schain Commit - r478:ecf5abfd8d13 · Jicamarca Repository

             '''
             $Author: murco $
             $Id: JROData.py 173 2012-11-20 15:06:21Z murco $
             '''
             import os, sys
             import copy
             import numpy
             import datetime
             import time
             from jroheaderIO import SystemHeader, RadarControllerHeader
             def hildebrand_sekhon(data, navg):
                 data = data.copy()
                 sortdata = numpy.sort(data,axis=None)
                 lenOfData = len(sortdata)
                 nums_min = lenOfData/10
                 if (lenOfData/10) > 2:
                     nums_min = lenOfData/10
                 else:
                     nums_min = 2
                 sump = 0.
                 sumq = 0.
                 j = 0
                 cont = 1
                 while((cont==1)and(j<lenOfData)):
                     sump += sortdata[j]
                     sumq += sortdata[j]**2
                     j += 1
                     if j > nums_min:
                         rtest = float(j)/(j-1) + 1.0/navg
                         if ((sumq*j) > (rtest*sump**2)):
                             j = j - 1
                             sump  = sump - sortdata[j]
                             sumq =  sumq - sortdata[j]**2
                             cont = 0
                 lnoise = sump /j
                 stdv = numpy.sqrt((sumq - lnoise**2)/(j - 1))
                 return lnoise
             class JROData:
             #    m_BasicHeader = BasicHeader()
             #    m_ProcessingHeader = ProcessingHeader()
                 systemHeaderObj = SystemHeader()
                 radarControllerHeaderObj = RadarControllerHeader()
             #    data = None
                 type = None
                 dtype = None
             #    nChannels = None
             #    nHeights = None
                 nProfiles = None
                 heightList = None
                 channelList = None
                 flagNoData = True
                 flagTimeBlock = False
                 useLocalTime = False
                 utctime = None
                 timeZone = None
                 dstFlag = None
                 errorCount = None
                 blocksize = None
                 nCode = None
                 nBaud = None
                 code = None
                 flagDecodeData = False #asumo q la data no esta decodificada
                 flagDeflipData = False #asumo q la data no esta sin flip
                 flagShiftFFT = False
                 ippSeconds = None
                 timeInterval = None
                 nCohInt = None
                 noise = None
                 windowOfFilter = 1
                 #Speed of ligth
                 C = 3e8
                 frequency = 49.92e6
                 realtime = False
                 beacon_heiIndexList = None
                 last_block = None
                 blocknow = None
                 def __init__(self):
                     raise ValueError, "This class has not been implemented"
                 def copy(self, inputObj=None):
                     if inputObj == None:
                         return copy.deepcopy(self)
                     for key in inputObj.__dict__.keys():
                         self.__dict__[key] = inputObj.__dict__[key]
                 def deepcopy(self):
                     return copy.deepcopy(self)
                 def isEmpty(self):
                     return self.flagNoData
                 def getNoise(self):
                     raise ValueError, "Not implemented"
                 def getNChannels(self):
                     return len(self.channelList)
                 def getChannelIndexList(self):
                     return range(self.nChannels)
                 def getNHeights(self):
                     return len(self.heightList)
                 def getHeiRange(self, extrapoints=0):
                     heis = self.heightList
             #        deltah = self.heightList[1] - self.heightList[0]
             #
             #        heis.append(self.heightList[-1])
                     return heis
                 def getltctime(self):
                     if self.useLocalTime:
                          return self.utctime - self.timeZone*60
                     return self.utctime
                 def getDatatime(self):
                     datatime = datetime.datetime.utcfromtimestamp(self.ltctime)
                     return datatime
                 def getTimeRange(self):
                     datatime = []
                     datatime.append(self.ltctime)
                     datatime.append(self.ltctime + self.timeInterval)
                     datatime = numpy.array(datatime)
                     return datatime
                 def getFmax(self):
                     PRF = 1./(self.ippSeconds * self.nCohInt)
                     fmax = PRF/2.
                     return fmax
                 def getVmax(self):
                     _lambda = self.C/self.frequency
                     vmax = self.getFmax() * _lambda
                     return vmax
                 nChannels = property(getNChannels, "I'm the 'nChannel' property.")
                 channelIndexList = property(getChannelIndexList, "I'm the 'channelIndexList' property.")
                 nHeights = property(getNHeights, "I'm the 'nHeights' property.")
                 noise = property(getNoise, "I'm the 'nHeights' property.")
                 datatime = property(getDatatime, "I'm the 'datatime' property")
                 ltctime = property(getltctime, "I'm the 'ltctime' property")
             class Voltage(JROData):
                 #data es un numpy array de 2 dmensiones (canales, alturas)
                 data = None
                 def __init__(self):
                     '''
                     Constructor
                     '''
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.systemHeaderObj = SystemHeader()
                     self.type = "Voltage"
                     self.data = None
                     self.dtype = None
             #        self.nChannels = 0
             #        self.nHeights = 0
                     self.nProfiles = None
                     self.heightList = None
                     self.channelList = None
             #        self.channelIndexList = None
                     self.flagNoData = True
                     self.flagTimeBlock = False
                     self.utctime = None
                     self.timeZone = None
                     self.dstFlag = None
                     self.errorCount = None
                     self.nCohInt = None
                     self.blocksize = None
                     self.flagDecodeData = False #asumo q la data no esta decodificada
                     self.flagDeflipData = False #asumo q la data no esta sin flip
                     self.flagShiftFFT = False
                 def getNoisebyHildebrand(self):
                     """
                     Determino el nivel de ruido usando el metodo Hildebrand-Sekhon
                     Return:
                         noiselevel
                     """
                     for channel in range(self.nChannels):
                         daux = self.data_spc[channel,:,:]
                         self.noise[channel] = hildebrand_sekhon(daux, self.nCohInt)
                     return self.noise
                 def getNoise(self, type = 1):
                     self.noise = numpy.zeros(self.nChannels)
                     if type == 1:
                         noise = self.getNoisebyHildebrand()
                     return 10*numpy.log10(noise)
             class Spectra(JROData):
                 #data es un numpy array de 2 dmensiones (canales, perfiles, alturas)
                 data_spc = None
                 #data es un numpy array de 2 dmensiones (canales, pares, alturas)
                 data_cspc = None
                 #data es un numpy array de 2 dmensiones (canales, alturas)
                 data_dc = None
                 nFFTPoints = None
                 nPairs = None
                 pairsList = None
                 nIncohInt = None
                 wavelength = None #Necesario para cacular el rango de velocidad desde la frecuencia
                 nCohInt = None #se requiere para determinar el valor de timeInterval
                 ippFactor = None
                 def __init__(self):
                     '''
                     Constructor
                     '''
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.systemHeaderObj = SystemHeader()
                     self.type = "Spectra"
             #        self.data = None
                     self.dtype = None
             #        self.nChannels = 0
             #        self.nHeights = 0
                     self.nProfiles = None
                     self.heightList = None
                     self.channelList = None
             #        self.channelIndexList = None
                     self.flagNoData = True
                     self.flagTimeBlock = False
                     self.utctime = None
                     self.nCohInt = None
                     self.nIncohInt = None
                     self.blocksize = None
                     self.nFFTPoints = None
                     self.wavelength = None
                     self.flagDecodeData = False #asumo q la data no esta decodificada
                     self.flagDeflipData = False #asumo q la data no esta sin flip
                     self.flagShiftFFT = False
                     self.ippFactor = 1
                     self.noise = None
                     self.beacon_heiIndexList = []
                 def getNoisebyHildebrand(self):
                     """
                     Determino el nivel de ruido usando el metodo Hildebrand-Sekhon
                     Return:
                         noiselevel
                     """
                     noise = numpy.zeros(self.nChannels)
                     for channel in range(self.nChannels):
                         daux = self.data_spc[channel,:,:]
                         noise[channel] = hildebrand_sekhon(daux, self.nIncohInt)
                     return noise
                 def getNoise(self):
                     if self.noise != None:
                         return self.noise
                     else:
                         noise = self.getNoisebyHildebrand()
                         return noise
                 def getFreqRange(self, extrapoints=0):
                     deltafreq = self.getFmax() / (self.nFFTPoints*self.ippFactor)
                     freqrange = deltafreq*(numpy.arange(self.nFFTPoints+extrapoints)-self.nFFTPoints/2.) - deltafreq/2
                     return freqrange
                 def getVelRange(self, extrapoints=0):
                     deltav = self.getVmax() / (self.nFFTPoints*self.ippFactor)
                     velrange = deltav*(numpy.arange(self.nFFTPoints+extrapoints)-self.nFFTPoints/2.) - deltav/2
                     return velrange
                 def getNPairs(self):
                     return len(self.pairsList)
                 def getPairsIndexList(self):
                     return range(self.nPairs)
                 def getNormFactor(self):
                     pwcode = 1
                     if self.flagDecodeData:
                         pwcode = numpy.sum(self.code[0]**2)
                     #normFactor = min(self.nFFTPoints,self.nProfiles)*self.nIncohInt*self.nCohInt*pwcode*self.windowOfFilter
                     normFactor = self.nProfiles*self.nIncohInt*self.nCohInt*pwcode*self.windowOfFilter
                     return normFactor
                 def getFlagCspc(self):
                     if self.data_cspc == None:
                         return True
                     return False
                 def getFlagDc(self):
                     if self.data_dc == None:
                         return True
                     return False
                 nPairs = property(getNPairs, "I'm the 'nPairs' property.")
                 pairsIndexList = property(getPairsIndexList, "I'm the 'pairsIndexList' property.")
                 normFactor = property(getNormFactor, "I'm the 'getNormFactor' property.")
                 flag_cspc = property(getFlagCspc)
                 flag_dc = property(getFlagDc)
             class SpectraHeis(JROData):
                 data_spc = None
                 data_cspc = None
                 data_dc = None
                 nFFTPoints = None
                 nPairs = None
                 pairsList = None
                 nIncohInt = None
                 def __init__(self):
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.systemHeaderObj = SystemHeader()
                     self.type = "SpectraHeis"
                     self.dtype = None
             #        self.nChannels = 0
             #        self.nHeights = 0
                     self.nProfiles = None
                     self.heightList = None
                     self.channelList = None
             #        self.channelIndexList = None
                     self.flagNoData = True
                     self.flagTimeBlock = False
                     self.nPairs = 0
                     self.utctime = None
                     self.blocksize = None
             class Fits:
                 heightList = None
                 channelList = None
                 flagNoData = True
                 flagTimeBlock = False
                 useLocalTime = False
                 utctime = None
                 timeZone = None
                 ippSeconds = None
                 timeInterval = None
                 nCohInt = None
                 nIncohInt = None
                 noise = None
                 windowOfFilter = 1
                 #Speed of ligth
                 C = 3e8
                 frequency = 49.92e6
                 realtime = False
                 def __init__(self):
                     self.type = "Fits"
                     self.nProfiles = None
                     self.heightList = None
                     self.channelList = None
             #         self.channelIndexList = None
                     self.flagNoData = True
                     self.utctime = None
                     self.nCohInt = None
                     self.nIncohInt = None
                     self.useLocalTime = True
             #         self.utctime = None
             #         self.timeZone = None
             #         self.ltctime = None
             #         self.timeInterval = None
             #         self.header = None
             #         self.data_header = None
             #         self.data = None
             #         self.datatime = None
             #         self.flagNoData = False
             #         self.expName = ''
             #         self.nChannels = None
             #         self.nSamples = None
             #         self.dataBlocksPerFile = None
             #         self.comments = ''
             #
                 def getltctime(self):
                     if self.useLocalTime:
                          return self.utctime - self.timeZone*60
                     return self.utctime
                 def getDatatime(self):
                     datatime = datetime.datetime.utcfromtimestamp(self.ltctime)
                     return datatime
                 def getTimeRange(self):
                     datatime = []
                     datatime.append(self.ltctime)
                     datatime.append(self.ltctime + self.timeInterval)
                     datatime = numpy.array(datatime)
                     return datatime
                 def getHeiRange(self):
                     heis = self.heightList
                     return heis
                 def isEmpty(self):
                     return self.flagNoData
                 def getNHeights(self):
                     return len(self.heightList)
                 def getNChannels(self):
                     return len(self.channelList)
                 def getChannelIndexList(self):
                     return range(self.nChannels)
                 def getNoise(self, type = 1):
                     self.noise = numpy.zeros(self.nChannels)
                     if type == 1:
                         noise = self.getNoisebyHildebrand()
                     if type == 2:
                         noise = self.getNoisebySort()
                     if type == 3:
                         noise = self.getNoisebyWindow()
                     return noise
                 datatime = property(getDatatime, "I'm the 'datatime' property")
                 nHeights = property(getNHeights, "I'm the 'nHeights' property.")
                 nChannels = property(getNChannels, "I'm the 'nChannel' property.")
                 channelIndexList = property(getChannelIndexList, "I'm the 'channelIndexList' property.")
                 noise = property(getNoise, "I'm the 'nHeights' property.")
                 datatime = property(getDatatime, "I'm the 'datatime' property")
                 ltctime = property(getltctime, "I'm the 'ltctime' property")
                 ltctime = property(getltctime, "I'm the 'ltctime' property")
             class AMISR:
                 def __init__(self):
                     self.flagNoData = True
                     self.data = None
                     self.utctime = None
                     self.type = "AMISR"
                     #propiedades para compatibilidad con Voltages
                     self.timeZone = 0#timezone like jroheader, difference in minutes between UTC and localtime
                     self.dstFlag = 0#self.dataIn.dstFlag
                     self.errorCount = 0#self.dataIn.errorCount
                     self.useLocalTime = True#self.dataIn.useLocalTime
                     self.radarControllerHeaderObj = None#self.dataIn.radarControllerHeaderObj.copy()
                     self.systemHeaderObj = None#self.dataIn.systemHeaderObj.copy()
                     self.channelList = [0]#self.dataIn.channelList esto solo aplica para el caso de AMISR
                     self.dtype = numpy.dtype([('real','<f4'),('imag','<f4')])
                     self.flagTimeBlock = None#self.dataIn.flagTimeBlock
                     #self.utctime = #self.firstdatatime
                     self.flagDecodeData = None#self.dataIn.flagDecodeData #asumo q la data esta decodificada
                     self.flagDeflipData = None#self.dataIn.flagDeflipData #asumo q la data esta sin flip
                     self.nCohInt = 1#self.dataIn.nCohInt
                     self.nIncohInt = 1
-                    self.ippSeconds = 0.004#self.dataIn.ippSeconds, segun el filename/Setup/Tufile
+                    self.ippSeconds = None#self.dataIn.ippSeconds, segun el filename/Setup/Tufile
                     self.windowOfFilter = None#self.dataIn.windowOfFilter
                     self.timeInterval = None#self.dataIn.timeInterval*self.dataOut.nFFTPoints*self.dataOut.nIncohInt
-                    self.frequency = 20000000#self.dataIn.frequency
+                    self.frequency = None#self.dataIn.frequency
                     self.realtime = 0#self.dataIn.realtime
                     #actualizar en la lectura de datos
                     self.heightList = None#self.dataIn.heightList
                     self.nProfiles = None#self.dataOut.nFFTPoints
                     self.nBaud = None#self.dataIn.nBaud
                     self.nCode = None#self.dataIn.nCode
                     self.code = None#self.dataIn.code
                     #consideracion para los Beams
                     self.beamCodeDict = None
                     self.beamRangeDict = None
                 def copy(self, inputObj=None):
                     if inputObj == None:
                         return copy.deepcopy(self)
                     for key in inputObj.__dict__.keys():
                         self.__dict__[key] = inputObj.__dict__[key]
                 def isEmpty(self):
                     return self.flagNoData

             '''
             $Author: murco $
             $Id: JRODataIO.py 169 2012-11-19 21:57:03Z murco $
             '''
             import os, sys
             import glob
             import time
             import numpy
             import fnmatch
             import time, datetime
             import h5py
+            import re
             from xml.etree.ElementTree import Element, SubElement, ElementTree
             try:
                 import pyfits
             except:
                 print "pyfits module has not been imported, it should be installed to save files in fits format"
             from jrodata import *
             from jroheaderIO import *
             from jroprocessing import *
             LOCALTIME = True #-18000
             def isNumber(str):
                 """
                 Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.
