source: trunk/python/asapplotter.py@ 364

Last change on this file since 364 was 282, checked in by mar637, 20 years ago

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[203]1from asap.asaplot import ASAPlot
[226]2from asap import rcParams
[203]3
4class asapplotter:
[226]5 """
6 The ASAP plotter.
7 By default the plotter is set up to plot polarisations
8 'colour stacked' and scantables across panels.
9 The defaul plotter is called 'plotter'.
10 Note:
11 Currenly it only plots 'spectra' not Tsys or
12 other variables.
13 """
[203]14 def __init__(self):
15 self._plotter = ASAPlot()
16
17 self._tdict = {'Time':'t','time':'t','t':'t','T':'t'}
18 self._bdict = {'Beam':'b','beam':'b','b':'b','B':'b'}
19 self._idict = {'IF':'i','if':'i','i':'i','I':'i'}
20 self._pdict = {'Pol':'p','pol':'p','p':'p'}
21 self._sdict = {'scan':'s','Scan':'s','s':'s','S':'s'}
22 self._cdict = {'t':'scan.nrow()',
23 'b':'scan.nbeam()',
24 'i':'scan.nif()',
25 'p':'scan.npol()',
26 's':'len(scans)'}
27 self._ldict = {'b':'Beam',
28 'i':'IF',
29 'p':'Pol',
30 's':'Scan'}
31 self._dicts = [self._tdict,self._bdict,
32 self._idict,self._pdict,
33 self._sdict]
34 self._panels = 's'
[226]35 self._stacking = rcParams['plotter.stacking']
[203]36 self._autoplot = False
37 self._minmax = None
38 self._data = None
39 self._lmap = []
[226]40 self._title = None
[257]41 self._ordinate = None
42 self._abcissa = None
[203]43
44 def _translate(self, name):
45 for d in self._dicts:
46 if d.has_key(name):
47 return d[name]
48 return None
49
50 def plot(self,*args):
51 """
52 Plot a (list of) scantables.
53 Parameters:
54 one or more comma separated scantables
55 Note:
56 If a (list) of scantables was specified in a previous call
57 to plot, no argument has to be given to 'replot'
58 NO checking is done that the abscissas of the scantables
59 are consistent e.g. all 'channel' or all 'velocity' etc.
60 """
61 if self._plotter.is_dead:
62 self._plotter = ASAPlot()
63 self._plotter.clear()
64 self._plotter.hold()
65 if len(args) > 0:
66 self._data = tuple(args)
67 if self._panels == 't':
68 if self._data[0].nrow() > 25:
69 print "Scan to be plotted contains more than 25 rows.\nCan't plot that many panels..."
70 return
71 self._plot_time(self._data[0], self._stacking)
72 elif self._panels == 's':
73 self._plot_scans(self._data, self._stacking)
74 else:
75 self._plot_other(self._data, self._stacking)
76 if self._minmax is not None:
77 self._plotter.set_limits(xlim=self._minmax)
78 self._plotter.release()
79 return
80
81 def _plot_time(self, scan, colmode):
82 if colmode == 't':
83 return
84 n = scan.nrow()
85 cdict = {'b':'scan.setbeam(j)',
86 'i':'scan.setif(j)',
87 'p':'scan.setpol(j)'}
88 if self._stacking is not None:
89 ncol = eval(self._cdict.get(colmode))
90 self._plotter.set_panels()
91 if n > 1:
92 self._plotter.set_panels(rows=n)
93 for i in range(n):
94 if n > 1:
95 self._plotter.palette(0)
96 self._plotter.subplot(i)
97 for j in range(ncol):
98 eval(cdict.get(colmode))
99 x = None
100 y = None
101 m = None
[226]102 if not self._title:
103 tlab = scan._getsourcename(i)
104 else:
105 if len(self._title) == n:
106 tlab = self._title[i]
107 else:
108 tlab = scan._getsourcename(i)
[203]109 x,xlab = scan.get_abcissa(i)
