source: branches/Release-2-fixes/python/asapplotter.py@ 1272

from asap.asaplot import ASAPlot
from asap import rcParams

class asapplotter:
    """
    The ASAP plotter.
    By default the plotter is set up to plot polarisations
    'colour stacked' and scantables across panels.
    Note:
        Currenly it only plots 'spectra' not Tsys or
        other variables.
    """
    def __init__(self):
        self._plotter = ASAPlot()

        self._tdict = {'Time':'t','time':'t','t':'t','T':'t'}
        self._bdict = {'Beam':'b','beam':'b','b':'b','B':'b'}
        self._idict = {'IF':'i','if':'i','i':'i','I':'i'}
        self._pdict = {'Pol':'p','pol':'p','p':'p'}
        self._sdict = {'scan':'s','Scan':'s','s':'s','S':'s'}
        self._cdict = {'t':'len(self._cursor["t"])',
                       'b':'len(self._cursor["b"])',
                       'i':'len(self._cursor["i"])',
                       'p':'len(self._cursor["p"])',
                       's':'len(scans)'}
        self._ldict = {'b':'Beam',
                       'i':'IF',
                       'p':'Pol',
                       's':'Scan'}
        self._dicts = [self._tdict,self._bdict,
                       self._idict,self._pdict,
                       self._sdict]
        self._panelling = None
        self._stacking = None
        self.set_panelling()
        self.set_stacking()
        self._rows = None
        self._cols = None
        self._autoplot = False
        self._minmaxx = None
        self._minmaxy = None
        self._data = None
        self._lmap = None
        self._title = None
        self._ordinate = None
        self._abcissa = None
        self._abcunit = None
        self._cursor = {'t':None, 'b':None,
                        'i':None, 'p':None
                        }

    def _translate(self, name):
        for d in self._dicts:
            if d.has_key(name):
                return d[name]
        return None
        
    def plot(self, *args):
        """
        Plot a (list of) scantables.
        Parameters:
            one or more comma separated scantables 
        Note:
            If a (list) of scantables was specified in a previous call
            to plot, no argument has to be given to 'replot'
            NO checking is done that the abcissas of the scantables
            are consistent e.g. all 'channel' or all 'velocity' etc.
        """
        if self._plotter.is_dead:
            self._plotter = ASAPlot()
        self._plotter.hold()
        self._plotter.clear()
        if len(args) > 0:
            if self._data is not None:                
                if list(args) != self._data:
                    self._data = list(args)
                    # reset cursor
                    self.set_cursor(refresh=False)
            else:
                self._data = list(args)
                self.set_cursor(refresh=False)
        # ranges become invalid when unit changes
        if self._abcunit != self._data[0].get_unit():
            self._minmaxx = None
            self._minmaxy = None
            self._abcunit = self._data[0].get_unit()
        if self._panelling == 't':
            maxrows = 25
            if self._data[0].nrow() > maxrows:
                if self._cursor["t"] is None or \
                       (isinstance(self._cursor["t"],list) and \
                        len(self._cursor["t"]) > maxrows ):
                    print "Scan to be plotted contains more than %d rows.\n" \
                          "Selecting first %d rows..." % (maxrows,maxrows)
                    self._cursor["t"] = range(maxrows)
            self._plot_time(self._data[0], self._stacking)
        elif self._panelling == 's':
            self._plot_scans(self._data, self._stacking)
        else:
            self._plot_other(self._data, self._stacking)
        if self._minmaxy is not None:
            self._plotter.set_limits(ylim=self._minmaxy)
        self._plotter.release()
        return