                 Excepciones:
                     Si un determinado string no puede ser convertido a numero
                 Input:
                     str, string al cual se le analiza para determinar si convertible a un numero o no
                 Return:
                     True    :    si el string es uno numerico
                     False   :    no es un string numerico
                 """
                 try:
                     float( str )
                     return True
                 except:
                     return False
             def isThisFileinRange(filename, startUTSeconds, endUTSeconds):
                 """
                 Esta funcion determina si un archivo de datos se encuentra o no dentro del rango de fecha especificado.
                 Inputs:
                     filename            :    nombre completo del archivo de datos en formato Jicamarca (.r)
                     startUTSeconds      :    fecha inicial del rango seleccionado. La fecha esta dada en
                                              segundos contados desde 01/01/1970.
                     endUTSeconds        :    fecha final del rango seleccionado. La fecha esta dada en
                                              segundos contados desde 01/01/1970.
                 Return:
                     Boolean    :    Retorna True si el archivo de datos contiene datos en el rango de
                                     fecha especificado, de lo contrario retorna False.
                 Excepciones:
                     Si el archivo no existe o no puede ser abierto
                     Si la cabecera no puede ser leida.
                 """
                 basicHeaderObj = BasicHeader(LOCALTIME)
                 try:
                     fp = open(filename,'rb')
                 except:
                     raise IOError, "The file %s can't be opened" %(filename)
                 sts = basicHeaderObj.read(fp)
                 fp.close()
                 if not(sts):
                     print "Skipping the file %s because it has not a valid header" %(filename)
                     return 0
                 if not ((startUTSeconds <= basicHeaderObj.utc) and (endUTSeconds > basicHeaderObj.utc)):
                     return 0
                 return 1
             def isFileinThisTime(filename, startTime, endTime):
                 """
                 Retorna 1 si el archivo de datos se encuentra dentro del rango de horas especificado.
                 Inputs:
                     filename            :    nombre completo del archivo de datos en formato Jicamarca (.r)
                     startTime          :    tiempo inicial del rango seleccionado en formato datetime.time
                     endTime            :    tiempo final del rango seleccionado en formato datetime.time
                 Return:
                     Boolean    :    Retorna True si el archivo de datos contiene datos en el rango de
                                     fecha especificado, de lo contrario retorna False.
                 Excepciones:
                     Si el archivo no existe o no puede ser abierto
                     Si la cabecera no puede ser leida.
                 """
                 try:
                     fp = open(filename,'rb')
                 except:
                     raise IOError, "The file %s can't be opened" %(filename)
                 basicHeaderObj = BasicHeader(LOCALTIME)
                 sts = basicHeaderObj.read(fp)
                 fp.close()
                 thisDatetime = basicHeaderObj.datatime
                 thisTime = basicHeaderObj.datatime.time()
                 if not(sts):
                     print "Skipping the file %s because it has not a valid header" %(filename)
                     return None
                 if not ((startTime <= thisTime) and (endTime > thisTime)):
                     return None
                 return thisDatetime
             def getFileFromSet(path,ext,set):
                 validFilelist = []
                 fileList = os.listdir(path)
                 # 0 1234 567 89A BCDE
                 # H YYYY DDD SSS .ext
                 for file in fileList:
                     try:
                         year = int(file[1:5])
                         doy  = int(file[5:8])
                     except:
                         continue
                     if (os.path.splitext(file)[-1].lower() != ext.lower()):
                         continue
                     validFilelist.append(file)
                 myfile = fnmatch.filter(validFilelist,'*%4.4d%3.3d%3.3d*'%(year,doy,set))
                 if len(myfile)!= 0:
                     return myfile[0]
                 else:
                     filename = '*%4.4d%3.3d%3.3d%s'%(year,doy,set,ext.lower())
                     print 'the filename %s does not exist'%filename
                     print '...going to the last file: '
                 if validFilelist:
                     validFilelist = sorted( validFilelist, key=str.lower )
                     return validFilelist[-1]
                 return None
             def getlastFileFromPath(path, ext):
                 """
                 Depura el fileList dejando solo los que cumplan el formato de "PYYYYDDDSSS.ext"
                 al final de la depuracion devuelve el ultimo file de la lista que quedo.
                 Input:
                     fileList    :    lista conteniendo todos los files (sin path) que componen una determinada carpeta
                     ext         :    extension de los files contenidos en una carpeta
                 Return:
                     El ultimo file de una determinada carpeta, no se considera el path.
                 """
                 validFilelist = []
                 fileList = os.listdir(path)
                 # 0 1234 567 89A BCDE
                 # H YYYY DDD SSS .ext
                 for file in fileList:
                     try:
                         year = int(file[1:5])
                         doy  = int(file[5:8])
                     except:
                         continue
                     if (os.path.splitext(file)[-1].lower() != ext.lower()):
                         continue
                     validFilelist.append(file)
                 if validFilelist:
                     validFilelist = sorted( validFilelist, key=str.lower )
                     return validFilelist[-1]
                 return None
             def checkForRealPath(path, foldercounter, year, doy, set, ext):
                 """
                 Por ser Linux Case Sensitive entonces checkForRealPath encuentra el nombre correcto de un path,
                 Prueba por varias combinaciones de nombres entre mayusculas y minusculas para determinar
                 el path exacto de un determinado file.
                 Example    :
                     nombre correcto del file es  .../.../D2009307/P2009307367.ext
                     Entonces la funcion prueba con las siguientes combinaciones
                         .../.../y2009307367.ext
                         .../.../Y2009307367.ext
                         .../.../x2009307/y2009307367.ext
                         .../.../x2009307/Y2009307367.ext
                         .../.../X2009307/y2009307367.ext
                         .../.../X2009307/Y2009307367.ext
                     siendo para este caso, la ultima combinacion de letras, identica al file buscado
                 Return:
                     Si encuentra la cobinacion adecuada devuelve el path completo y el nombre del file
                     caso contrario devuelve None como path y el la ultima combinacion de nombre en mayusculas
                     para el filename
                 """
                 fullfilename = None
                 find_flag = False
                 filename = None
                 prefixDirList = [None,'d','D']
                 if ext.lower() == ".r": #voltage
                     prefixFileList = ['d','D']
                 elif ext.lower() == ".pdata": #spectra
                     prefixFileList = ['p','P']
                 else:
                     return None, filename
                 #barrido por las combinaciones posibles
                 for prefixDir in prefixDirList:
                     thispath = path
                     if prefixDir != None:
                         #formo el nombre del directorio xYYYYDDD (x=d o x=D)
                         if foldercounter == 0:
                             thispath = os.path.join(path, "%s%04d%03d" % ( prefixDir, year, doy ))
                         else:
                             thispath = os.path.join(path, "%s%04d%03d_%02d" % ( prefixDir, year, doy , foldercounter))
                     for prefixFile in prefixFileList: #barrido por las dos combinaciones posibles de "D"
                         filename = "%s%04d%03d%03d%s" % ( prefixFile, year, doy, set, ext ) #formo el nombre del file xYYYYDDDSSS.ext
                         fullfilename = os.path.join( thispath, filename ) #formo el path completo
                         if os.path.exists( fullfilename ): #verifico que exista
                             find_flag = True
                             break
                     if find_flag:
                         break
                 if not(find_flag):
                     return None, filename
                 return fullfilename, filename
             def isDoyFolder(folder):
                 try:
                     year = int(folder[1:5])
                 except:
                     return 0
                 try:
                     doy = int(folder[5:8])
                 except:
                     return 0
                 return 1
             class JRODataIO:
                 c = 3E8
                 isConfig = False
                 basicHeaderObj = BasicHeader(LOCALTIME)
                 systemHeaderObj = SystemHeader()
                 radarControllerHeaderObj = RadarControllerHeader()
                 processingHeaderObj = ProcessingHeader()
                 online = 0
                 dtype = None
                 pathList = []
                 filenameList = []
                 filename = None
                 ext = None
                 flagIsNewFile = 1
                 flagTimeBlock = 0
                 flagIsNewBlock = 0
                 fp = None
                 firstHeaderSize = 0
                 basicHeaderSize = 24
                 versionFile = 1103
                 fileSize = None
                 ippSeconds = None
                 fileSizeByHeader = None
                 fileIndex = None
                 profileIndex = None
                 blockIndex = None
                 nTotalBlocks = None
                 maxTimeStep = 30
                 lastUTTime = None
                 datablock = None
                 dataOut = None
                 blocksize = None
                 def __init__(self):
                     raise ValueError, "Not implemented"
                 def run(self):
                     raise ValueError, "Not implemented"
                 def getOutput(self):
                     return self.dataOut
             class JRODataReader(JRODataIO, ProcessingUnit):
                 nReadBlocks = 0
                 delay  = 10   #number of seconds waiting a new file
                 nTries  = 3  #quantity tries
                 nFiles = 3   #number of files for searching
                 path = None
                 foldercounter = 0
                 flagNoMoreFiles = 0
                 datetimeList = []
                 __isFirstTimeOnline = 1
                 __printInfo = True
                 profileIndex = None
                 def __init__(self):
                     """
                     """
                     raise ValueError, "This method has not been implemented"
                 def createObjByDefault(self):
                     """
                     """
                     raise ValueError, "This method has not been implemented"
                 def getBlockDimension(self):
                     raise ValueError, "No implemented"
                 def __searchFilesOffLine(self,
                                         path,
                                         startDate,
                                         endDate,
                                         startTime=datetime.time(0,0,0),
                                         endTime=datetime.time(23,59,59),
                                         set=None,
                                         expLabel='',
                                         ext='.r',
                                         walk=True):
                     pathList = []
                     if not walk:
                         #pathList.append(path)
                         multi_path = path.split(',')
                         for single_path in multi_path:
                             pathList.append(single_path)
                     else:
                         #dirList = []
                         multi_path = path.split(',')
                         for single_path in multi_path:
                             dirList = []
                             for thisPath in os.listdir(single_path):
                                 if not os.path.isdir(os.path.join(single_path,thisPath)):
                                     continue
                                 if not isDoyFolder(thisPath):
                                     continue
                                 dirList.append(thisPath)
                             if not(dirList):
                                 return None, None
                             thisDate = startDate
                             while(thisDate <= endDate):
                                 year = thisDate.timetuple().tm_year
                                 doy = thisDate.timetuple().tm_yday
                                 matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')
                                 if len(matchlist) == 0:
                                     thisDate += datetime.timedelta(1)
                                     continue
                                 for match in matchlist:
                                     pathList.append(os.path.join(single_path,match,expLabel))
                                 thisDate += datetime.timedelta(1)
                     if pathList == []:
                         print "Any folder was found for the date range: %s-%s" %(startDate, endDate)
                         return None, None
                     print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)
                     filenameList = []
                     datetimeList = []
                     pathDict = {}
                     filenameList_to_sort = []
                     for i in range(len(pathList)):
                         thisPath = pathList[i]
                         fileList = glob.glob1(thisPath, "*%s" %ext)
                         fileList.sort()
                         pathDict.setdefault(fileList[0])
                         pathDict[fileList[0]] = i
                         filenameList_to_sort.append(fileList[0])
                     filenameList_to_sort.sort()
                     for file in filenameList_to_sort:
                         thisPath = pathList[pathDict[file]]
                         fileList = glob.glob1(thisPath, "*%s" %ext)
                         fileList.sort()
                         for file in fileList:
                             filename = os.path.join(thisPath,file)
                             thisDatetime = isFileinThisTime(filename, startTime, endTime)
                             if not(thisDatetime):
                                 continue
                             filenameList.append(filename)
                             datetimeList.append(thisDatetime)
                     if not(filenameList):
                         print "Any file was found for the time range %s - %s" %(startTime, endTime)
                         return None, None
                     print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)
                     print
                     for i in range(len(filenameList)):
                         print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())
                     self.filenameList = filenameList
                     self.datetimeList = datetimeList
                     return pathList, filenameList
                 def __searchFilesOnLine(self, path, expLabel = "", ext = None, walk=True, set=None):
                     """
                     Busca el ultimo archivo de la ultima carpeta (determinada o no por startDateTime) y
                     devuelve el archivo encontrado ademas de otros datos.
