#!/usr/bin/python import sys import time import numpy as np from configparser import ConfigParser from epics.utils import IOENCODING from .. import Device, get_pv, poll, caput, caget MAX_ROIS = 32 class DXP(Device): _attrs = ('PreampGain','MaxEnergy','ADCPercentRule','BaselineCutPercent', 'BaselineThreshold','BaselineFilterLength','BaselineCutEnable', 'InputCountRate', 'OutputCountRate', 'GapTime','PeakingTime','EnergyThreshold','MaxWidth', 'PresetMode', 'TriggerPeakingTime', 'TriggerGapTime','TriggerThreshold') def __init__(self,prefix,mca=1): self._prefix = "%sdxp%i" % (prefix, mca) Device.__init__(self, self._prefix, delim=':') poll() class ROI(Device): """epics ROI device for MCA record >>> from epics.devices.mca import ROI, MCA >>> r = ROI('PRE:mca1', roi=1) >>> print r.name, r.left, r.right arguments --------- prefix MCA record prefix roi integer for ROI (0 through 31) bgr_width width in bins for calculating NET counts data_pv optional PV name to read counts from (not needed for most MCA records, but useful for some) attribute (read/write) ---------------------- LO, left low bin for ROI HI, right high bin for ROI NM, name name properties (read only) ----------------------- center roi center bin width roi width (in bins) address == prefix total sum counts in ROI net background-subtracted sum counts in ROI methods ------- clear remove ROI """ _nonpvs = ('_prefix', '_pvs', '_delim', 'attrs', 'width', 'center', 'bgr_width', 'address', 'net', 'total', '_dat_', '_net_') _aliases = {'left': 'LO', 'right': 'HI', 'name': 'NM'} def __init__(self, prefix, roi=0, bgr_width=3, data_pv=None): self.address = self._prefix = '%s.R%i' % (prefix, roi) self.bgr_width = bgr_width _attrs = ('NM', 'LO', 'HI') Device.__init__(self,self._prefix, delim='', attrs=_attrs, aliases=self._aliases, with_poll=False) if data_pv is None: data_pv = self.address if isinstance(data_pv, basestring): data_pv = get_pv(data_pv) self._pvs['_dat_'] = data_pv self._pvs['_net_'] = get_pv(self.address + 'N') def __eq__(self, other): """used for comparisons""" return (self.LO == getattr(other, 'LO', None) and self.HI == getattr(other, 'HI', None) and self.bgr_width == getattr(other, 'bgr_width', None) ) def __ne__(self, other): return not self.__eq__(other) def __lt__(self, other): return self.LO < getattr(other, 'LO', None) def __le__(self, other): return self.LO <= getattr(other, 'LO', None) def __gt__(self, other): return self.LO > getattr(other, 'LO', None) def __ge__(self, other): return self.LO >= getattr(other, 'LO', None) def __repr__(self): "string representation" pref = self._prefix if pref.endswith('.'): pref = pref[:-1] return "" % (pref, self.NM, self.LO, self.HI) #return "" % (pref, self.NM, # self.LO, self.HI) @property def total(self): return self.get_counts(net=False) @property def sum(self): return self.get_counts(net=False) @property def net(self): return self.get_counts(net=True) @property def center(self): return int(round(self.HI + self.LO)/2.0) @property def width(self): return int(round(self.HI - self.LO)) def clear(self): self.NM = '' self.LO = -1 self.HI = -1 def get_counts(self, data=None, net=False): """ calculate total and net counts for a spectra Parameters: ----------- * data: numpy array of spectra or None to read from PV * net: bool to set net counts (default=False: total counts returned) """ # implicitly read data from a PV if data is None and self._pvs['_dat_'] is not None: data = self._pvs['_dat_'].get() if net and not isinstance(data, np.ndarray): data = self._pvs['_net_'].get() if not isinstance(data, np.ndarray): return data total = data[self.LO:self.HI+1].sum() if not net: return total # calculate net counts bgr_width = int(self.bgr_width) ilmin = max((self.LO - bgr_width), 0) irmax = min((self.HI + bgr_width), len(data)-1) + 1 bgr_counts = np.concatenate((data[ilmin:self.LO], data[self.HI+1:irmax])).mean() return (total - bgr_counts*(self.HI-self.LO)) class MCA(Device): _attrs =('CALO', 'CALS', 'CALQ', 'TTH', 'EGU', 'PRTM', 'PLTM', 'ACQG', 'NUSE', 'DWEL', 'ERTM', 'ELTM', 'IDTIM') _nonpvs = ('_prefix', '_pvs', '_delim', '_npts', 'rois', '_nrois', 'rois') def __init__(self, prefix, mca=None, nrois=None, data_pv=None): self._prefix = prefix self._npts = None self._nrois = nrois if self._nrois is None: self._nrois = MAX_ROIS self.rois = [] if isinstance(mca, int): self._prefix = "%smca%i" % (prefix, mca) Device.__init__(self,self._prefix, delim='.', attrs=self._attrs, with_poll=False) self._pvs['VAL'] = get_pv("%sVAL" % self._prefix, auto_monitor=False) self._pvs['_dat_'] = None if data_pv is not None: self._pvs['_dat_'] = get_pv(data_pv) poll() def get_rois(self, nrois=None): self.rois = [] data_pv = self._pvs['_dat_'] prefix = self._prefix if prefix.endswith('.'): prefix = prefix[:-1] if nrois is None: nrois = self._nrois for i in range(nrois): roi = ROI(prefix=prefix, roi=i, data_pv=data_pv) if roi.NM is None: break if len(roi.NM.strip()) <= 0 or roi.HI <= 0: break self.rois.append(roi) poll() return self.rois def del_roi(self, roiname): self.get_rois() for roi in self.rois: if roi.NM.strip().lower() == roiname.strip().lower(): roi.clear() poll(0.010, 1.0) self.set_rois(self.rois) def add_roi(self, roiname, lo=-1, hi=-1, calib=None): """add an roi, given name, lo, and hi channels, and an optional calibration other than that of this mca. That is, specifying an ROI with all of lo, hi AND calib will set the ROI **by energy** so that it matches the provided calibration. To add an ROI to several MCAs with differing calibration, use cal_1 = mca1.get_calib() for mca im (mca1, mca2, mca3, mca4): mca.add_roi('Fe Ka', lo=600, hi=700, calib=cal_1) """ if lo < 0 or hi <0: return rois = self.get_rois() try: iroi = len(rois) except: iroi = 0 if iroi >= MAX_ROIS: raise ValueError('too many ROIs - cannot add more %i/%i' % (iroi, MAX_ROIS)) data_pv = self._pvs['_dat_'] prefix = self._prefix if prefix.endswith('.'): prefix = prefix[:-1] roi = ROI(prefix=prefix, roi=iroi, data_pv=self._pvs['_dat_']) roi.NM = roiname.strip() offset, scale = 0.0, 1.0 if calib is not None: off, slope, quad = self.get_calib() offset = calib[0] - off scale = calib[1] / slope roi.LO = round(offset + scale*lo) roi.HI = round(offset + scale*hi) rois.append(roi) self.set_rois(rois) def set_rois(self, rois, calib=None): """set all rois, with optional calibration that those ROIs correspond to (if they have a different energy calibration), and ensures they are ordered and contiguous. A whole set of ROIs can be copied by energy from one mca to another with: rois = mca1.get_rois() calib = mca1.get_calib() mca2.set_rois(rois, calib=calib) """ data_pv = self._pvs['_dat_'] prefix = self._prefix if prefix.endswith('.'): prefix = prefix[:-1] offset, scale = 0.0, 1.0 if calib is not None: off, slope, quad = self.get_calib() offset = calib[0] - off scale = calib[1] / slope # do an explicit get here to make sure all data is # available before trying to sort it! poll(0.0050, 1.0) [(r.get('NM'), r.get('LO')) for r in rois] roidat = [(r.NM, r.LO, r.HI) for r in sorted(rois)] iroi = 0 self.rois = [] for name, lo, hi in roidat: if len(name)<1 or lo<0 or hi<0: continue roi = ROI(prefix=prefix, roi=iroi, data_pv=data_pv) roi.NM = name.strip() roi.LO = round(offset + scale*lo) roi.HI = round(offset + scale*hi) self.rois.append(roi) iroi += 1 # erase any remaning ROIs for i in range(iroi, MAX_ROIS): lo = caget("%s.R%iLO" % (prefix, i)) if lo < 0: break