    def _plot_time(self, scan, colmode):
        if colmode == 't':
            return
        n = len(self._cursor["t"])
        cdict = {'b':'scan.setbeam(j)',
                 'i':'scan.setif(j)',
                 'p':'scan.setpol(j)'}
        cdict2 = {'b':'self._cursor["b"]',
                  'i':'self._cursor["i"]',
                  'p':'self._cursor["p"]'}
        ncol = 1
        if self._stacking is not None:
            ncol = eval(self._cdict.get(colmode))
        if n > 1:
            if self._rows and self._cols:
                n = min(n,self._rows*self._cols)
                self._plotter.set_panels(rows=self._rows,cols=self._cols,
                                         nplots=n)
            else:
                self._plotter.set_panels(rows=n,cols=0,nplots=n)
        else:
            self._plotter.set_panels()
        rows = self._cursor["t"]
        self._plotter.palette(0)
        for rowsel in rows:
            i = self._cursor["t"].index(rowsel)
            if n > 1:
                self._plotter.palette(0)
                self._plotter.subplot(i)
            colvals = eval(cdict2.get(colmode))
            for j in colvals:
                polmode = "raw"
                jj = colvals.index(j)
                savej = j
                for k in cdict.keys():
                    sel = eval(cdict2.get(k))                    
                    j = sel[0]
                    if k == "p":
                        which = self._cursor["p"].index(j)
                        polmode = self._polmode[which]
                        j = which
                    eval(cdict.get(k))
                j = savej
                if colmode == "p":
                    polmode = self._polmode[self._cursor["p"].index(j)]
                    #j = jj
                eval(cdict.get(colmode))
                x = None
                y = None
                m = None
                if self._title is None:
                    tlab = scan._getsourcename(rowsel)                    
                else:
                    if len(self._title) >= n:
                        tlab = self._title[rowsel]
                    else:
                        tlab = scan._getsourcename(rowsel)
                x,xlab = scan.get_abcissa(rowsel)
                if self._abcissa: xlab = self._abcissa
                y = None
                if polmode == "stokes":
                    y = scan._getstokesspectrum(rowsel)
                elif polmode == "stokes2":
                    y = scan._getstokesspectrum(rowsel,True)
                elif polmode == "circular":
                    y = scan._stokestopolspectrum(rowsel,False,-1)
                else:
                    y = scan._getspectrum(rowsel)
                if self._ordinate:
                    ylab = self._ordinate
                else:
                    ylab = scan._get_ordinate_label()
                m = scan._getmask(rowsel)
                if self._lmap and len(self._lmap) > 0:
                    llab = self._lmap[jj]
                else:
                    if colmode == 'p':
                        llab = self._get_pollabel(scan, polmode)
                    else:                    
                        llab = self._ldict.get(colmode)+' '+str(j)
                self._plotter.set_line(label=llab)
                if self._minmaxx is not None:
                    s,e = self._slice_indeces(x)
                    x = x[s:e]
                    y = y[s:e]
                    m = m[s:e]
                self._plotter.plot(x,y,m)
                
                xlim=[min(x),max(x)]
                if self._minmaxx is not None:
                    xlim = self._minmaxx
                self._plotter.axes.set_xlim(xlim)
            self._plotter.set_axes('xlabel',xlab)
            self._plotter.set_axes('ylabel',ylab)
            self._plotter.set_axes('title',tlab)            
        return

    def _plot_scans(self, scans, colmode):
        print "Plotting mode is scans across panels. Can only plot one row per scan."
        if colmode == 's':
            return
        cdict = {'b':'scan.setbeam(j)',
                 'i':'scan.setif(j)',
                 'p':'scan.setpol(j)'}
        cdict2 = {'b':'self._cursor["b"]',
                  'i':'self._cursor["i"]',
                  'p':'self._cursor["p"]'}
        
        n = len(scans)
        ncol = 1
        if self._stacking is not None:
            scan = scans[0]
            ncol = eval(self._cdict.get(colmode))
        if n > 1:
            if self._rows and self._cols:
                n = min(n,self._rows*self._cols)
                self._plotter.set_panels(rows=self._rows,cols=self._cols,
                                         nplots=n)
            else:
                self._plotter.set_panels(rows=n,cols=0,nplots=n)
        else:
            self._plotter.set_panels()