                     Input:
                         path           :    carpeta donde estan contenidos los files que contiene data
                         expLabel        :     Nombre del subexperimento (subfolder)
                         ext              :    extension de los files
                         walk        :    Si es habilitado no realiza busquedas dentro de los ubdirectorios (doypath)
                     Return:
                         directory   :    eL directorio donde esta el file encontrado
                         filename    :    el ultimo file de una determinada carpeta
                         year        :    el anho
                         doy         :    el numero de dia del anho
                         set         :    el set del archivo
                     """
                     dirList = []
                     if not walk:
                         fullpath = path
                         foldercounter = 0
                     else:
                         #Filtra solo los directorios
                         for thisPath in os.listdir(path):
                             if not os.path.isdir(os.path.join(path,thisPath)):
                                 continue
                             if not isDoyFolder(thisPath):
                                 continue
                             dirList.append(thisPath)
                         if not(dirList):
                             return None, None, None, None, None, None
                         dirList = sorted( dirList, key=str.lower )
                         doypath = dirList[-1]
                         foldercounter = int(doypath.split('_')[1]) if len(doypath.split('_'))>1 else 0
                         fullpath = os.path.join(path, doypath, expLabel)
                     print "%s folder was found: " %(fullpath )
                     if set == None:
                         filename = getlastFileFromPath(fullpath, ext)
                     else:
                         filename = getFileFromSet(fullpath, ext, set)
                     if not(filename):
                         return None, None, None, None, None, None
                     print "%s file was found" %(filename)
                     if not(self.__verifyFile(os.path.join(fullpath, filename))):
                         return None, None, None, None, None, None
                     year = int( filename[1:5] )
                     doy  = int( filename[5:8] )
                     set  = int( filename[8:11] )
                     return fullpath, foldercounter, filename, year, doy, set
                 def __setNextFileOffline(self):
                     idFile = self.fileIndex
                     while (True):
                         idFile += 1
                         if not(idFile < len(self.filenameList)):
                             self.flagNoMoreFiles = 1
                             print "No more Files"
                             return 0
                         filename = self.filenameList[idFile]
                         if not(self.__verifyFile(filename)):
                             continue
                         fileSize = os.path.getsize(filename)
                         fp = open(filename,'rb')
                         break
                     self.flagIsNewFile = 1
                     self.fileIndex = idFile
                     self.filename = filename
                     self.fileSize = fileSize
                     self.fp = fp
                     print "Setting the file: %s"%self.filename
                     return 1
                 def __setNextFileOnline(self):
                     """
                     Busca el siguiente file que tenga suficiente data para ser leida, dentro de un folder especifico, si
                     no encuentra un file valido espera un tiempo determinado y luego busca en los posibles n files
                     siguientes.
                     Affected:
                         self.flagIsNewFile
                         self.filename
                         self.fileSize
                         self.fp
                         self.set
                         self.flagNoMoreFiles
                     Return:
 : si luego de una busqueda del siguiente file valido este no pudo ser encontrado
 : si el file fue abierto con exito y esta listo a ser leido
                     Excepciones:
                         Si un determinado file no puede ser abierto
                     """
                     nFiles = 0
                     fileOk_flag = False
                     firstTime_flag = True
                     self.set += 1
                     if self.set > 999:
                         self.set = 0
                         self.foldercounter += 1
                     #busca el 1er file disponible
                     fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )
                     if fullfilename:
                         if self.__verifyFile(fullfilename, False):
                             fileOk_flag = True
                     #si no encuentra un file entonces espera y vuelve a buscar
                     if not(fileOk_flag):
                         for nFiles in range(self.nFiles+1): #busco en los siguientes self.nFiles+1 files posibles
                             if firstTime_flag: #si es la 1era vez entonces hace el for self.nTries veces
                                 tries = self.nTries
                             else:
                                 tries = 1 #si no es la 1era vez entonces solo lo hace una vez
                             for nTries in range( tries ):
                                 if firstTime_flag:
                                     print "\tWaiting %0.2f sec for the file \"%s\" , try %03d ..." % ( self.delay, filename, nTries+1 )
                                     time.sleep( self.delay )
                                 else:
                                     print "\tSearching next \"%s%04d%03d%03d%s\" file ..." % (self.optchar, self.year, self.doy, self.set, self.ext)
                                 fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )
                                 if fullfilename:
                                     if self.__verifyFile(fullfilename):
                                         fileOk_flag = True
                                         break
                             if fileOk_flag:
                                 break
                             firstTime_flag = False
                             print "\tSkipping the file \"%s\" due to this file doesn't exist" % filename
                             self.set += 1
                             if nFiles == (self.nFiles-1): #si no encuentro el file buscado cambio de carpeta y busco en la siguiente carpeta
                                 self.set = 0
                                 self.doy += 1
                                 self.foldercounter = 0
                     if fileOk_flag:
                         self.fileSize = os.path.getsize( fullfilename )
                         self.filename = fullfilename
                         self.flagIsNewFile = 1
                         if self.fp != None: self.fp.close()
                         self.fp = open(fullfilename, 'rb')
                         self.flagNoMoreFiles = 0
                         print 'Setting the file: %s' % fullfilename
                     else:
                         self.fileSize = 0
                         self.filename = None
                         self.flagIsNewFile = 0
                         self.fp = None
                         self.flagNoMoreFiles = 1
                         print 'No more Files'
                     return fileOk_flag
                 def setNextFile(self):
                     if self.fp != None:
                         self.fp.close()
                     if self.online:
                         newFile = self.__setNextFileOnline()
                     else:
                         newFile = self.__setNextFileOffline()
                     if not(newFile):
                         return 0
                     self.__readFirstHeader()
                     self.nReadBlocks = 0
                     return 1
                 def __waitNewBlock(self):
                     """
                     Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.
                     Si el modo de lectura es OffLine siempre retorn 0
                     """
                     if not self.online:
                         return 0
                     if (self.nReadBlocks >= self.processingHeaderObj.dataBlocksPerFile):
                         return 0
                     currentPointer = self.fp.tell()
                     neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize
                     for nTries in range( self.nTries ):
                         self.fp.close()
                         self.fp = open( self.filename, 'rb' )
                         self.fp.seek( currentPointer )
                         self.fileSize = os.path.getsize( self.filename )
                         currentSize = self.fileSize - currentPointer
                         if ( currentSize >= neededSize ):
                             self.__rdBasicHeader()
                             return 1
                         if self.fileSize == self.fileSizeByHeader:
             #                self.flagEoF = True
                             return 0
                         print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)
                         time.sleep( self.delay )
                     return 0
                 def waitDataBlock(self,pointer_location):
                     currentPointer = pointer_location
                     neededSize = self.processingHeaderObj.blockSize #+ self.basicHeaderSize
                     for nTries in range( self.nTries ):
                         self.fp.close()
                         self.fp = open( self.filename, 'rb' )
                         self.fp.seek( currentPointer )
                         self.fileSize = os.path.getsize( self.filename )
                         currentSize = self.fileSize - currentPointer
                         if ( currentSize >= neededSize ):
                             return 1
                         print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)
                         time.sleep( self.delay )
                     return 0
                 def __jumpToLastBlock(self):
                     if not(self.__isFirstTimeOnline):
                         return
                     csize = self.fileSize - self.fp.tell()
                     blocksize = self.processingHeaderObj.blockSize
                     #salta el primer bloque de datos
                     if csize > self.processingHeaderObj.blockSize:
                         self.fp.seek(self.fp.tell() + blocksize)
                     else:
                         return
                     csize = self.fileSize - self.fp.tell()
                     neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize
                     while True:
                         if self.fp.tell()<self.fileSize:
                             self.fp.seek(self.fp.tell() + neededsize)
                         else:
                             self.fp.seek(self.fp.tell() - neededsize)
                             break
             #        csize = self.fileSize - self.fp.tell()
             #        neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize
             #        factor = int(csize/neededsize)
             #        if factor > 0:
             #            self.fp.seek(self.fp.tell() + factor*neededsize)
                     self.flagIsNewFile = 0
                     self.__isFirstTimeOnline = 0
                 def __setNewBlock(self):
                     if self.fp == None:
                         return 0
                     if self.online:
                         self.__jumpToLastBlock()
                     if self.flagIsNewFile:
                         return 1
                     self.lastUTTime = self.basicHeaderObj.utc
                     currentSize = self.fileSize - self.fp.tell()
                     neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize
                     if (currentSize >= neededSize):
                         self.__rdBasicHeader()
                         return 1
                     if self.__waitNewBlock():
                         return 1
                     if not(self.setNextFile()):
                         return 0
                     deltaTime = self.basicHeaderObj.utc - self.lastUTTime #
                     self.flagTimeBlock = 0
                     if deltaTime > self.maxTimeStep:
                         self.flagTimeBlock = 1
                     return 1
                 def readNextBlock(self):
                     if not(self.__setNewBlock()):
                         return 0
                     if not(self.readBlock()):
                         return 0
                     return 1
                 def __rdProcessingHeader(self, fp=None):
                     if fp == None:
                         fp = self.fp
                     self.processingHeaderObj.read(fp)
                 def __rdRadarControllerHeader(self, fp=None):
                     if fp == None:
                         fp = self.fp
                     self.radarControllerHeaderObj.read(fp)
                 def __rdSystemHeader(self, fp=None):
                     if fp == None:
                         fp = self.fp
                     self.systemHeaderObj.read(fp)
                 def __rdBasicHeader(self, fp=None):
                     if fp == None:
                         fp = self.fp
                     self.basicHeaderObj.read(fp)
                 def __readFirstHeader(self):
                     self.__rdBasicHeader()
                     self.__rdSystemHeader()
                     self.__rdRadarControllerHeader()
                     self.__rdProcessingHeader()
                     self.firstHeaderSize = self.basicHeaderObj.size
                     datatype = int(numpy.log2((self.processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))
                     if datatype == 0:
                         datatype_str = numpy.dtype([('real','<i1'),('imag','<i1')])
                     elif datatype == 1:
                         datatype_str = numpy.dtype([('real','<i2'),('imag','<i2')])
                     elif datatype == 2:
                         datatype_str = numpy.dtype([('real','<i4'),('imag','<i4')])
                     elif datatype == 3:
                         datatype_str = numpy.dtype([('real','<i8'),('imag','<i8')])
                     elif datatype == 4:
                         datatype_str = numpy.dtype([('real','<f4'),('imag','<f4')])
                     elif datatype == 5:
                         datatype_str = numpy.dtype([('real','<f8'),('imag','<f8')])
                     else:
                         raise ValueError, 'Data type was not defined'
                     self.dtype = datatype_str
                     self.ippSeconds = 2 * 1000 * self.radarControllerHeaderObj.ipp / self.c
                     self.fileSizeByHeader = self.processingHeaderObj.dataBlocksPerFile * self.processingHeaderObj.blockSize + self.firstHeaderSize + self.basicHeaderSize*(self.processingHeaderObj.dataBlocksPerFile - 1)
             #        self.dataOut.channelList = numpy.arange(self.systemHeaderObj.numChannels)
             #        self.dataOut.channelIndexList = numpy.arange(self.systemHeaderObj.numChannels)
                     self.getBlockDimension()
                 def __verifyFile(self, filename, msgFlag=True):
                     msg = None
                     try:
                         fp = open(filename, 'rb')
                         currentPosition = fp.tell()
                     except:
                         if msgFlag:
                             print "The file %s can't be opened" % (filename)
                         return False
                     neededSize = self.processingHeaderObj.blockSize + self.firstHeaderSize
                     if neededSize == 0:
                         basicHeaderObj = BasicHeader(LOCALTIME)
                         systemHeaderObj = SystemHeader()
                         radarControllerHeaderObj = RadarControllerHeader()
                         processingHeaderObj = ProcessingHeader()
                         try:
                             if not( basicHeaderObj.read(fp) ): raise IOError
                             if not( systemHeaderObj.read(fp) ): raise IOError
                             if not( radarControllerHeaderObj.read(fp) ): raise IOError
                             if not( processingHeaderObj.read(fp) ): raise IOError
                             data_type = int(numpy.log2((processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))
                             neededSize = processingHeaderObj.blockSize + basicHeaderObj.size
                         except:
                             if msgFlag:
                                 print "\tThe file %s is empty or it hasn't enough data" % filename
                             fp.close()
                             return False
                     else:
                         msg = "\tSkipping the file %s due to it hasn't enough data" %filename
                     fp.close()
                     fileSize = os.path.getsize(filename)
                     currentSize = fileSize - currentPosition
                     if currentSize < neededSize:
                         if msgFlag and (msg != None):
                             print msg #print"\tSkipping the file %s due to it hasn't enough data" %filename
                         return False
                     return True
                 def setup(self,
                             path=None,
                             startDate=None,
                             endDate=None,
                             startTime=datetime.time(0,0,0),
                             endTime=datetime.time(23,59,59),
                             set=None,
                             expLabel = "",
                             ext = None,
                             online = False,
                             delay = 60,
                             walk = True):
                     if path == None:
                         raise ValueError, "The path is not valid"
                     if ext == None:
                         ext = self.ext
                     if online:
                         print "Searching files in online mode..."
                         for nTries in range( self.nTries ):
                             fullpath, foldercounter, file, year, doy, set = self.__searchFilesOnLine(path=path, expLabel=expLabel, ext=ext, walk=walk, set=set)
                             if fullpath:
                                 break
                             print '\tWaiting %0.2f sec for an valid file in %s: try %02d ...' % (self.delay, path, nTries+1)
                             time.sleep( self.delay )
                         if not(fullpath):
                             print "There 'isn't valied files in %s" % path
                             return None
                         self.year = year
                         self.doy  = doy
                         self.set  = set - 1
                         self.path = path
                         self.foldercounter = foldercounter
                         last_set = None
                     else:
                         print "Searching files in offline mode ..."
                         pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,
                                                                            startTime=startTime, endTime=endTime,
                                                                            set=set, expLabel=expLabel, ext=ext,
                                                                            walk=walk)
                         if not(pathList):
                             print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,
                                                                     datetime.datetime.combine(startDate,startTime).ctime(),
                                                                     datetime.datetime.combine(endDate,endTime).ctime())
                             sys.exit(-1)
                         self.fileIndex = -1
                         self.pathList = pathList
                         self.filenameList = filenameList
                         file_name = os.path.basename(filenameList[-1])
                         basename, ext = os.path.splitext(file_name)
                         last_set = int(basename[-3:])
                     self.online = online
                     self.delay = delay
                     ext = ext.lower()
                     self.ext = ext
                     if not(self.setNextFile()):
                         if (startDate!=None) and (endDate!=None):
                             print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())
                         elif startDate != None:
                             print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())
                         else:
                             print "No files"
                         sys.exit(-1)
             #        self.updateDataHeader()
                     if last_set != None:
                         self.dataOut.last_block = last_set * self.processingHeaderObj.dataBlocksPerFile + self.basicHeaderObj.dataBlock
                     return self.dataOut
                 def getBasicHeader(self):
                     self.dataOut.utctime = self.basicHeaderObj.utc + self.basicHeaderObj.miliSecond/1000. + self.profileIndex * self.ippSeconds
                     self.dataOut.flagTimeBlock = self.flagTimeBlock
                     self.dataOut.timeZone = self.basicHeaderObj.timeZone
                     self.dataOut.dstFlag = self.basicHeaderObj.dstFlag
                     self.dataOut.errorCount = self.basicHeaderObj.errorCount
                     self.dataOut.useLocalTime = self.basicHeaderObj.useLocalTime
                 def getFirstHeader(self):
                     raise ValueError, "This method has not been implemented"
                 def getData():
                     raise ValueError, "This method has not been implemented"
                 def hasNotDataInBuffer():
                     raise ValueError, "This method has not been implemented"
                 def readBlock():
                     raise ValueError, "This method has not been implemented"
                 def isEndProcess(self):
                     return self.flagNoMoreFiles
                 def printReadBlocks(self):
                     print "Number of read blocks per file %04d" %self.nReadBlocks
                 def printTotalBlocks(self):
                     print "Number of read blocks %04d" %self.nTotalBlocks
                 def printNumberOfBlock(self):
                     if self.flagIsNewBlock:
                         print "Block No. %04d, Total blocks %04d -> %s" %(self.basicHeaderObj.dataBlock, self.nTotalBlocks, self.dataOut.datatime.ctime())
                         self.dataOut.blocknow = self.basicHeaderObj.dataBlock
                 def printInfo(self):
                     if self.__printInfo == False:
                         return
                     self.basicHeaderObj.printInfo()
                     self.systemHeaderObj.printInfo()
                     self.radarControllerHeaderObj.printInfo()
                     self.processingHeaderObj.printInfo()
                     self.__printInfo = False
                 def run(self, **kwargs):
                     if not(self.isConfig):
             #            self.dataOut = dataOut
                         self.setup(**kwargs)
                         self.isConfig = True
                     self.getData()
             class JRODataWriter(JRODataIO, Operation):
                 """
                 Esta clase permite escribir datos a archivos procesados (.r o ,pdata). La escritura
                 de los datos siempre se realiza por bloques.