caput("%s.R%iLO" % (prefix, i), -1) caput("%s.R%iHI" % (prefix, i), -1) caput("%s.R%iNM" % (prefix, i), '') def clear_rois(self, nrois=None): for roi in self.get_rois(nrois=nrois): roi.clear() self.rois = [] def get_calib(self): return [self.get(i) for i in ('CALO','CALS','CALQ')] def get_energy(self): if self._npts is None: self._npts = len(self.get('VAL')) en = np.arange(self._npts, dtype='f8') cal = self.get_calib() return cal[0] + en*(cal[1] + en*cal[2]) class MultiXMAP(Device): """ multi-Channel XMAP DXP device """ attrs = ['PresetReal','Dwell','Acquiring', 'EraseStart','StopAll', 'PresetMode', 'PixelsPerBuffer_RBV', 'NextPixel', 'PixelsPerRun', 'Apply', 'AutoApply', 'CollectMode', 'SyncCount', 'BufferSize_RBV'] pathattrs = ('FilePath', 'FileTemplate', 'FileWriteMode', 'FileName', 'FileNumber', 'FullFileName_RBV', 'Capture', 'NumCapture', 'WriteFile_RBV', 'AutoSave', 'EnableCallbacks', 'ArraySize0_RBV', 'FileTemplate_RBV', 'FileName_RBV', 'AutoIncrement') _nonpvs = ('_prefix', '_pvs', '_delim', 'filesaver', 'pathattrs', '_nonpvs', 'nmca', 'dxps', 'mcas') def __init__(self, prefix, filesaver='netCDF1:',nmca=4): self.filesaver = filesaver self._prefix = prefix self.nmca = nmca self.dxps = [DXP(prefix, mca=i+1) for i in range(nmca)] self.mcas = [MCA(prefix, mca=i+1) for i in range(nmca)] Device.__init__(self, prefix, attrs=self.attrs, delim='', mutable=True) for p in self.pathattrs: pvname = '%s%s%s' % (prefix, filesaver, p) self.add_pv(pvname, attr=p) def get_calib(self): return [m.get_calib() for m in self.mcas] def get_rois(self): return [m.get_rois() for m in self.mcas] def roi_calib_info(self): buff = ['[rois]'] add = buff.append rois = self.get_rois() for iroi in range(len(rois[0])): name = rois[0][iroi].NM s = [[rois[m][iroi].LO, rois[m][iroi].HI] for m in range(self.nmca)] dat = repr(s).replace('],', '').replace('[', '').replace(']','').replace(',','') add("ROI%2.2i = %s | %s" % (iroi, name, dat)) caldat = np.array(self.get_calib()) add('[calibration]') add("OFFSET = %s " % (' '.join(["%.7g" % i for i in caldat[:, 0]]))) add("SLOPE = %s " % (' '.join(["%.7g" % i for i in caldat[:, 1]]))) add("QUAD = %s " % (' '.join(["%.7g" % i for i in caldat[:, 2]]))) add('[dxp]') for a in self.dxps[0]._attrs: vals = [str(dxp.get(a, as_string=True)).replace(' ','_') for dxp in self.dxps] add("%s = %s" % (a, ' '.join(vals))) return buff def restore_rois(self, roifile): """restore ROI setting from ROI.dat file""" cp = ConfigParser() cp.read(roifile) rois = [] self.mcas[0].clear_rois() prefix = self.mcas[0]._prefix if prefix.endswith('.'): prefix = prefix[:-1] iroi = 0 for a in cp.options('rois'): if a.lower().startswith('roi'): name, dat = cp.get('rois', a).split('|') lims = [int(i) for i in dat.split()] lo, hi = lims[0], lims[1] roi = ROI(prefix=prefix, roi=iroi) roi.LO = lo roi.HI = hi roi.NM = name.strip() rois.append(roi) iroi += 1 poll(0.050, 1.0) self.mcas[0].set_rois(rois) cal0 = self.mcas[0].get_calib() for mca in self.mcas[1:]: mca.set_rois(rois, calib=cal0) def Write_CurrentConfig(self, filename=None): buff = [] add = buff.append add('#Multi-Element xMAP Settings saved: %s' % time.ctime()) add('[general]') add('prefix= %s' % self._prefix) add('nmcas = %i' % self.nmca) add('filesaver= %s' % self.filesaver) d.add('starting roi....') buff.extend( self.roi_calib_info() ) d.add('wrote roi / calib / dxp') buff = '\n'.join(buff) if filename is not None: fh = open(filename,'w', encoding=IOENCODING) fh.write(buff) fh.close() d.add('wrote file') # d.show() return buff def start(self): "Start Struck" self.EraseStart = 1 if self.Acquiring == 0: poll() self.EraseStart = 1 return self.EraseStart def stop(self): "Stop Struck Collection" self.StopAll = 1 return self.StopAll def next_pixel(self): "Advance