        for scan in scans:
            self._plotter.palette(0)
            if n > 1:
                self._plotter.subplot(scans.index(scan))
            colvals = eval(cdict2.get(colmode))
            rowsel = self._cursor["t"][0]
            for j in colvals:
                polmode = "raw"
                jj = colvals.index(j)
                savej = j
                for k in cdict.keys():
                    sel = eval(cdict2.get(k))                    
                    j = sel[0]
                    eval(cdict.get(k))
                    if k == "p":
                        which = self._cursor["p"].index(j)
                        polmode = self._polmode[which]
                        j = which
                j = savej
                if colmode == "p":
                    polmode = self._polmode[self._cursor["p"].index(j)]
                    #j = jj
                eval(cdict.get(colmode))
                x = None
                y = None
                m = None
                tlab = self._title
                if not self._title:
                    tlab = scan._getsourcename(rowsel)
                x,xlab = scan.get_abcissa(rowsel)
                if self._abcissa: xlab = self._abcissa
                if polmode == "stokes":
                    y = scan._getstokesspectrum(rowsel)
                elif polmode == "stokes2":
                    y = scan._getstokesspectrum(rowsel,True)
                elif polmode == "circular":
                    y = scan._stokestopolspectrum(rowsel,False,-1)
                else:
                    y = scan._getspectrum(rowsel)
                if self._ordinate:
                    ylab = self._ordinate
                else:
                    ylab = scan._get_ordinate_label()
                m = scan._getmask(rowsel)
                if self._lmap and len(self._lmap) > 0:
                    llab = self._lmap[jj]
                else:
                    if colmode == 'p':
                        llab = self._get_pollabel(scan, polmode)
                    else:
                        llab = self._ldict.get(colmode)+' '+str(j)
                self._plotter.set_line(label=llab)
                if self._minmaxx is not None:
                    s,e = self._slice_indeces(x)
                    x = x[s:e]
                    y = y[s:e]
                    m = m[s:e]

                self._plotter.plot(x,y,m)
                xlim=[min(x),max(x)]
                if self._minmaxx is not None:
                    xlim = self._minmaxx
                self._plotter.axes.set_xlim(xlim)

            self._plotter.set_axes('xlabel',xlab)
            self._plotter.set_axes('ylabel',ylab)
            self._plotter.set_axes('title',tlab)
        return
    
    def _plot_other(self,scans,colmode):
        if colmode == self._panelling:
            return
        cdict = {'b':'scan.setbeam(i)',
                 'i':'scan.setif(i)',
                 'p':'scan.setpol(i)'}
        cdict2 = {'b':'self._cursor["b"]',
                  'i':'self._cursor["i"]',
                  'p':'self._cursor["p"]',
                  's': 'scans',
                  't': 'self._cursor["t"]'}
        scan = scans[0]
        n = eval(self._cdict.get(self._panelling))
        ncol=1
        if self._stacking is not None:            
            ncol = eval(self._cdict.get(colmode))
        if n > 1:
            if self._rows and self._cols:
                n = min(n,self._rows*self._cols)
                self._plotter.set_panels(rows=self._rows,cols=self._cols,
                                         nplots=n)
            else:
                self._plotter.set_panels(rows=n,cols=0,nplots=n)
        else:
            self._plotter.set_panels()            
        panels = self._cursor[self._panelling]        
        for i in panels:
            self._plotter.palette(0)
            polmode = "raw"
            ii = self._cursor[self._panelling].index(i)
            if n>1:
                self._plotter.subplot(ii)
            if self._panelling == "p":
                polmode = self._polmode[ii]
                eval(cdict.get(self._panelling))
            else:
                eval(cdict.get(self._panelling))
            colvals = eval(cdict2.get(colmode))
            for j in colvals:
                rowsel = self._cursor["t"][0]
                jj = colvals.index(j)
                savei = i
                for k in cdict.keys():
                    if k != self._panelling:
                        sel = eval(cdict2.get(k))
                        i = sel[0]
                        if k == "p":
                            which = self._cursor["p"].index(i)
                            polmode = self._polmode[which]
                            i = which                        
                        eval(cdict.get(k))
                i = savei
                if colmode == 's':
                    scan = j
                elif colmode == 't':
                    rowsel = j                    
                else:
                    savei = i
                    if colmode == 'p':
                        polmode = self._polmode[self._cursor["p"].index(j)]
                    i = j
                    eval(cdict.get(colmode))
                    i = savei
                x = None
                y = None
                m = None
                x,xlab = scan.get_abcissa(rowsel)
                if self._abcissa: xlab = self._abcissa
                if polmode == "stokes":
                    y = scan._getstokesspectrum(rowsel)
                elif polmode == "stokes2":
                    y = scan._getstokesspectrum(rowsel,True)
                elif polmode == "circular":
                    y = scan._stokestopolspectrum(rowsel,False,-1)
                else:
                    y = scan._getspectrum(rowsel)