                 """
                 blockIndex = 0
                 path = None
                 setFile = None
                 profilesPerBlock = None
                 blocksPerFile = None
                 nWriteBlocks = 0
                 def __init__(self, dataOut=None):
                     raise ValueError, "Not implemented"
                 def hasAllDataInBuffer(self):
                     raise ValueError, "Not implemented"
                 def setBlockDimension(self):
                     raise ValueError, "Not implemented"
                 def writeBlock(self):
                     raise ValueError, "No implemented"
                 def putData(self):
                     raise ValueError, "No implemented"
                 def setBasicHeader(self):
                     self.basicHeaderObj.size = self.basicHeaderSize #bytes
                     self.basicHeaderObj.version = self.versionFile
                     self.basicHeaderObj.dataBlock = self.nTotalBlocks
                     utc = numpy.floor(self.dataOut.utctime)
                     milisecond  = (self.dataOut.utctime - utc)* 1000.0
                     self.basicHeaderObj.utc = utc
                     self.basicHeaderObj.miliSecond = milisecond
                     self.basicHeaderObj.timeZone = self.dataOut.timeZone
                     self.basicHeaderObj.dstFlag = self.dataOut.dstFlag
                     self.basicHeaderObj.errorCount = self.dataOut.errorCount
                 def setFirstHeader(self):
                     """
                     Obtiene una copia del First Header
                     Affected:
                         self.basicHeaderObj
                         self.systemHeaderObj
                         self.radarControllerHeaderObj
                         self.processingHeaderObj self.
                     Return:
                         None
                     """
                     raise ValueError, "No implemented"
                 def __writeFirstHeader(self):
                     """
                     Escribe el primer header del file es decir el Basic header y el Long header (SystemHeader, RadarControllerHeader, ProcessingHeader)
                     Affected:
                         __dataType
                     Return:
                         None
                     """
             #        CALCULAR PARAMETROS
                     sizeLongHeader = self.systemHeaderObj.size + self.radarControllerHeaderObj.size + self.processingHeaderObj.size
                     self.basicHeaderObj.size = self.basicHeaderSize + sizeLongHeader
                     self.basicHeaderObj.write(self.fp)
                     self.systemHeaderObj.write(self.fp)
                     self.radarControllerHeaderObj.write(self.fp)
                     self.processingHeaderObj.write(self.fp)
                     self.dtype = self.dataOut.dtype
                 def __setNewBlock(self):
                     """
                     Si es un nuevo file escribe el First Header caso contrario escribe solo el Basic Header
                     Return:
 :    si no pudo escribir nada
 :    Si escribio el Basic el First Header
                     """
                     if self.fp == None:
                         self.setNextFile()
                     if self.flagIsNewFile:
                         return 1
                     if self.blockIndex < self.processingHeaderObj.dataBlocksPerFile:
                         self.basicHeaderObj.write(self.fp)
                         return 1
                     if not( self.setNextFile() ):
                         return 0
                     return 1
                 def writeNextBlock(self):
                     """
                     Selecciona el bloque siguiente de datos y los escribe en un file
                     Return:
 :    Si no hizo pudo escribir el bloque de datos
 :    Si no pudo escribir el bloque de datos
                     """
                     if not( self.__setNewBlock() ):
                         return 0
                     self.writeBlock()
                     return 1
                 def setNextFile(self):
                     """
                     Determina el siguiente file que sera escrito
                     Affected:
                         self.filename
                         self.subfolder
                         self.fp
                         self.setFile
                         self.flagIsNewFile
                     Return:
 :    Si el archivo no puede ser escrito
 :    Si el archivo esta listo para ser escrito
                     """
                     ext = self.ext
                     path = self.path
                     if self.fp != None:
                         self.fp.close()
                     timeTuple = time.localtime( self.dataOut.utctime)
                     subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)
                     fullpath = os.path.join( path, subfolder )
                     if not( os.path.exists(fullpath) ):
                         os.mkdir(fullpath)
                         self.setFile = -1 #inicializo mi contador de seteo
                     else:
                         filesList = os.listdir( fullpath )
                         if len( filesList ) > 0:
                             filesList = sorted( filesList, key=str.lower )
                             filen = filesList[-1]
                             # el filename debera tener el siguiente formato
                             # 0 1234 567 89A BCDE (hex)
                             # x YYYY DDD SSS .ext
                             if isNumber( filen[8:11] ):
                                 self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file
                             else:
                                 self.setFile = -1
                         else:
                             self.setFile = -1 #inicializo mi contador de seteo
                     setFile = self.setFile
                     setFile += 1
                     file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,
                                                     timeTuple.tm_year,
                                                     timeTuple.tm_yday,
                                                     setFile,
                                                     ext )
                     filename = os.path.join( path, subfolder, file )
                     fp = open( filename,'wb' )
                     self.blockIndex = 0
                     #guardando atributos
                     self.filename = filename
                     self.subfolder = subfolder
                     self.fp = fp
                     self.setFile = setFile
                     self.flagIsNewFile = 1
                     self.setFirstHeader()
                     print 'Writing the file: %s'%self.filename
                     self.__writeFirstHeader()
                     return 1
                 def setup(self, dataOut, path, blocksPerFile, profilesPerBlock=64, set=0, ext=None):
                     """
                     Setea el tipo de formato en la cual sera guardada la data y escribe el First Header
                     Inputs:
                         path      :    el path destino en el cual se escribiran los files a crear
                         format    :    formato en el cual sera salvado un file
                         set       :    el setebo del file
                     Return:
 :    Si no realizo un buen seteo
 :    Si realizo un buen seteo
                     """
                     if ext == None:
                         ext = self.ext
                     ext = ext.lower()
                     self.ext = ext
                     self.path = path
                     self.setFile = set - 1
                     self.blocksPerFile = blocksPerFile
                     self.profilesPerBlock = profilesPerBlock
                     self.dataOut = dataOut
                     if not(self.setNextFile()):
                         print "There isn't a next file"
                         return 0
                     self.setBlockDimension()
                     return 1
                 def run(self, dataOut, **kwargs):
                     if not(self.isConfig):
                         self.setup(dataOut, **kwargs)
                         self.isConfig = True
                     self.putData()
             class VoltageReader(JRODataReader):
                 """
                 Esta clase permite leer datos de voltage desde archivos en formato rawdata (.r). La lectura
                 de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones:
                 perfiles*alturas*canales) son almacenados en la variable "buffer".
                                          perfiles * alturas * canales
                 Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,
                 RadarControllerHeader y Voltage. Los tres primeros se usan para almacenar informacion de la
                 cabecera de datos (metadata), y el cuarto (Voltage) para obtener y almacenar un perfil de
                 datos desde el "buffer" cada vez que se ejecute el metodo "getData".
                 Example:
                     dpath = "/home/myuser/data"
                     startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)
                     endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)
                     readerObj = VoltageReader()
                     readerObj.setup(dpath, startTime, endTime)
                     while(True):
                         #to get one profile
                         profile =  readerObj.getData()
                         #print the profile
                         print profile
                         #If you want to see all datablock
                         print readerObj.datablock
                         if readerObj.flagNoMoreFiles:
                             break
                 """
                 ext = ".r"
                 optchar = "D"
                 dataOut = None
                 def __init__(self):
                     """
                     Inicializador de la clase VoltageReader para la lectura de datos de voltage.
                     Input:
                         dataOut    :    Objeto de la clase Voltage. Este objeto sera utilizado para
                                           almacenar un perfil de datos cada vez que se haga un requerimiento
                                           (getData). El perfil sera obtenido a partir del buffer de datos,
                                           si el buffer esta vacio se hara un nuevo proceso de lectura de un
                                           bloque de datos.
                                           Si este parametro no es pasado se creara uno internamente.
                     Variables afectadas:
                         self.dataOut
                     Return:
                         None
                     """
                     self.isConfig = False
                     self.datablock = None
                     self.utc = 0
                     self.ext = ".r"
                     self.optchar = "D"
                     self.basicHeaderObj = BasicHeader(LOCALTIME)
                     self.systemHeaderObj = SystemHeader()
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.processingHeaderObj = ProcessingHeader()
                     self.online = 0
                     self.fp = None
                     self.idFile = None
                     self.dtype = None
                     self.fileSizeByHeader = None
                     self.filenameList = []
                     self.filename = None
                     self.fileSize = None
                     self.firstHeaderSize = 0
                     self.basicHeaderSize = 24
                     self.pathList = []
                     self.filenameList = []
                     self.lastUTTime = 0
                     self.maxTimeStep = 30
                     self.flagNoMoreFiles = 0
                     self.set = 0
                     self.path = None
                     self.profileIndex = 2**32-1
                     self.delay  = 3   #seconds
                     self.nTries  = 3  #quantity tries
                     self.nFiles = 3   #number of files for searching
                     self.nReadBlocks = 0
                     self.flagIsNewFile = 1
                     self.__isFirstTimeOnline = 1
                     self.ippSeconds = 0
                     self.flagTimeBlock = 0
                     self.flagIsNewBlock = 0
                     self.nTotalBlocks = 0
                     self.blocksize = 0
                     self.dataOut = self.createObjByDefault()
                 def createObjByDefault(self):
                     dataObj = Voltage()
                     return dataObj
                 def __hasNotDataInBuffer(self):
                     if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:
                         return 1
                     return 0
                 def getBlockDimension(self):
                     """
                     Obtiene la cantidad de puntos a leer por cada bloque de datos
                     Affected:
                         self.blocksize
                     Return:
                         None
                     """
                     pts2read = self.processingHeaderObj.profilesPerBlock * self.processingHeaderObj.nHeights * self.systemHeaderObj.nChannels
                     self.blocksize = pts2read
                 def readBlock(self):
                     """
                     readBlock lee el bloque de datos desde la posicion actual del puntero del archivo
                     (self.fp) y actualiza todos los parametros relacionados al bloque de datos
                     (metadata + data). La data leida es almacenada en el buffer y el contador del buffer
                     es seteado a 0
                     Inputs:
                         None
                     Return:
                         None
                     Affected:
                         self.profileIndex
                         self.datablock
                         self.flagIsNewFile
                         self.flagIsNewBlock
                         self.nTotalBlocks
                     Exceptions:
                         Si un bloque leido no es un bloque valido
                     """
                     current_pointer_location = self.fp.tell()
                     junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )
                     try:
                         junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )
                     except:
                         #print "The read block (%3d) has not enough data" %self.nReadBlocks
                         if self.waitDataBlock(pointer_location=current_pointer_location):
                             junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )
                             junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )
             #             return 0
                     junk = numpy.transpose(junk, (2,0,1))
                     self.datablock = junk['real'] + junk['imag']*1j
                     self.profileIndex = 0
                     self.flagIsNewFile = 0
                     self.flagIsNewBlock = 1
                     self.nTotalBlocks += 1
                     self.nReadBlocks += 1
                     return 1
                 def getFirstHeader(self):
                     self.dataOut.dtype = self.dtype
                     self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock
                     xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight
                     self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)
                     self.dataOut.channelList = range(self.systemHeaderObj.nChannels)
                     self.dataOut.ippSeconds = self.ippSeconds
                     self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt
                     self.dataOut.nCohInt = self.processingHeaderObj.nCohInt
                     self.dataOut.flagShiftFFT = False
                     if self.radarControllerHeaderObj.code != None:
                         self.dataOut.nCode = self.radarControllerHeaderObj.nCode
                         self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud
                         self.dataOut.code = self.radarControllerHeaderObj.code
                     self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()
                     self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()
                     self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada
                     self.dataOut.flagDeflipData = False #asumo q la data no esta sin flip
                     self.dataOut.flagShiftFFT = False
                 def getData(self):
                     """
                     getData obtiene una unidad de datos del buffer de lectura y la copia a la clase "Voltage"
                     con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de
                     lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"
                     Ademas incrementa el contador del buffer en 1.
                     Return:
                         data    :    retorna un perfil de voltages (alturas * canales) copiados desde el
                                      buffer. Si no hay mas archivos a leer retorna None.
                     Variables afectadas:
                         self.dataOut
                         self.profileIndex
                     Affected:
                         self.dataOut
                         self.profileIndex
                         self.flagTimeBlock
                         self.flagIsNewBlock
                     """
                     if self.flagNoMoreFiles:
                         self.dataOut.flagNoData = True
                         print 'Process finished'
                         return 0
                     self.flagTimeBlock = 0
                     self.flagIsNewBlock = 0
                     if self.__hasNotDataInBuffer():
                         if not( self.readNextBlock() ):
                             return 0
                         self.getFirstHeader()
                     if self.datablock == None:
                         self.dataOut.flagNoData = True
                         return 0
                     self.dataOut.data = self.datablock[:,self.profileIndex,:]
                     self.dataOut.flagNoData = False
                     self.getBasicHeader()
                     self.profileIndex += 1
                     self.dataOut.realtime = self.online
                     return self.dataOut.data
             class VoltageWriter(JRODataWriter):
                 """
                 Esta clase permite escribir datos de voltajes a archivos procesados (.r). La escritura
                 de los datos siempre se realiza por bloques.