[257]110 if self._abcissa: xlab = self._abcissa
111 y = scan._getspectrum(i)
112 if self._ordinate:
113 ylab = self._ordinate
114 else:
115 ylab = 'Flux ('+scan.get_fluxunit()+')'
116 m = scan._getmask(i)
[226]117 if self._lmap and len(self._lmap) > 0:
[203]118 llab = self._lmap[j]
119 else:
120 llab = self._ldict.get(colmode)+' '+str(j)
121 self._plotter.set_line(label=llab)
122 self._plotter.plot(x,y,m)
123 xlim=[min(x),max(x)]
124 self._plotter.axes.set_xlim(xlim)
125 self._plotter.set_axes('xlabel',xlab)
126 self._plotter.set_axes('ylabel',ylab)
127 self._plotter.set_axes('title',tlab)
128 return
129
130 def _plot_scans(self, scans, colmode):
131 if colmode == 's':
132 return
133 cdict = {'b':'scan.setbeam(j)',
134 'i':'scan.setif(j)',
135 'p':'scan.setpol(j)'}
136 n = len(scans)
137 if self._stacking is not None:
138 scan = scans[0]
139 ncol = eval(self._cdict.get(colmode))
140 self._plotter.set_panels()
141 if n > 1:
142 self._plotter.set_panels(rows=n)
143 i = 0
144 for scan in scans:
145 if n > 1:
146 self._plotter.subplot(i)
147 self._plotter.palette(0)
148 for j in range(ncol):
149 eval(cdict.get(colmode))
150 x = None
151 y = None
152 m = None
[226]153 tlab = self._title
154 if not self._title:
155 tlab = scan._getsourcename()
[203]156 x,xlab = scan.get_abcissa()
[257]157 if self._abcissa: xlab = self._abcissa
158 y = scan._getspectrum()
159 if self._ordinate:
160 ylab = self._ordinate
161 else:
162 ylab = 'Flux ('+scan.get_fluxunit()+')'
163 m = scan._getmask()
164 if self._lmap and len(self._lmap) > 0:
[203]165 llab = self._lmap[j]
166 else:
167 llab = self._ldict.get(colmode)+' '+str(j)
168 self._plotter.set_line(label=llab)
169 self._plotter.plot(x,y,m)
170 xlim=[min(x),max(x)]
171 self._plotter.axes.set_xlim(xlim)
172
173 self._plotter.set_axes('xlabel',xlab)
174 self._plotter.set_axes('ylabel',ylab)
175 self._plotter.set_axes('title',tlab)
176 i += 1
177 return
178
179 def _plot_other(self,scans,colmode):
180 if colmode == self._panels:
181 return
182 cdict = {'b':'scan.setbeam(j)',
183 'i':'scan.setif(j)',
184 'p':'scan.setpol(j)',
185 's':'scans[j]'}
186 scan = scans[0]
187 n = eval(self._cdict.get(self._panels))
188 if self._stacking is not None:
189 ncol = eval(self._cdict.get(colmode))
190 self._plotter.set_panels()
191 if n > 1:
192 self._plotter.set_panels(rows=n)
193 for i in range(n):
194 if n>1:
195 self._plotter.subplot(i)
196 self._plotter.palette(0)
197 k=0
[282]198 j=i
[203]199 eval(cdict.get(self._panels))
200 for j in range(ncol):
201 if colmode == 's':
202 scan = eval(cdict.get(colmode))
203 elif colmode == 't':
204 k = j
205 else:
206 eval(cdict.get(colmode))
207 x = None
208 y = None
209 m = None
210 x,xlab = scan.get_abcissa(k)
[257]211 if self._abcissa: xlab = self._abcissa
212 y = scan._getspectrum(k)
213 if self._ordinate:
214 ylab = self._ordinate
215 else:
216 ylab = 'Flux ('+scan.get_fluxunit()+')'
217 m = scan._getmask(k)
[203]218 if colmode == 's' or colmode == 't':
[226]219 if not self._title:
220 tlab = self._ldict.get(self._panels)+' '+str(i)
221 else:
222 if len(self.title) == n:
223 tlab = self._title[i]
224 else:
225 tlab = self._ldict.get(self._panels)+' '+str(i)
[203]226 llab = scan._getsourcename(k)
227 else:
[226]228 if self._title and len(self._title) > 0:
[257]229 tlab = self._title[i]
[226]230 else:
[257]231 tlab = self._ldict.get(self._panels)+' '+str(i)
[226]232 if self._lmap and len(self._lmap) > 0:
[203]233 llab = self._lmap[j]
234 else:
235 llab = self._ldict.get(colmode)+' '+str(j)
236 self._plotter.set_line(label=llab)
237 self._plotter.plot(x,y,m)
238 xlim=[min(x),max(x)]
239 self._plotter.axes.set_xlim(xlim)
240
241 self._plotter.set_axes('xlabel',xlab)
242 self._plotter.set_axes('ylabel',ylab)
243 self._plotter.set_axes('title',tlab)
244
245 return
246
247
[226]248 def set_mode(self, stacking=None, panelling=None):
[203]249 """
250 Parameters:
251 stacking: tell the plotter which variable to plot
252 as line colour overlays (default 'pol')
253 panelling: tell the plotter which variable to plot
254 across multiple panels (default 'scan'
255 Note:
256 Valid modes are:
257 'beam' 'Beam' 'b': Beams
258 'if' 'IF' 'i': IFs
259 'pol' 'Pol' 'p': Polarisations
260 'scan' 'Scan' 's': Scans
261 'time' 'Time' 't': Times
262 """
263 if not self.set_panels(panelling):
264 print "Invalid mode"
[226]265 return
[203]266 if not self.set_stacking(stacking):
267 print "Invalid mode"
[226]268 return
269 if self._data: self.plot()
[203]270 return
271
[226]272 def set_panels(self, what=None):
273 if not what:
274 what = rcParams['plotter.panelling']
[203]275 md = self._translate(what)
276 if md:
[226]277 self._panels = md
278 self._title = None
[203]279 return True
280 return False
281
[226]282 def set_stacking(self, what=None):
283 if not what:
284 what = rcParams['plotter.stacking']
[203]285 md = self._translate(what)
286 if md:
287 self._stacking = md
[226]288 self._lmap = None
[203]289 return True
290 return False
291
292 def set_range(self,start=None,end=None):
293 """
294 Set the range of interest on the abcissa of the plot
295 Parameters:
296 start,end: The start an end point of the 'zoom' window
297 Note:
298 These become non-sensical when the unit changes.
299 use plotter.set_range() without parameters to reset
300
301 """
302 if start is None and end is None:
303 self._minmax = None
[226]304 if self._data: self.plot()
[203]305 else:
306 self._minmax = [start,end]
[226]307 if self._data: self.plot()
[203]308 return
309
[257]310 def set_legend(self, mp=None):
[203]311 """
312 Specify a mapping for the legend instead of using the default
313 indices:
314 Parameters:
315 mp: a list of 'strings'. This should have the same length
316 as the number of elements on the legend and then maps
317 to the indeces in order
318
319 Example:
320 If the data has to IFs/rest frequencies with index 0 and 1
321 for CO and SiO:
322 plotter.set_stacking('i')
323 plotter.set_legend_map(['CO','SiO'])
324 plotter.plot()
325 """
326 self._lmap = mp
[226]327 if self._data: self.plot()
328 return
329
330 def set_title(self, title=None):
331 self._title = title
332 if self._data: self.plot()
333 return
334
[257]335 def set_ordinate(self, ordinate=None):
336 self._ordinate = ordinate
337 if self._data: self.plot()
338 return
339
340 def set_abcissa(self, abcissa=None):
341 self._abcissa = abcissa
342 if self._data: self.plot()
343 return
344
345
346
[203]347if __name__ == '__main__':
348 plotter = asapplotter()
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