                if self._ordinate:
                    ylab = self._ordinate
                else:
                    ylab = scan._get_ordinate_label()
                m = scan._getmask(rowsel)
                if colmode == 's' or colmode == 't':
                    if self._title and len(self._title) > 0:
                        tlab = self._title[ii]
                    else:
                        if self._panelling == 'p':
                            tlab = self._get_pollabel(scan, polmode)
                        else:
                            tlab = self._ldict.get(self._panelling)+' '+str(i)
                    if self._lmap and len(self._lmap) > 0:
                        llab = self._lmap[jj]
                    else:
                        llab = scan._getsourcename(rowsel)
                else:
                    if self._title and len(self._title) > 0:
                        tlab = self._title[ii]
                    else:
                        if self._panelling == 'p':
                            tlab = self._get_pollabel(scan, polmode)
                        else:
                            tlab = self._ldict.get(self._panelling)+' '+str(i)
                    if self._lmap and len(self._lmap) > 0:
                        llab = self._lmap[jj]
                    else:
                        if colmode == 'p':
                            llab = self._get_pollabel(scan, polmode)
                        else:
                            llab = self._ldict.get(colmode)+' '+str(j)
                self._plotter.set_line(label=llab)
                if self._minmaxx is not None:
                    s,e = self._slice_indeces(x)
                    x = x[s:e]
                    y = y[s:e]
                    m = m[s:e]

                self._plotter.plot(x,y,m)
                xlim=[min(x),max(x)]
                if self._minmaxx is not None:
                    xlim = self._minmaxx
                self._plotter.axes.set_xlim(xlim)

            self._plotter.set_axes('xlabel',xlab)
            self._plotter.set_axes('ylabel',ylab)
            self._plotter.set_axes('title',tlab)
        
        return


    def set_mode(self, stacking=None, panelling=None):
        """
        Set the plots look and feel, i.e. what you want to see on the plot.
        Parameters:
            stacking:     tell the plotter which variable to plot
                          as line color overlays (default 'pol')
            panelling:    tell the plotter which variable to plot
                          across multiple panels (default 'scan'
        Note:
            Valid modes are:
                 'beam' 'Beam' 'b':     Beams
                 'if' 'IF' 'i':         IFs
                 'pol' 'Pol' 'p':       Polarisations
                 'scan' 'Scan' 's':     Scans
                 'time' 'Time' 't':     Times
        """
        if not self.set_panelling(panelling):
            print "Invalid mode"
            return
        if not self.set_stacking(stacking):
            print "Invalid mode"
            return
        if self._data: self.plot()
        return

    def set_panelling(self, what=None):
        mode = what
        if mode is None:
             mode = rcParams['plotter.panelling']
        md = self._translate(mode)
        if md:
            self._panelling = md
            self._title = None
            return True
        return False

    def set_layout(self,rows=None,cols=None):
        """
        Set the multi-panel layout, i.e. how many rows and columns plots
        are visible.
        Parameters:
             rows:   The number of rows of plots
             cols:   The number of columns of plots
        Note:
             If no argument is given, the potter reverts to its auto-plot
             behaviour.
        """
        self._rows = rows
        self._cols = cols
        if self._data: self.plot()
        return

    def set_stacking(self, what=None):  
        mode = what
        if mode is None:            
             mode = rcParams['plotter.stacking']        
        md = self._translate(mode)
        if md:
            self._stacking = md
            self._lmap = None
            return True
        return False

    def set_range(self,xstart=None,xend=None,ystart=None,yend=None):
        """
        Set the range of interest on the abcissa of the plot
        Parameters:
            [x,y]start,[x,y]end:  The start and end points of the 'zoom' window
        Note:
            These become non-sensical when the unit changes.
            use plotter.set_range() without parameters to reset