                 """
                 ext = ".r"
                 optchar = "D"
                 shapeBuffer = None
                 def __init__(self):
                     """
                     Inicializador de la clase VoltageWriter para la escritura de datos de espectros.
                     Affected:
                         self.dataOut
                     Return: None
                     """
                     self.nTotalBlocks = 0
                     self.profileIndex = 0
                     self.isConfig = False
                     self.fp = None
                     self.flagIsNewFile = 1
                     self.nTotalBlocks = 0
                     self.flagIsNewBlock = 0
                     self.setFile = None
                     self.dtype = None
                     self.path = None
                     self.filename = None
                     self.basicHeaderObj = BasicHeader(LOCALTIME)
                     self.systemHeaderObj = SystemHeader()
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.processingHeaderObj = ProcessingHeader()
                 def hasAllDataInBuffer(self):
                     if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:
                         return 1
                     return 0
                 def setBlockDimension(self):
                     """
                     Obtiene las formas dimensionales del los subbloques de datos que componen un bloque
                     Affected:
                         self.shape_spc_Buffer
                         self.shape_cspc_Buffer
                         self.shape_dc_Buffer
                     Return: None
                     """
                     self.shapeBuffer = (self.processingHeaderObj.profilesPerBlock,
                                         self.processingHeaderObj.nHeights,
                                         self.systemHeaderObj.nChannels)
                     self.datablock = numpy.zeros((self.systemHeaderObj.nChannels,
                                                  self.processingHeaderObj.profilesPerBlock,
                                                  self.processingHeaderObj.nHeights),
                                                  dtype=numpy.dtype('complex64'))
                 def writeBlock(self):
                     """
                     Escribe el buffer en el file designado
                     Affected:
                         self.profileIndex
                         self.flagIsNewFile
                         self.flagIsNewBlock
                         self.nTotalBlocks
                         self.blockIndex
                     Return: None
                     """
                     data = numpy.zeros( self.shapeBuffer, self.dtype )
                     junk = numpy.transpose(self.datablock, (1,2,0))
                     data['real'] = junk.real
                     data['imag'] = junk.imag
                     data = data.reshape( (-1) )
                     data.tofile( self.fp )
                     self.datablock.fill(0)
                     self.profileIndex = 0
                     self.flagIsNewFile = 0
                     self.flagIsNewBlock = 1
                     self.blockIndex += 1
                     self.nTotalBlocks += 1
                 def putData(self):
                     """
                     Setea un bloque de datos y luego los escribe en un file
                     Affected:
                         self.flagIsNewBlock
                         self.profileIndex
                     Return:
 :    Si no hay data o no hay mas files que puedan escribirse
 :    Si se escribio la data de un bloque en un file
                     """
                     if self.dataOut.flagNoData:
                         return 0
                     self.flagIsNewBlock = 0
                     if self.dataOut.flagTimeBlock:
                         self.datablock.fill(0)
                         self.profileIndex = 0
                         self.setNextFile()
                     if self.profileIndex == 0:
                         self.setBasicHeader()
                     self.datablock[:,self.profileIndex,:] = self.dataOut.data
                     self.profileIndex += 1
                     if self.hasAllDataInBuffer():
                         #if self.flagIsNewFile:
                         self.writeNextBlock()
             #            self.setFirstHeader()
                     return 1
                 def __getProcessFlags(self):
                     processFlags = 0
                     dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])
                     dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])
                     dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])
                     dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])
                     dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])
                     dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])
                     dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]
                     datatypeValueList =  [PROCFLAG.DATATYPE_CHAR,
                                        PROCFLAG.DATATYPE_SHORT,
                                        PROCFLAG.DATATYPE_LONG,
                                        PROCFLAG.DATATYPE_INT64,
                                        PROCFLAG.DATATYPE_FLOAT,
                                        PROCFLAG.DATATYPE_DOUBLE]
                     for index in range(len(dtypeList)):
                         if self.dataOut.dtype == dtypeList[index]:
                             dtypeValue = datatypeValueList[index]
                             break
                     processFlags += dtypeValue
                     if self.dataOut.flagDecodeData:
                         processFlags += PROCFLAG.DECODE_DATA
                     if self.dataOut.flagDeflipData:
                         processFlags += PROCFLAG.DEFLIP_DATA
                     if self.dataOut.code != None:
                         processFlags += PROCFLAG.DEFINE_PROCESS_CODE
                     if self.dataOut.nCohInt > 1:
                         processFlags += PROCFLAG.COHERENT_INTEGRATION
                     return processFlags
                 def __getBlockSize(self):
                     '''
                     Este metodos determina el cantidad de bytes para un bloque de datos de tipo Voltage
                     '''
                     dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])
                     dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])
                     dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])
                     dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])
                     dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])
                     dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])
                     dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]
                     datatypeValueList = [1,2,4,8,4,8]
                     for index in range(len(dtypeList)):
                         if self.dataOut.dtype == dtypeList[index]:
                             datatypeValue = datatypeValueList[index]
                             break
                     blocksize = int(self.dataOut.nHeights * self.dataOut.nChannels * self.profilesPerBlock * datatypeValue * 2)
                     return blocksize
                 def setFirstHeader(self):
                     """
                     Obtiene una copia del First Header
                     Affected:
                         self.systemHeaderObj
                         self.radarControllerHeaderObj
                         self.dtype
                     Return:
                         None
                     """
                     self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()
                     self.systemHeaderObj.nChannels = self.dataOut.nChannels
                     self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()
                     self.setBasicHeader()
                     processingHeaderSize = 40 # bytes
                     self.processingHeaderObj.dtype = 0 # Voltage
                     self.processingHeaderObj.blockSize = self.__getBlockSize()
                     self.processingHeaderObj.profilesPerBlock = self.profilesPerBlock
                     self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile
                     self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows
                     self.processingHeaderObj.processFlags = self.__getProcessFlags()
                     self.processingHeaderObj.nCohInt = self.dataOut.nCohInt
                     self.processingHeaderObj.nIncohInt = 1 # Cuando la data de origen es de tipo Voltage
                     self.processingHeaderObj.totalSpectra = 0 # Cuando la data de origen es de tipo Voltage
             #         if self.dataOut.code != None:
             #             self.processingHeaderObj.code = self.dataOut.code
             #             self.processingHeaderObj.nCode = self.dataOut.nCode
             #             self.processingHeaderObj.nBaud = self.dataOut.nBaud
             #             codesize = int(8 + 4 * self.dataOut.nCode * self.dataOut.nBaud)
             #             processingHeaderSize += codesize
                     if self.processingHeaderObj.nWindows != 0:
                         self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]
                         self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]
                         self.processingHeaderObj.nHeights = self.dataOut.nHeights
                         self.processingHeaderObj.samplesWin = self.dataOut.nHeights
                         processingHeaderSize += 12
                     self.processingHeaderObj.size = processingHeaderSize
             class SpectraReader(JRODataReader):
                 """
                 Esta clase permite leer datos de espectros desde archivos procesados (.pdata). La lectura
                 de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones)
                 son almacenados en tres buffer's para el Self Spectra, el Cross Spectra y el DC Channel.
                                     paresCanalesIguales    * alturas * perfiles  (Self Spectra)
                                     paresCanalesDiferentes * alturas * perfiles  (Cross Spectra)
                                     canales * alturas                            (DC Channels)
                 Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,
                 RadarControllerHeader y Spectra. Los tres primeros se usan para almacenar informacion de la
                 cabecera de datos (metadata), y el cuarto (Spectra) para obtener y almacenar un bloque de
                 datos desde el "buffer" cada vez que se ejecute el metodo "getData".
                 Example:
                     dpath = "/home/myuser/data"
                     startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)
                     endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)
                     readerObj = SpectraReader()
                     readerObj.setup(dpath, startTime, endTime)
                     while(True):
                         readerObj.getData()
                         print readerObj.data_spc
                         print readerObj.data_cspc
                         print readerObj.data_dc
                         if readerObj.flagNoMoreFiles:
                             break
                 """
                 pts2read_SelfSpectra = 0
                 pts2read_CrossSpectra = 0
                 pts2read_DCchannels = 0
                 ext = ".pdata"
                 optchar = "P"
                 dataOut = None
                 nRdChannels = None
                 nRdPairs = None
                 rdPairList = []
                 def __init__(self):
                     """
                     Inicializador de la clase SpectraReader para la lectura de datos de espectros.
                     Inputs:
                         dataOut    :    Objeto de la clase Spectra. Este objeto sera utilizado para
                                           almacenar un perfil de datos cada vez que se haga un requerimiento
                                           (getData). El perfil sera obtenido a partir del buffer de datos,
                                           si el buffer esta vacio se hara un nuevo proceso de lectura de un
                                           bloque de datos.
                                           Si este parametro no es pasado se creara uno internamente.
                     Affected:
                         self.dataOut
                     Return      : None
                     """
                     self.isConfig = False
                     self.pts2read_SelfSpectra = 0
                     self.pts2read_CrossSpectra = 0
                     self.pts2read_DCchannels = 0
                     self.datablock = None
                     self.utc = None
                     self.ext = ".pdata"
                     self.optchar = "P"
                     self.basicHeaderObj = BasicHeader(LOCALTIME)
                     self.systemHeaderObj = SystemHeader()
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.processingHeaderObj = ProcessingHeader()
                     self.online = 0
                     self.fp = None
                     self.idFile = None
                     self.dtype = None
                     self.fileSizeByHeader = None
                     self.filenameList = []
                     self.filename = None
                     self.fileSize = None
                     self.firstHeaderSize = 0
                     self.basicHeaderSize = 24
                     self.pathList = []
                     self.lastUTTime = 0
                     self.maxTimeStep = 30
                     self.flagNoMoreFiles = 0
                     self.set = 0
                     self.path = None
                     self.delay  = 60   #seconds
                     self.nTries = 3  #quantity tries
                     self.nFiles = 3   #number of files for searching
                     self.nReadBlocks = 0
                     self.flagIsNewFile = 1
                     self.__isFirstTimeOnline = 1
                     self.ippSeconds = 0
                     self.flagTimeBlock = 0
                     self.flagIsNewBlock = 0
                     self.nTotalBlocks = 0
                     self.blocksize = 0
                     self.dataOut = self.createObjByDefault()
                     self.profileIndex = 1 #Always
                 def createObjByDefault(self):
                     dataObj = Spectra()
                     return dataObj
                 def __hasNotDataInBuffer(self):
                     return 1
                 def getBlockDimension(self):
                     """
                     Obtiene la cantidad de puntos a leer por cada bloque de datos
                     Affected:
                         self.nRdChannels
                         self.nRdPairs
                         self.pts2read_SelfSpectra
                         self.pts2read_CrossSpectra
                         self.pts2read_DCchannels
                         self.blocksize
                         self.dataOut.nChannels
                         self.dataOut.nPairs
                     Return:
                         None
                     """
                     self.nRdChannels = 0
                     self.nRdPairs = 0
                     self.rdPairList = []
                     for i in range(0, self.processingHeaderObj.totalSpectra*2, 2):
                         if self.processingHeaderObj.spectraComb[i] == self.processingHeaderObj.spectraComb[i+1]:
                             self.nRdChannels = self.nRdChannels + 1 #par de canales iguales
                         else:
                             self.nRdPairs = self.nRdPairs + 1 #par de canales diferentes
                             self.rdPairList.append((self.processingHeaderObj.spectraComb[i], self.processingHeaderObj.spectraComb[i+1]))
                     pts2read = self.processingHeaderObj.nHeights * self.processingHeaderObj.profilesPerBlock
                     self.pts2read_SelfSpectra = int(self.nRdChannels * pts2read)
                     self.blocksize = self.pts2read_SelfSpectra
                     if self.processingHeaderObj.flag_cspc:
                         self.pts2read_CrossSpectra = int(self.nRdPairs * pts2read)
                         self.blocksize += self.pts2read_CrossSpectra
                     if self.processingHeaderObj.flag_dc:
                         self.pts2read_DCchannels = int(self.systemHeaderObj.nChannels * self.processingHeaderObj.nHeights)
                         self.blocksize += self.pts2read_DCchannels
             #        self.blocksize = self.pts2read_SelfSpectra + self.pts2read_CrossSpectra + self.pts2read_DCchannels
                 def readBlock(self):
                     """
                     Lee el bloque de datos desde la posicion actual del puntero del archivo
                     (self.fp) y actualiza todos los parametros relacionados al bloque de datos
                     (metadata + data). La data leida es almacenada en el buffer y el contador del buffer
                     es seteado a 0
                     Return: None
                     Variables afectadas:
                         self.flagIsNewFile
                         self.flagIsNewBlock
                         self.nTotalBlocks
                         self.data_spc
                         self.data_cspc
                         self.data_dc
                     Exceptions:
                         Si un bloque leido no es un bloque valido
                     """
                     blockOk_flag = False
                     fpointer = self.fp.tell()
                     spc = numpy.fromfile( self.fp, self.dtype[0], self.pts2read_SelfSpectra )
                     spc = spc.reshape( (self.nRdChannels, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D
                     if self.processingHeaderObj.flag_cspc:
                         cspc = numpy.fromfile( self.fp, self.dtype, self.pts2read_CrossSpectra )
                         cspc = cspc.reshape( (self.nRdPairs, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D
                     if self.processingHeaderObj.flag_dc:
                         dc = numpy.fromfile( self.fp, self.dtype, self.pts2read_DCchannels ) #int(self.processingHeaderObj.nHeights*self.systemHeaderObj.nChannels) )
                         dc = dc.reshape( (self.systemHeaderObj.nChannels, self.processingHeaderObj.nHeights) ) #transforma a un arreglo 2D
                     if not(self.processingHeaderObj.shif_fft):
                         #desplaza a la derecha en el eje 2 determinadas posiciones
                         shift = int(self.processingHeaderObj.profilesPerBlock/2)
                         spc = numpy.roll( spc, shift , axis=2 )
                         if self.processingHeaderObj.flag_cspc:
                             #desplaza a la derecha en el eje 2 determinadas posiciones
                             cspc = numpy.roll( cspc, shift, axis=2 )
             #            self.processingHeaderObj.shif_fft = True
                     spc = numpy.transpose( spc, (0,2,1) )
                     self.data_spc = spc
                     if self.processingHeaderObj.flag_cspc:
                         cspc = numpy.transpose( cspc, (0,2,1) )
                         self.data_cspc = cspc['real'] + cspc['imag']*1j
                     else:
                         self.data_cspc = None
                     if self.processingHeaderObj.flag_dc:
                         self.data_dc = dc['real'] + dc['imag']*1j
                     else:
                         self.data_dc = None
                     self.flagIsNewFile = 0
                     self.flagIsNewBlock = 1
                     self.nTotalBlocks += 1
                     self.nReadBlocks += 1
                     return 1
                 def getFirstHeader(self):
                     self.dataOut.dtype = self.dtype
                     self.dataOut.nPairs = self.nRdPairs
                     self.dataOut.pairsList = self.rdPairList
                     self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock
                     self.dataOut.nFFTPoints = self.processingHeaderObj.profilesPerBlock
                     self.dataOut.nCohInt = self.processingHeaderObj.nCohInt
                     self.dataOut.nIncohInt = self.processingHeaderObj.nIncohInt
                     xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight
                     self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)
                     self.dataOut.channelList = range(self.systemHeaderObj.nChannels)
                     self.dataOut.ippSeconds = self.ippSeconds
                     self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt * self.processingHeaderObj.nIncohInt * self.dataOut.nFFTPoints
                     self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()
                     self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()
                     self.dataOut.flagShiftFFT = self.processingHeaderObj.shif_fft
                     self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada
                     self.dataOut.flagDeflipData = True #asumo q la data no esta sin flip
                     if self.radarControllerHeaderObj.code != None:
                         self.dataOut.nCode = self.radarControllerHeaderObj.nCode
                         self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud
                         self.dataOut.code = self.radarControllerHeaderObj.code
                         self.dataOut.flagDecodeData = True
                 def getData(self):
                     """
                     Copia el buffer de lectura a la clase "Spectra",
                     con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de
                     lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"
                     Return:
 :    Si no hay mas archivos disponibles
 :    Si hizo una buena copia del buffer
                     Affected:
                         self.dataOut
                         self.flagTimeBlock
                         self.flagIsNewBlock
                     """
                     if self.flagNoMoreFiles:
                         self.dataOut.flagNoData = True
                         print 'Process finished'
                         return 0
                     self.flagTimeBlock = 0
                     self.flagIsNewBlock = 0
                     if self.__hasNotDataInBuffer():
                         if not( self.readNextBlock() ):
                             self.dataOut.flagNoData = True
                             return 0
                     #data es un numpy array de 3 dmensiones (perfiles, alturas y canales)
                     if self.data_dc == None:
                         self.dataOut.flagNoData = True
                         return 0
                     self.getBasicHeader()
                     self.getFirstHeader()
                     self.dataOut.data_spc = self.data_spc
                     self.dataOut.data_cspc = self.data_cspc
                     self.dataOut.data_dc = self.data_dc
                     self.dataOut.flagNoData = False
                     self.dataOut.realtime = self.online
                     return self.dataOut.data_spc
             class SpectraWriter(JRODataWriter):
                 """
                 Esta clase permite escribir datos de espectros a archivos procesados (.pdata). La escritura
                 de los datos siempre se realiza por bloques.
