._margins or len(self._margins) !=6:
2030 self.set_margin(refresh=False)
2031 self._plotter.set_panels(rows=self._rows,cols=self._cols,
[2693]2032 nplots=ntotpl,margin=self._margins,ganged=True)
[2603]2033 if self.casabar_exists():
2034 self._plotter.figmgr.casabar.enable_button()
[2691]2035 # Plot helper
2036 from asap._asap import plothelper as plhelper
2037 ph = plhelper(self._data)
[2717]2038 #ph.set_gridval(self._cols, self._rows, spacing[0], spacing[1],
2039 # center[0], center[1], epoch="J2000", projname="SIN")
2040 if type(spacing) in (list, tuple, array):
2041 if len(spacing) == 0:
2042 spacing = ["", ""]
2043 elif len(spacing) == 1:
2044 spacing = [spacing[0], spacing[0]]
2045 else:
2046 spacing = [spacing, spacing]
2047 ph.set_grid(self._cols, self._rows, spacing[0], spacing[1], \
2048 center, projname="SIN")
2049
[2576]2050 # Actual plot
2051 npl = 0
2052 for irow in range(self._data.nrow()):
[2691]2053 (ix, iy) = ph.get_gpos(irow)
2054 #print("asapplotter.plotgrid: (ix, iy) = (%f, %f)" % (ix, iy))
[2576]2055 if ix < 0 or ix >= self._cols:
[2602]2056 #print "Row %d : Out of X-range (x = %f) ... skipped" % (irow, pos[0])
[2576]2057 continue
[2691]2058 ix = int(ix)
2059 if iy < 0 or iy >= self._rows:
[2602]2060 #print "Row %d : Out of Y-range (y = %f) ... skipped" % (irow,pos[1])
[2576]2061 continue
[2691]2062 iy = int(iy)
2063 ipanel = ix + iy*self._rows
2064 #print("Resolved panel Id (%d, %d): %d" % (ix, iy, ipanel))
[2576]2065 if len(self._plotter.subplots[ipanel]['lines']) > 0:
[2602]2066 #print "Row %d : panel %d lready plotted ... skipped" % (irow,ipanel)
[2576]2067 # a spectrum already plotted in the panel
2068 continue
2069 # Plotting this row
[2602]2070 #print "PLOTTING row %d (panel=%d)" % (irow, ipanel)
[2576]2071 npl += 1
2072 self._plotter.subplot(ipanel)
[2602]2073 self._plotter.palette(0,colormap=self._colormap, \
2074 linestyle=0,linestyles=self._linestyles)
[2576]2075 xlab = self._abcissa and self._abcissa[ipanel] \
[2603]2076 or self._data._getabcissalabel(irow)
[2576]2077 if self._offset and not self._abcissa:
2078 xlab += " (relative)"
2079 ylab = self._ordinate and self._ordinate[ipanel] \
[2603]2080 or self._data._get_ordinate_label()
[2576]2081 self._plotter.set_axes('xlabel', xlab)
2082 self._plotter.set_axes('ylabel', ylab)
2083 lbl = self._data.get_direction(irow)
2084 self._plotter.set_axes('title',lbl)
2085
[2603]2086 y = self._data._getspectrum(irow)
[2576]2087 # flag application
[2603]2088 mr = self._data._getflagrow(irow)
[2576]2089 if mr: # FLAGROW=True
2090 y = ma.masked_array(y,mask=mr)
2091 else:
[2603]2092 m = self._data._getmask(irow)
[2576]2093 from numpy import logical_not, logical_and
2094 ### user mask is not available so far
2095 #if self._maskselection and len(self._usermask) == len(m):
2096 # if d[self._stacking](irow) in self._maskselection[self._stacking]:
2097 # m = logical_and(m, self._usermask)
2098 y = ma.masked_array(y,mask=logical_not(array(m,copy=False)))
2099
[2603]2100 x = array(self._data._getabcissa(irow))
[2576]2101 if self._offset:
2102 x += self._offset
2103 if self._minmaxx is not None:
2104 s,e = self._slice_indeces(x)
2105 x = x[s:e]
2106 y = y[s:e]
2107 if len(x) > 1024 and rcParams['plotter.decimate']:
2108 fac = len(x)/1024
2109 x = x[::fac]
2110 y = y[::fac]
2111 self._plotter.set_line(label=lbl)
2112 plotit = self._plotter.plot
2113 if self._hist: plotit = self._plotter.hist
2114 if len(x) > 0 and not mr:
2115 plotit(x,y)
2116# xlim= self._minmaxx or [min(x),max(x)]
2117# allxlim += xlim
2118# ylim= self._minmaxy or [ma.minimum(y),ma.maximum(y)]
2119# allylim += ylim
2120# else:
2121# xlim = self._minmaxx or []
2122# allxlim += xlim
2123# ylim= self._minmaxy or []
2124# allylim += ylim
2125
2126 if npl >= ntotpl:
2127 break
2128
2129 if self._minmaxy is not None:
2130 self._plotter.set_limits(ylim=self._minmaxy)
2131 self._plotter.release()
2132 self._plotter.tidy()
2133 self._plotter.show(hardrefresh=False)
2134 return
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