        """
        if xstart is None and xend is None:
            self._minmaxx = None
        else:
            self._minmaxx = [xstart,xend]
        if ystart is None and yend is None:
            self._minmaxy = None
        else:
            self._minmaxy = [ystart,yend]            
        if self._data: self.plot()
        return
    
    def set_legend(self, mp=None):
        """
        Specify a mapping for the legend instead of using the default
        indices:
        Parameters:
             mp:    a list of 'strings'. This should have the same length
                    as the number of elements on the legend and then maps
                    to the indeces in order. It is possible to uses latex
                    math expression. These have to be enclosed in r'', e.g. r'$x^{2}$'

        Example:
             If the data has two IFs/rest frequencies with index 0 and 1
             for CO and SiO:
             plotter.set_stacking('i')
             plotter.set_legend(['CO','SiO'])
             plotter.plot()
             plotter.set_legend([r'$^{12}CO$', r'SiO'])
        """
        self._lmap = mp
        if self._data: self.plot()
        return

    def set_title(self, title=None):
        """
        Set the title of the plot. If multiple panels are plotted,
        multiple titles have to be specified.
        Example:
             # two panels are visible on the plotter
             plotter.set_title(["First Panel","Second Panel"])
        """
        self._title = title
        if self._data: self.plot()
        return

    def set_ordinate(self, ordinate=None):
        """
        Set the y-axis label of the plot. If multiple panels are plotted,
        multiple labels have to be specified.
        Example:
             # two panels are visible on the plotter
             plotter.set_ordinate(["First Y-Axis","Second Y-Axis"])
        """
        self._ordinate = ordinate
        if self._data: self.plot()
        return

    def set_abcissa(self, abcissa=None):
        """
        Set the x-axis label of the plot. If multiple panels are plotted,
        multiple labels have to be specified.
        Example:
             # two panels are visible on the plotter
             plotter.set_ordinate(["First X-Axis","Second X-Axis"])
        """
        self._abcissa = abcissa
        if self._data: self.plot()
        return

    def set_colors(self, colormap):
        """
        Set the colors to be used. The plotter will cycle through
        these colors when lines are overlaid (stacking mode).
        Example:
             plotter.set_colors("red green blue")
             # If for example four lines are overlaid e.g I Q U V
             # 'I' will be 'red', 'Q' will be 'green', U will be 'blue'
             # and 'V' will be 'red' again.
        """
        self._plotter.palette(0,colormap=colormap)
        if self._data: self.plot()

    def set_linestyles(self, linestyles):
        """
        Parameters:
             linestyles:     a list of linestyles to use.
                             'line', 'dashed', 'dotted', 'dashdot',
                             'dashdotdot' and 'dashdashdot' are
                             possible
                             
        Set the linestyles to be used. The plotter will cycle through
        these linestyles when lines are overlaid (stacking mode) AND
        only one color has been set.
        Example:
             plotter.set_colors("black")
             plotter.set_linestyles("line dashed dotted dashdot")
             # If for example four lines are overlaid e.g I Q U V
             # 'I' will be 'solid', 'Q' will be 'dashed',
             # U will be 'dotted' and 'V' will be 'dashdot'.
        """
        self._plotter.palette(color=0,linestyle=0,linestyles=linestyles)
        if self._data: self.plot()
    
    def save(self, filename=None, orientation=None):
        """
        Save the plot to a file. The know formats are 'png', 'ps', 'eps'.
        Parameters:
             filename:    The name of the output file. This is optional
                          and autodetects the image format from the file
                          suffix. If non filename is specified a file
                          called 'yyyymmdd_hhmmss.png' is created in the
                          current directory.
             orientation: optional parameter for postscript only (not eps).
                          'landscape', 'portrait' or None (default) are valid.
                          If None is choosen for 'ps' output, the plot is
                          automatically oriented to fill the page.
        """
        self._plotter.save(filename,orientation)
        return
    