                 """
                 ext = ".pdata"
                 optchar = "P"
                 shape_spc_Buffer = None
                 shape_cspc_Buffer = None
                 shape_dc_Buffer = None
                 data_spc = None
                 data_cspc = None
                 data_dc = None
             #    dataOut = None
                 def __init__(self):
                     """
                     Inicializador de la clase SpectraWriter para la escritura de datos de espectros.
                     Affected:
                         self.dataOut
                         self.basicHeaderObj
                         self.systemHeaderObj
                         self.radarControllerHeaderObj
                         self.processingHeaderObj
                     Return: None
                     """
                     self.isConfig = False
                     self.nTotalBlocks = 0
                     self.data_spc = None
                     self.data_cspc = None
                     self.data_dc = None
                     self.fp = None
                     self.flagIsNewFile = 1
                     self.nTotalBlocks = 0
                     self.flagIsNewBlock = 0
                     self.setFile = None
                     self.dtype = None
                     self.path = None
                     self.noMoreFiles = 0
                     self.filename = None
                     self.basicHeaderObj = BasicHeader(LOCALTIME)
                     self.systemHeaderObj = SystemHeader()
                     self.radarControllerHeaderObj = RadarControllerHeader()
                     self.processingHeaderObj = ProcessingHeader()
                 def hasAllDataInBuffer(self):
                     return 1
                 def setBlockDimension(self):
                     """
                     Obtiene las formas dimensionales del los subbloques de datos que componen un bloque
                     Affected:
                         self.shape_spc_Buffer
                         self.shape_cspc_Buffer
                         self.shape_dc_Buffer
                     Return: None
                     """
                     self.shape_spc_Buffer = (self.dataOut.nChannels,
                                              self.processingHeaderObj.nHeights,
                                              self.processingHeaderObj.profilesPerBlock)
                     self.shape_cspc_Buffer = (self.dataOut.nPairs,
                                               self.processingHeaderObj.nHeights,
                                               self.processingHeaderObj.profilesPerBlock)
                     self.shape_dc_Buffer = (self.dataOut.nChannels,
                                             self.processingHeaderObj.nHeights)
                 def writeBlock(self):
                     """
                     Escribe el buffer en el file designado
                     Affected:
                         self.data_spc
                         self.data_cspc
                         self.data_dc
                         self.flagIsNewFile
                         self.flagIsNewBlock
                         self.nTotalBlocks
                         self.nWriteBlocks
                     Return: None
                     """
                     spc = numpy.transpose( self.data_spc, (0,2,1) )
                     if not( self.processingHeaderObj.shif_fft ):
                         spc = numpy.roll( spc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones
                     data = spc.reshape((-1))
                     data = data.astype(self.dtype[0])
                     data.tofile(self.fp)
                     if self.data_cspc != None:
                         data = numpy.zeros( self.shape_cspc_Buffer, self.dtype )
                         cspc = numpy.transpose( self.data_cspc, (0,2,1) )
                         if not( self.processingHeaderObj.shif_fft ):
                             cspc = numpy.roll( cspc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones
                         data['real'] = cspc.real
                         data['imag'] = cspc.imag
                         data = data.reshape((-1))
                         data.tofile(self.fp)
                     if self.data_dc != None:
                         data = numpy.zeros( self.shape_dc_Buffer, self.dtype )
                         dc = self.data_dc
                         data['real'] = dc.real
                         data['imag'] = dc.imag
                         data = data.reshape((-1))
                         data.tofile(self.fp)
                     self.data_spc.fill(0)
                     if self.data_dc != None:
                         self.data_dc.fill(0)
                     if self.data_cspc != None:
                         self.data_cspc.fill(0)
                     self.flagIsNewFile = 0
                     self.flagIsNewBlock = 1
                     self.nTotalBlocks += 1
                     self.nWriteBlocks += 1
                     self.blockIndex += 1
                 def putData(self):
                     """
                     Setea un bloque de datos y luego los escribe en un file
                     Affected:
                         self.data_spc
                         self.data_cspc
                         self.data_dc
                     Return:
 :    Si no hay data o no hay mas files que puedan escribirse
 :    Si se escribio la data de un bloque en un file
                     """
                     if self.dataOut.flagNoData:
                         return 0
                     self.flagIsNewBlock = 0
                     if self.dataOut.flagTimeBlock:
                         self.data_spc.fill(0)
                         self.data_cspc.fill(0)
                         self.data_dc.fill(0)
                         self.setNextFile()
                     if self.flagIsNewFile == 0:
                         self.setBasicHeader()
                     self.data_spc = self.dataOut.data_spc.copy()
                     if self.dataOut.data_cspc != None:
                         self.data_cspc = self.dataOut.data_cspc.copy()
                     self.data_dc = self.dataOut.data_dc.copy()
                     # #self.processingHeaderObj.dataBlocksPerFile)
                     if self.hasAllDataInBuffer():
             #            self.setFirstHeader()
                         self.writeNextBlock()
                     return 1
                 def __getProcessFlags(self):
                     processFlags = 0
                     dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])
                     dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])
                     dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])
                     dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])
                     dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])
                     dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])
                     dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]
                     datatypeValueList =  [PROCFLAG.DATATYPE_CHAR,
                                        PROCFLAG.DATATYPE_SHORT,
                                        PROCFLAG.DATATYPE_LONG,
                                        PROCFLAG.DATATYPE_INT64,
                                        PROCFLAG.DATATYPE_FLOAT,
                                        PROCFLAG.DATATYPE_DOUBLE]
                     for index in range(len(dtypeList)):
                         if self.dataOut.dtype == dtypeList[index]:
                             dtypeValue = datatypeValueList[index]
                             break
                     processFlags += dtypeValue
                     if self.dataOut.flagDecodeData:
                         processFlags += PROCFLAG.DECODE_DATA
                     if self.dataOut.flagDeflipData:
                         processFlags += PROCFLAG.DEFLIP_DATA
                     if self.dataOut.code != None:
                         processFlags += PROCFLAG.DEFINE_PROCESS_CODE
                     if self.dataOut.nIncohInt > 1:
                         processFlags += PROCFLAG.INCOHERENT_INTEGRATION
                     if self.dataOut.data_dc != None:
                         processFlags += PROCFLAG.SAVE_CHANNELS_DC
                     return processFlags
                 def __getBlockSize(self):
                     '''
                     Este metodos determina el cantidad de bytes para un bloque de datos de tipo Spectra
                     '''
                     dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])
                     dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])
                     dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])
                     dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])
                     dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])
                     dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])
                     dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]
                     datatypeValueList = [1,2,4,8,4,8]
                     for index in range(len(dtypeList)):
                         if self.dataOut.dtype == dtypeList[index]:
                             datatypeValue = datatypeValueList[index]
                             break
                     pts2write = self.dataOut.nHeights * self.dataOut.nFFTPoints
                     pts2write_SelfSpectra = int(self.dataOut.nChannels * pts2write)
                     blocksize = (pts2write_SelfSpectra*datatypeValue)
                     if self.dataOut.data_cspc != None:
                         pts2write_CrossSpectra = int(self.dataOut.nPairs * pts2write)
                         blocksize += (pts2write_CrossSpectra*datatypeValue*2)
                     if self.dataOut.data_dc != None:
                         pts2write_DCchannels = int(self.dataOut.nChannels * self.dataOut.nHeights)
                         blocksize += (pts2write_DCchannels*datatypeValue*2)
                     blocksize = blocksize #* datatypeValue * 2 #CORREGIR ESTO
                     return blocksize
                 def setFirstHeader(self):
                     """
                     Obtiene una copia del First Header
                     Affected:
                         self.systemHeaderObj
                         self.radarControllerHeaderObj
                         self.dtype
                     Return:
                         None
                     """
                     self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()
                     self.systemHeaderObj.nChannels = self.dataOut.nChannels
                     self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()
                     old_code_size = self.dataOut.radarControllerHeaderObj.code_size
                     new_code_size = int(numpy.ceil(self.dataOut.nBaud/32.))*self.dataOut.nCode*4
                     self.radarControllerHeaderObj.size = self.radarControllerHeaderObj.size - old_code_size + new_code_size
                     self.setBasicHeader()
                     processingHeaderSize = 40 # bytes
                     self.processingHeaderObj.dtype = 1 # Spectra
                     self.processingHeaderObj.blockSize = self.__getBlockSize()
                     self.processingHeaderObj.profilesPerBlock = self.dataOut.nFFTPoints
                     self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile
                     self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows
                     self.processingHeaderObj.processFlags = self.__getProcessFlags()
                     self.processingHeaderObj.nCohInt = self.dataOut.nCohInt# Se requiere para determinar el valor de timeInterval
                     self.processingHeaderObj.nIncohInt = self.dataOut.nIncohInt
                     self.processingHeaderObj.totalSpectra = self.dataOut.nPairs + self.dataOut.nChannels
                     self.processingHeaderObj.shif_fft = self.dataOut.flagShiftFFT
                     if self.processingHeaderObj.totalSpectra > 0:
                         channelList = []
                         for channel in range(self.dataOut.nChannels):
                             channelList.append(channel)
                             channelList.append(channel)
                         pairsList = []
                         if self.dataOut.nPairs > 0:
                             for pair in self.dataOut.pairsList:
                                 pairsList.append(pair[0])
                                 pairsList.append(pair[1])
                         spectraComb = channelList + pairsList
                         spectraComb = numpy.array(spectraComb,dtype="u1")
                         self.processingHeaderObj.spectraComb = spectraComb
                         sizeOfSpcComb = len(spectraComb)
                         processingHeaderSize += sizeOfSpcComb
             #        The processing header should not have information about code
             #        if self.dataOut.code != None:
             #            self.processingHeaderObj.code = self.dataOut.code
             #            self.processingHeaderObj.nCode = self.dataOut.nCode
             #            self.processingHeaderObj.nBaud = self.dataOut.nBaud
             #            nCodeSize = 4 # bytes
             #            nBaudSize = 4 # bytes
             #            codeSize = 4 # bytes
             #            sizeOfCode = int(nCodeSize + nBaudSize + codeSize * self.dataOut.nCode * self.dataOut.nBaud)
             #            processingHeaderSize += sizeOfCode
                     if self.processingHeaderObj.nWindows != 0:
                         self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]
                         self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]
                         self.processingHeaderObj.nHeights = self.dataOut.nHeights
                         self.processingHeaderObj.samplesWin = self.dataOut.nHeights
                         sizeOfFirstHeight = 4
                         sizeOfdeltaHeight = 4
                         sizeOfnHeights = 4
                         sizeOfWindows = (sizeOfFirstHeight + sizeOfdeltaHeight + sizeOfnHeights)*self.processingHeaderObj.nWindows
                         processingHeaderSize += sizeOfWindows
                     self.processingHeaderObj.size = processingHeaderSize
             class SpectraHeisWriter(Operation):
             #    set = None
                 setFile = None
                 idblock = None
                 doypath = None
                 subfolder = None
                 def __init__(self):
                     self.wrObj = FITS()
             #        self.dataOut = dataOut
                     self.nTotalBlocks=0
             #        self.set = None
                     self.setFile = None
                     self.idblock = 0
                     self.wrpath = None
                     self.doypath = None
                     self.subfolder = None
                     self.isConfig = False
                 def isNumber(str):
                     """
                     Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.