to Next Pixel:" self.NextPixel = 1 return self.NextPixel def finish_pixels(self, timeout=2): "Advance to Next Pixel until CurrentPixel == PixelsPerRun" pprun = self.PixelsPerRun cur = self.dxps[0].get('CurrentPixel') t0 = time.time() while cur < pprun and time.time()-t0 < timeout: time.sleep(0.1) pprun = self.PixelsPerRun cur = self.dxps[0].get('CurrentPixel') ok = cur >= pprun if not ok: print('XMAP needs to finish pixels ', cur, ' / ' , pprun) for i in range(pprun-cur): self.next_pixel() time.sleep(0.10) self.FileCaptureOff() return ok, pprun-cur def readmca(self,n=1): "Read a Struck MCA" return self.get('mca%i' % n) def SCAMode(self): "put XMAP in SCA mapping mode" self.CollectMode = 2 def SpectraMode(self): "put XMAP in MCA spectra mode" self.stop() self.CollectMode = 0 self.PresetMode = 0 # wait until BufferSize is ready buffsize = -1 t0 = time.time() while time.time() - t0 < 5: self.CollectMode = 0 time.sleep(0.05) if self.BufferSize_RBV < 16384: break def MCAMode(self, filename=None, filenumber=None, npulses=11): "put XMAP in MCA mapping mode" self.AutoApply = 1 self.stop() self.PresetMode = 0 self.setFileWriteMode(2) if npulses < 2: npulses = 2 self.CollectMode = 1 self.PixelsPerRun = npulses # First, make sure ArraySize0_RBV for the netcdf plugin # is the correct value self.FileCaptureOff() self.start() f_size = -1 t0 = time.time() while (f_size < 16384) and time.time()-t0 < 10: for i in range(5): time.sleep(0.1) self.NextPixel = 1 f_size = self.fileGet('ArraySize0_RBV') if f_size > 16384: break # self.PixelsPerRun = npulses self.SyncCount = 1 self.setFileNumber(filenumber) if filename is not None: self.setFileName(filename) # wait until BufferSize is ready self.Apply = 1 self.CollectMode = 1 self.PixelsPerRun = npulses time.sleep(0.50) t0 = time.time() while time.time() - t0 < 10: time.sleep(0.25) if self.BufferSize_RBV > 16384: break # set expected number of buffers to put in a single file ppbuff = self.PixelsPerBuffer_RBV time.sleep(0.25) if ppbuff is None: ppbuff = 124 self.setFileNumCapture(1 + (npulses-1)/ppbuff) f_buffsize = -1 t0 = time.time() while time.time()- t0 < 5: time.sleep(0.1) f_buffsize = self.fileGet('ArraySize0_RBV') if self.BufferSize_RBV == f_buffsize: break time.sleep(0.5) return def filePut(self,attr, value, **kw): return self.put("%s%s" % (self.filesaver, attr), value, **kw) def fileGet(self, attr, **kw): return self.get("%s%s" % (self.filesaver, attr), **kw) def setFilePath(self, pathname): return self.filePut('FilePath', pathname) def setFileTemplate(self, fmt): return self.filePut('FileTemplate', fmt) def setFileWriteMode(self, mode): return self.filePut('FileWriteMode', mode) def setFileName(self, fname): return self.filePut('FileName', fname) def nextFileNumber(self): self.setFileNumber(1+self.fileGet('FileNumber')) def setFileNumber(self, fnum=None): if fnum is None: self.filePut('AutoIncrement', 1) else: self.filePut('AutoIncrement', 0) return self.filePut('FileNumber',fnum) def getLastFileName(self): return self.fileGet('FullFileName_RBV',as_string=True) def FileCaptureOn(self): return self.filePut('Capture', 1) def FileCaptureOff(self): return self.filePut('Capture', 0) def setFileNumCapture(self,n): return self.filePut('NumCapture', n) def FileWriteComplete(self): return (0==self.fileGet('WriteFile_RBV') ) def getFileTemplate(self): return self.fileGet('FileTemplate_RBV',as_string=True) def getFileName(self): return self.fileGet('FileName_RBV',as_string=True) def getFileNumber(self): return self.fileGet('FileNumber_RBV') def getFilePath(self): return self.fileGet('FilePath_RBV',as_string=True) def getFileNameByIndex(self,index): return self.getFileTemplate() % (self.getFilePath(), self.getFileName(), index)