    def set_cursor(self, row=None,beam=None,IF=None,pol=None, refresh=True):
        """
        Specify a 'cursor' for plotting selected spectra. Time (rows),
        Beam, IF, Polarisation ranges can be specified.
        Parameters:
            Default for all paramaters is to select all available
            row:    selects the rows (time stamps) to be plotted, this has
                    to be a vector of row indices, e.g. row=[0,2,5] or row=[2]
            beam:   select a range of beams
            IF:     select a range of IFs
            pol:    select Polarisations for plotting these can be by index
                    (raw polarisations (default)) or by names any of:
                    ["I", "Q", "U", "V"] or
                    ["I", "Plinear", "Pangle", "V"] or
                    ["XX", "YY", "Real(XY)", "Imag(XY)"] or
                    ["RR", "LL"]
        Example:
            plotter.set_mode('pol','time')
            plotter.plot(myscan) # plots all raw polarisations colour stacked
            plotter.set_cursor(pol=["I"]) # plot "I" only for all rows
            # plot "I" only for two time stamps row=0 and row=2
            plotter.set_cursor(row=[0,2],pol=["I"])

        Note:
            Be careful to select only exisiting polarisations.            
        """
        if not self._data:
            print "Can only set cursor after a first call to plot()"
            return
        
        n = self._data[0].nrow()
        if row is None:
            self._cursor["t"] = range(n)
        else:
            for i in row:
                if i < 0 or i >= n:
                    print "Row index '%d' out of range" % i
                    return
            self._cursor["t"] = row

        n = self._data[0].nbeam()
        if beam is None:
            self._cursor["b"] = range(n)
        else:
            for i in beam:
                if i < 0 or  i >= n:
                    print "Beam index '%d' out of range" % i
                    return            
            self._cursor["b"] = beam

        n = self._data[0].nif()
        if IF is None:
            self._cursor["i"] = range(n)
        else:
            for i in IF:
                if i < 0 or i >= n:
                    print "IF index '%d' out of range" %i
                    return            
            self._cursor["i"] = IF            

        n = self._data[0].npol()
        dstokes = {"I":0,"Q":1,"U":2,"V":3}
        dstokes2 = {"I":0,"Plinear":1,"Pangle":2,"V":3}
        draw = {"XX":0, "YY":1,"Real(XY)":2, "Imag(XY)":3}
        dcirc = { "RR":0,"LL":1}#,"Real(RL)":2,"Imag(RL)":3}
        
        if pol is None:
            self._cursor["p"] = range(n)
            self._polmode = ["raw" for i in range(n)]
        else:
            if isinstance(pol,str):
                pol = pol.split()
            polmode = []
            pols = []
            for i in pol:
                if isinstance(i,str):
                    if draw.has_key(i):
                        pols.append(draw.get(i))
                        polmode.append("raw")
                    elif dstokes.has_key(i):
                        pols.append(dstokes.get(i))
                        polmode.append("stokes")
                    elif dstokes2.has_key(i):
                        pols.append(dstokes2.get(i))
                        polmode.append("stokes2")
                    elif dcirc.has_key(i):
                        pols.append(dcirc.get(i))
                        polmode.append("circular")
                    else:
                        print "Pol type '%s' not valid" %i
                        return
                elif 0 > i >= n:
                    print "Pol index '%d' out of range" %i
                    return
                else:
                    pols.append(i)
                    polmode.append("raw")
            self._cursor["p"] = pols
            self._polmode = polmode
        if self._data and refresh: self.plot()

    def _get_pollabel(self, scan, polmode):
        tlab = ""
        if polmode == "stokes":
            tlab = scan._getpolarizationlabel(0,1,0)
        elif polmode == "stokes2":
            tlab = scan._getpolarizationlabel(0,1,1)
        elif polmode == "circular":
            tlab = scan._getpolarizationlabel(0,0,0)
        else:
            tlab = scan._getpolarizationlabel(1,0,0)
        return tlab

    def _slice_indeces(self, data):
        mn = self._minmaxx[0]
        mx = self._minmaxx[1]
        asc = data[0] < data[-1]        
        start=0
        end = len(data)-1
        inc = 1
        if not asc:
            start = len(data)-1
            end = 0
            inc = -1
        # find min index
        while data[start] < mn:
            start+= inc
        # find max index
        while data[end] > mx:
            end-=inc
        end +=1
        if start > end:
            return end,start 
        return start,end
            
if __name__ == '__main__':
    plotter = asapplotter()