                     Excepciones:
                     Si un determinado string no puede ser convertido a numero
                     Input:
                     str, string al cual se le analiza para determinar si convertible a un numero o no
                     Return:
                     True    :    si el string es uno numerico
                     False   :    no es un string numerico
                     """
                     try:
                         float( str )
                         return True
                     except:
                         return False
                 def setup(self, dataOut, wrpath):
                     if not(os.path.exists(wrpath)):
                         os.mkdir(wrpath)
                     self.wrpath = wrpath
             #        self.setFile = 0
                     self.dataOut = dataOut
                 def putData(self):
                     name= time.localtime( self.dataOut.utctime)
                     ext=".fits"
                     if self.doypath == None:
                        self.subfolder = 'F%4.4d%3.3d_%d' % (name.tm_year,name.tm_yday,time.mktime(datetime.datetime.now().timetuple()))
                        self.doypath = os.path.join( self.wrpath, self.subfolder )
                        os.mkdir(self.doypath)
                     if self.setFile == None:
             #           self.set = self.dataOut.set
                        self.setFile = 0
             #        if self.set != self.dataOut.set:
             ##            self.set = self.dataOut.set
             #            self.setFile = 0
                     #make the filename
                     file = 'D%4.4d%3.3d_%3.3d%s' % (name.tm_year,name.tm_yday,self.setFile,ext)
                     filename = os.path.join(self.wrpath,self.subfolder, file)
                     idblock = numpy.array([self.idblock],dtype="int64")
                     header=self.wrObj.cFImage(idblock=idblock,
                                             year=time.gmtime(self.dataOut.utctime).tm_year,
                                             month=time.gmtime(self.dataOut.utctime).tm_mon,
                                             day=time.gmtime(self.dataOut.utctime).tm_mday,
                                             hour=time.gmtime(self.dataOut.utctime).tm_hour,
                                             minute=time.gmtime(self.dataOut.utctime).tm_min,
                                             second=time.gmtime(self.dataOut.utctime).tm_sec)
                     c=3E8
                     deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]
                     freq=numpy.arange(-1*self.dataOut.nHeights/2.,self.dataOut.nHeights/2.)*(c/(2*deltaHeight*1000))
                     colList = []
                     colFreq=self.wrObj.setColF(name="freq", format=str(self.dataOut.nFFTPoints)+'E', array=freq)
                     colList.append(colFreq)
                     nchannel=self.dataOut.nChannels
                     for i in range(nchannel):
                         col = self.wrObj.writeData(name="PCh"+str(i+1),
                                                      format=str(self.dataOut.nFFTPoints)+'E',
                                                       data=10*numpy.log10(self.dataOut.data_spc[i,:]))
                         colList.append(col)
                     data=self.wrObj.Ctable(colList=colList)
                     self.wrObj.CFile(header,data)
                     self.wrObj.wFile(filename)
                     #update the setFile
                     self.setFile += 1
                     self.idblock += 1
                     return 1
                 def run(self, dataOut, **kwargs):
                     if not(self.isConfig):
                         self.setup(dataOut, **kwargs)
                         self.isConfig = True
                     self.putData()
             class ParameterConf:
                 ELEMENTNAME = 'Parameter'
                 def __init__(self):
                     self.name = ''
                     self.value = ''
                 def readXml(self, parmElement):
                     self.name = parmElement.get('name')
                     self.value = parmElement.get('value')
                 def getElementName(self):
                     return self.ELEMENTNAME
             class Metadata:
                 def __init__(self, filename):
                     self.parmConfObjList = []
                     self.readXml(filename)
                 def readXml(self, filename):
                     self.projectElement = None
                     self.procUnitConfObjDict = {}
                     self.projectElement = ElementTree().parse(filename)
                     self.project = self.projectElement.tag
                     parmElementList = self.projectElement.getiterator(ParameterConf().getElementName())
                     for parmElement in parmElementList:
                         parmConfObj = ParameterConf()
                         parmConfObj.readXml(parmElement)
                         self.parmConfObjList.append(parmConfObj)
             class FitsWriter(Operation):
                 def __init__(self):
                     self.isConfig = False
                     self.dataBlocksPerFile = None
                     self.blockIndex = 0
                     self.flagIsNewFile = 1
                     self.fitsObj = None
                     self.optchar = 'P'
                     self.ext = '.fits'
                     self.setFile = 0
                 def setFitsHeader(self, dataOut, metadatafile):
                     header_data = pyfits.PrimaryHDU()
                     metadata4fits = Metadata(metadatafile)
                     for parameter in metadata4fits.parmConfObjList:
                         parm_name = parameter.name
                         parm_value = parameter.value
             #             if parm_value == 'fromdatadatetime':
             #                 value = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())
             #             elif parm_value == 'fromdataheights':
             #                 value = dataOut.nHeights
             #             elif parm_value == 'fromdatachannel':
             #                 value = dataOut.nChannels
             #             elif parm_value == 'fromdatasamples':
             #                 value = dataOut.nFFTPoints
             #             else:
             #                 value = parm_value
                         header_data.header[parm_name] = parm_value
                     header_data.header['DATETIME'] = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())
                     header_data.header['CHANNELLIST'] = str(dataOut.channelList)
                     header_data.header['NCHANNELS'] = dataOut.nChannels
                     #header_data.header['HEIGHTS'] = dataOut.heightList
                     header_data.header['NHEIGHTS'] = dataOut.nHeights
                     header_data.header['IPPSECONDS'] = dataOut.ippSeconds
                     header_data.header['NCOHINT'] = dataOut.nCohInt
                     header_data.header['NINCOHINT'] = dataOut.nIncohInt
                     header_data.header['TIMEZONE'] = dataOut.timeZone
                     header_data.header['NBLOCK'] = self.blockIndex
                     header_data.writeto(self.filename)
                     self.addExtension(dataOut.heightList,'HEIGHTLIST')
                 def setup(self, dataOut, path, dataBlocksPerFile, metadatafile):
                     self.path = path
                     self.dataOut = dataOut
                     self.metadatafile = metadatafile
                     self.dataBlocksPerFile = dataBlocksPerFile
                 def open(self):
                     self.fitsObj = pyfits.open(self.filename, mode='update')
                 def addExtension(self, data, tagname):
                     self.open()
                     extension = pyfits.ImageHDU(data=data, name=tagname)
                     #extension.header['TAG'] = tagname
                     self.fitsObj.append(extension)
                     self.write()
                 def addData(self, data):
                     self.open()
                     extension = pyfits.ImageHDU(data=data, name=self.fitsObj[0].header['DATATYPE'])
                     extension.header['UTCTIME'] = self.dataOut.utctime
                     self.fitsObj.append(extension)
                     self.blockIndex += 1
                     self.fitsObj[0].header['NBLOCK'] = self.blockIndex
                     self.write()
                 def write(self):
                     self.fitsObj.flush(verbose=True)
                     self.fitsObj.close()
                 def setNextFile(self):
                     ext = self.ext
                     path = self.path
                     timeTuple = time.localtime( self.dataOut.utctime)
                     subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)
                     fullpath = os.path.join( path, subfolder )
                     if not( os.path.exists(fullpath) ):
                         os.mkdir(fullpath)
                         self.setFile = -1 #inicializo mi contador de seteo
                     else:
                         filesList = os.listdir( fullpath )
                         if len( filesList ) > 0:
                             filesList = sorted( filesList, key=str.lower )
                             filen = filesList[-1]
                             if isNumber( filen[8:11] ):
                                 self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file
                             else:
                                 self.setFile = -1
                         else:
                             self.setFile = -1 #inicializo mi contador de seteo
                     setFile = self.setFile
                     setFile += 1
                     file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,
                                                     timeTuple.tm_year,
                                                     timeTuple.tm_yday,
                                                     setFile,
                                                     ext )
                     filename = os.path.join( path, subfolder, file )
                     self.blockIndex = 0
                     self.filename = filename
                     self.setFile = setFile
                     self.flagIsNewFile = 1
                     print 'Writing the file: %s'%self.filename
                     self.setFitsHeader(self.dataOut, self.metadatafile)
                     return 1
                 def writeBlock(self):
                     self.addData(self.dataOut.data_spc)
                     self.flagIsNewFile = 0
                 def __setNewBlock(self):
                     if self.flagIsNewFile:
                         return 1
                     if self.blockIndex < self.dataBlocksPerFile:
                         return 1
                     if not( self.setNextFile() ):
                         return 0
                     return 1
                 def writeNextBlock(self):
                     if not( self.__setNewBlock() ):
                         return 0
                     self.writeBlock()
                     return 1
                 def putData(self):
                     if self.flagIsNewFile:
                         self.setNextFile()
                     self.writeNextBlock()
                 def run(self, dataOut, **kwargs):
                     if not(self.isConfig):
                         self.setup(dataOut, **kwargs)
                         self.isConfig = True
                     self.putData()
             class FitsReader(ProcessingUnit):
             #     __TIMEZONE = time.timezone
                 expName = None
                 datetimestr = None
                 utc = None
                 nChannels = None
                 nSamples = None
                 dataBlocksPerFile = None
                 comments = None
                 lastUTTime = None
                 header_dict = None
                 data = None
                 data_header_dict = None
                 def __init__(self):
                     self.isConfig = False
                     self.ext = '.fits'
                     self.setFile = 0
                     self.flagNoMoreFiles = 0
                     self.flagIsNewFile = 1
                     self.flagTimeBlock = None
                     self.fileIndex = None
                     self.filename = None
                     self.fileSize = None
                     self.fitsObj = None
                     self.timeZone = None
                     self.nReadBlocks = 0
                     self.nTotalBlocks = 0
                     self.dataOut = self.createObjByDefault()
                     self.maxTimeStep = 10# deberia ser definido por el usuario usando el metodo setup()
                     self.blockIndex = 1
                 def createObjByDefault(self):
                     dataObj = Fits()
                     return dataObj
                 def isFileinThisTime(self, filename, startTime, endTime, useLocalTime=False):
                     try:
                         fitsObj = pyfits.open(filename,'readonly')
                     except:
                         raise IOError, "The file %s can't be opened" %(filename)
                     header = fitsObj[0].header
                     struct_time = time.strptime(header['DATETIME'], "%b %d %Y %H:%M:%S")
                     utc = time.mktime(struct_time) - time.timezone #TIMEZONE debe ser un parametro del header FITS
                     ltc = utc
                     if useLocalTime:
                         ltc -= time.timezone
                     thisDatetime = datetime.datetime.utcfromtimestamp(ltc)
                     thisTime = thisDatetime.time()
                     if not ((startTime <= thisTime) and (endTime > thisTime)):
                         return None
                     return thisDatetime
                 def __setNextFileOnline(self):
                     raise ValueError, "No implemented"
                 def __setNextFileOffline(self):
                     idFile = self.fileIndex
                     while (True):
                         idFile += 1
                         if not(idFile < len(self.filenameList)):
                             self.flagNoMoreFiles = 1
                             print "No more Files"
                             return 0
                         filename = self.filenameList[idFile]
             #            if not(self.__verifyFile(filename)):
             #                continue
                         fileSize = os.path.getsize(filename)
                         fitsObj = pyfits.open(filename,'readonly')
                         break
                     self.flagIsNewFile = 1
                     self.fileIndex = idFile
                     self.filename = filename
                     self.fileSize = fileSize
                     self.fitsObj = fitsObj
                     self.blockIndex = 0
                     print "Setting the file: %s"%self.filename
                     return 1
                 def readHeader(self):
                     headerObj = self.fitsObj[0]
                     self.header_dict = headerObj.header
                     if 'EXPNAME' in headerObj.header.keys():
                         self.expName = headerObj.header['EXPNAME']
                     if 'DATATYPE' in headerObj.header.keys():
                         self.dataType = headerObj.header['DATATYPE']
                     self.datetimestr = headerObj.header['DATETIME']
                     channelList = headerObj.header['CHANNELLIST']
                     channelList = channelList.split('[')
                     channelList = channelList[1].split(']')
                     channelList = channelList[0].split(',')
                     channelList = [int(ch) for ch in channelList]
                     self.channelList = channelList
                     self.nChannels = headerObj.header['NCHANNELS']
                     self.nHeights = headerObj.header['NHEIGHTS']
                     self.ippSeconds = headerObj.header['IPPSECONDS']
                     self.nCohInt = headerObj.header['NCOHINT']
                     self.nIncohInt = headerObj.header['NINCOHINT']
                     self.dataBlocksPerFile = headerObj.header['NBLOCK']
                     self.timeZone = headerObj.header['TIMEZONE']
                     self.timeInterval = self.ippSeconds * self.nCohInt * self.nIncohInt
                     if 'COMMENT' in headerObj.header.keys():
                         self.comments = headerObj.header['COMMENT']
                     self.readHeightList()
                 def readHeightList(self):
                     self.blockIndex = self.blockIndex + 1
                     obj = self.fitsObj[self.blockIndex]
                     self.heightList = obj.data
                     self.blockIndex = self.blockIndex + 1
                 def readExtension(self):
                     obj = self.fitsObj[self.blockIndex]
                     self.heightList = obj.data
                     self.blockIndex = self.blockIndex + 1
                 def setNextFile(self):
                     if self.online:
                         newFile = self.__setNextFileOnline()
                     else:
                         newFile = self.__setNextFileOffline()
                     if not(newFile):
                         return 0
                     self.readHeader()
                     self.nReadBlocks = 0
             #         self.blockIndex = 1
                     return 1
                 def __searchFilesOffLine(self,
                                         path,
                                         startDate,
                                         endDate,
                                         startTime=datetime.time(0,0,0),
                                         endTime=datetime.time(23,59,59),
                                         set=None,
                                         expLabel='',
                                         ext='.fits',
                                         walk=True):
                     pathList = []
                     if not walk:
                         pathList.append(path)
                     else:
                         dirList = []
                         for thisPath in os.listdir(path):
                             if not os.path.isdir(os.path.join(path,thisPath)):
                                 continue
                             if not isDoyFolder(thisPath):
                                 continue
                             dirList.append(thisPath)
                         if not(dirList):
                             return None, None
                         thisDate = startDate
                         while(thisDate <= endDate):
                             year = thisDate.timetuple().tm_year
                             doy = thisDate.timetuple().tm_yday
                             matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')
                             if len(matchlist) == 0:
                                 thisDate += datetime.timedelta(1)
                                 continue
                             for match in matchlist:
                                 pathList.append(os.path.join(path,match,expLabel))
                             thisDate += datetime.timedelta(1)
                     if pathList == []:
                         print "Any folder was found for the date range: %s-%s" %(startDate, endDate)
                         return None, None
                     print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)
                     filenameList = []
                     datetimeList = []
                     for i in range(len(pathList)):
                         thisPath = pathList[i]
                         fileList = glob.glob1(thisPath, "*%s" %ext)
                         fileList.sort()
                         for file in fileList:
                             filename = os.path.join(thisPath,file)
                             thisDatetime = self.isFileinThisTime(filename, startTime, endTime)
                             if not(thisDatetime):
                                 continue
                             filenameList.append(filename)
                             datetimeList.append(thisDatetime)
                     if not(filenameList):
                         print "Any file was found for the time range %s - %s" %(startTime, endTime)
                         return None, None
                     print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)
                     print
                     for i in range(len(filenameList)):
                         print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())
                     self.filenameList = filenameList
                     self.datetimeList = datetimeList
                     return pathList, filenameList
                 def setup(self, path=None,
                             startDate=None,
                             endDate=None,
                             startTime=datetime.time(0,0,0),
                             endTime=datetime.time(23,59,59),
                             set=0,
                             expLabel = "",
                             ext = None,
                             online = False,
                             delay = 60,
                             walk = True):
                     if path == None:
                         raise ValueError, "The path is not valid"
                     if ext == None:
                         ext = self.ext
                     if not(online):
                         print "Searching files in offline mode ..."
                         pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,
                                                                            startTime=startTime, endTime=endTime,
                                                                            set=set, expLabel=expLabel, ext=ext,
                                                                            walk=walk)
                         if not(pathList):
                             print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,
                                                                     datetime.datetime.combine(startDate,startTime).ctime(),
                                                                     datetime.datetime.combine(endDate,endTime).ctime())
                             sys.exit(-1)
                         self.fileIndex = -1
                         self.pathList = pathList
                         self.filenameList = filenameList
                     self.online = online
                     self.delay = delay
                     ext = ext.lower()
                     self.ext = ext
                     if not(self.setNextFile()):
                         if (startDate!=None) and (endDate!=None):
                             print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())
                         elif startDate != None:
                             print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())
                         else:
                             print "No files"
                         sys.exit(-1)
                 def readBlock(self):
                     dataObj = self.fitsObj[self.blockIndex]
                     self.data = dataObj.data
                     self.data_header_dict = dataObj.header
                     self.utc = self.data_header_dict['UTCTIME']
                     self.flagIsNewFile = 0
                     self.blockIndex += 1
                     self.nTotalBlocks += 1
                     self.nReadBlocks += 1
                     return 1
                 def __jumpToLastBlock(self):
                     raise ValueError, "No implemented"
                 def __waitNewBlock(self):
                     """
                     Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.
                     Si el modo de lectura es OffLine siempre retorn 0
                     """
                     if not self.online:
                         return 0
                     if (self.nReadBlocks >= self.dataBlocksPerFile):
                         return 0
                     currentPointer = self.fp.tell()
                     neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize
                     for nTries in range( self.nTries ):
                         self.fp.close()
                         self.fp = open( self.filename, 'rb' )
                         self.fp.seek( currentPointer )
                         self.fileSize = os.path.getsize( self.filename )
                         currentSize = self.fileSize - currentPointer
                         if ( currentSize >= neededSize ):
                             self.__rdBasicHeader()
                             return 1
                         print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)
                         time.sleep( self.delay )
                     return 0
                 def __setNewBlock(self):
                     if self.online:
                         self.__jumpToLastBlock()
                     if self.flagIsNewFile:
                         return 1
                     self.lastUTTime = self.utc
                     if self.online:
                         if self.__waitNewBlock():
                             return 1
                     if self.nReadBlocks < self.dataBlocksPerFile:
                         return 1
                     if not(self.setNextFile()):
                         return 0
                     deltaTime = self.utc - self.lastUTTime
                     self.flagTimeBlock = 0
                     if deltaTime > self.maxTimeStep:
                         self.flagTimeBlock = 1
                     return 1
                 def readNextBlock(self):
                     if not(self.__setNewBlock()):
                         return 0
                     if not(self.readBlock()):
                         return 0
                     return 1
                 def getData(self):
                     if self.flagNoMoreFiles:
                         self.dataOut.flagNoData = True
                         print 'Process finished'
                         return 0
                     self.flagTimeBlock = 0
                     self.flagIsNewBlock = 0
                     if not(self.readNextBlock()):
                         return 0
                     if self.data == None:
                         self.dataOut.flagNoData = True
                         return 0
                     self.dataOut.data = self.data
                     self.dataOut.data_header = self.data_header_dict
                     self.dataOut.utctime = self.utc
                     self.dataOut.header = self.header_dict
                     self.dataOut.expName = self.expName
                     self.dataOut.nChannels = self.nChannels
                     self.dataOut.timeZone = self.timeZone
                     self.dataOut.dataBlocksPerFile = self.dataBlocksPerFile
                     self.dataOut.comments = self.comments
                     self.dataOut.timeInterval = self.timeInterval
                     self.dataOut.channelList = self.channelList
                     self.dataOut.heightList = self.heightList
                     self.dataOut.flagNoData = False
                     return self.dataOut.data
                 def run(self, **kwargs):
                     if not(self.isConfig):
                         self.setup(**kwargs)
                         self.isConfig = True
                     self.getData()
             class RadacHeader():
                 def __init__(self, fp):
                     header = 'Raw11/Data/RadacHeader'
                     self.beamCodeByPulse = fp.get(header+'/BeamCode')
                     self.beamCode = fp.get('Raw11/Data/Beamcodes')
                     self.code = fp.get(header+'/Code')
                     self.frameCount = fp.get(header+'/FrameCount')
                     self.modeGroup = fp.get(header+'/ModeGroup')
                     self.nsamplesPulse = fp.get(header+'/NSamplesPulse')
                     self.pulseCount = fp.get(header+'/PulseCount')
                     self.radacTime = fp.get(header+'/RadacTime')
                     self.timeCount = fp.get(header+'/TimeCount')
                     self.timeStatus = fp.get(header+'/TimeStatus')
                     self.nrecords = self.pulseCount.shape[0] #numero de bloques
                     self.npulses = self.pulseCount.shape[1] #numero de perfiles
                     self.nsamples = self.nsamplesPulse[0,0] #numero de alturas
                     self.nbeams = self.beamCode.shape[1] #numero de beams
                 def getIndexRangeToPulse(self, idrecord=0):
                     indexToZero = numpy.where(self.pulseCount.value[idrecord,:]==0)
                     startPulseCountId = indexToZero[0][0]
                     endPulseCountId = startPulseCountId - 1
                     range1 = numpy.arange(startPulseCountId,self.npulses,1)
                     range2 = numpy.arange(0,startPulseCountId,1)
                     return range1, range2
             class AMISRReader(ProcessingUnit):
                 path = None
                 startDate = None
                 endDate = None
                 startTime = None
                 endTime = None
                 walk = None
                 isConfig = False
                 def __init__(self):
                     self.set = None
                     self.subset = None
                     self.extension_file = '.h5'
                     self.dtc_str = 'dtc'
                     self.dtc_id = 0
                     self.status = True
                     self.isConfig = False
                     self.dirnameList = []
                     self.filenameList = []
                     self.fileIndex = None
                     self.flagNoMoreFiles = False
                     self.flagIsNewFile = 0
                     self.filename = ''
                     self.amisrFilePointer = None
                     self.radacHeaderObj = None
                     self.dataOut = self.__createObjByDefault()
                     self.datablock = None
                     self.rest_datablock = None
                     self.range = None
                     self.idrecord_count = 0
                     self.profileIndex = 0
                     self.idpulse_range1 = None
                     self.idpulse_range2 = None
                     self.beamCodeByFrame = None
                     self.radacTimeByFrame = None
                     #atributos originales tal y como esta en el archivo de datos
                     self.beamCodesFromFile = None
                     self.radacTimeFromFile = None
                     self.rangeFromFile = None
                     self.dataByFrame = None
                     self.dataset = None
                     self.beamCodeDict = {}
                     self.beamRangeDict = {}
+                    #experiment cgf file
+                    self.npulsesint_fromfile = None
+                    self.recordsperfile_fromfile = None
+                    self.nbeamcodes_fromfile = None
+                    self.ngates_fromfile = None
+                    self.ippSeconds_fromfile = None
+                    self.frequency_h5file = None
                 def __createObjByDefault(self):
                     dataObj = AMISR()
                     return dataObj
                 def __setParameters(self,path,startDate,endDate,startTime,endTime,walk):
                     self.path = path
                     self.startDate = startDate
                     self.endDate = endDate
                     self.startTime = startTime
                     self.endTime = endTime
                     self.walk = walk
                 def __checkPath(self):
                     if os.path.exists(self.path):
                         self.status = 1
                     else:
                         self.status = 0
                         print 'Path:%s does not exists'%self.path
                     return
                 def __selDates(self, amisr_dirname_format):
                     year = int(amisr_dirname_format[0:4])
                     month = int(amisr_dirname_format[4:6])
                     dom = int(amisr_dirname_format[6:8])
                     thisDate = datetime.date(year,month,dom)
                     if (thisDate>=self.startDate and thisDate <= self.endDate):
                         return amisr_dirname_format
                 def __findDataForDates(self):
-                    import re
                     if not(self.status):
                         return None
                     pat = '\d+.\d+'
                     dirnameList = [re.search(pat,x).string for x in os.listdir(self.path)]
                     dirnameList = [self.__selDates(x) for x in dirnameList]
                     dirnameList = filter(lambda x:x!=None,dirnameList)
                     if len(dirnameList)>0:
                         self.status = 1
                         self.dirnameList = dirnameList
                         self.dirnameList.sort()
                     else:
                         self.status = 0
                         return None
                 def __getTimeFromData(self):
                     pass
                 def __filterByGlob1(self, dirName):
                     filter_files = glob.glob1(dirName, '*.*%s'%self.extension_file)
                     filterDict = {}
                     filterDict.setdefault(dirName)
                     filterDict[dirName] = filter_files
                     return filterDict
                 def __getFilenameList(self, fileListInKeys, dirList):
                     for value in fileListInKeys:
                         dirName = value.keys()[0]
                         for file in value[dirName]:
                             filename = os.path.join(dirName, file)
                             self.filenameList.append(filename)
                 def __selectDataForTimes(self):
                     #aun no esta implementado el filtro for tiempo
                     if not(self.status):
                         return None
                     dirList = [os.path.join(self.path,x) for x in self.dirnameList]
                     fileListInKeys = [self.__filterByGlob1(x) for x in dirList]
                     self.__getFilenameList(fileListInKeys, dirList)
                     if len(self.filenameList)>0:
                         self.status = 1
                         self.filenameList.sort()
                     else:
                         self.status = 0
                         return None
                 def __searchFilesOffline(self,
                                         path,
                                         startDate,
                                         endDate,
                                         startTime=datetime.time(0,0,0),
                                         endTime=datetime.time(23,59,59),
                                         walk=True):
                     self.__setParameters(path, startDate, endDate, startTime, endTime, walk)
                     self.__checkPath()
                     self.__findDataForDates()
                     self.__selectDataForTimes()
                     for i in range(len(self.filenameList)):
                         print "%s" %(self.filenameList[i])
                     return
                 def __setNextFileOffline(self):
                     idFile = self.fileIndex
                     while (True):
                         idFile += 1
                         if not(idFile < len(self.filenameList)):
                             self.flagNoMoreFiles = 1
                             print "No more Files"
                             return 0
                         filename = self.filenameList[idFile]
                         amisrFilePointer = h5py.File(filename,'r')
                         break
                     self.flagIsNewFile = 1
                     self.fileIndex = idFile
                     self.filename = filename
                     self.amisrFilePointer = amisrFilePointer
                     print "Setting the file: %s"%self.filename
                     return 1
                 def __readHeader(self):
                     self.radacHeaderObj = RadacHeader(self.amisrFilePointer)
+                    #update values from experiment cfg file
+                    self.radacHeaderObj.nrecords = self.recordsperfile_fromfile
+                    self.radacHeaderObj.nbeams = self.nbeamcodes_fromfile
+                    self.radacHeaderObj.npulses = self.npulsesint_fromfile
+                    self.radacHeaderObj.nsamples = self.ngates_fromfile
+                    #get tuning frequency
+                    frequency_h5file_dataset = self.amisrFilePointer.get('Rx'+'/TuningFrequency')
+                    self.frequency_h5file = frequency_h5file_dataset[0,0]
                     self.flagIsNewFile = 1
                 def __getBeamCode(self):
                     self.beamCodeDict = {}
                     self.beamRangeDict = {}
                     for i in range(len(self.radacHeaderObj.beamCode[0,:])):
                         self.beamCodeDict.setdefault(i)
                         self.beamRangeDict.setdefault(i)
                         self.beamCodeDict[i] = self.radacHeaderObj.beamCode[0,i]
                     just4record0 = self.radacHeaderObj.beamCodeByPulse[0,:]
                     for i in range(len(self.beamCodeDict.values())):
                         xx = numpy.where(just4record0==self.beamCodeDict.values()[i])
                         self.beamRangeDict[i] = xx[0]
+                def __getExpParameters(self):
+                    if not(self.status):
+                        return None
+                    experimentCfgPath = os.path.join(self.path, self.dirnameList[0], 'Setup')
+                    expFinder = glob.glob1(experimentCfgPath,'*.exp')
+                    if len(expFinder)== 0:
+                        self.status = 0
+                        return None
+                    experimentFilename = os.path.join(experimentCfgPath,expFinder[0])
+                    f = open(experimentFilename)
+                    lines = f.readlines()
+                    f.close()
+                    parmsList = ['npulsesint*','recordsperfile*','nbeamcodes*','ngates*']
+                    filterList = [fnmatch.filter(lines, x) for x in parmsList]
+                    values = [re.sub(r'\D',"",x[0]) for x in filterList]
+                    self.npulsesint_fromfile = int(values[0])
+                    self.recordsperfile_fromfile = int(values[1])
+                    self.nbeamcodes_fromfile = int(values[2])
+                    self.ngates_fromfile = int(values[3])
+                    tufileFinder = fnmatch.filter(lines, 'tufile=*')
+                    tufile = tufileFinder[0].split('=')[1].split('\n')[0]
+                    tufilename = os.path.join(experimentCfgPath,tufile)
+                    f = open(tufilename)
+                    lines = f.readlines()
+                    f.close()
+                    self.ippSeconds_fromfile = float(lines[1].split()[2])/1E6
+                    self.status = 1
                 def __setNextFile(self):
                     newFile = self.__setNextFileOffline()
                     if not(newFile):
                         return 0
                     self.__readHeader()
                     self.__getBeamCode()
                     self.readDataBlock()
                 def setup(self,path=None,
                                 startDate=None,
                                 endDate=None,
                                 startTime=datetime.time(0,0,0),
                                 endTime=datetime.time(23,59,59),
                                 walk=True):
                     #Busqueda de archivos offline
                     self.__searchFilesOffline(path, startDate, endDate, startTime, endTime, walk)
                     if not(self.filenameList):
                         print "There is no files into the folder: %s"%(path)
                         sys.exit(-1)
+                    self.__getExpParameters()
                     self.fileIndex = -1
                     self.__setNextFile()
                 def readRanges(self):
                     dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Range')
                     #self.rangeFromFile = dataset.value
                     self.rangeFromFile = numpy.reshape(dataset.value,(-1))
                     return range
                 def readRadacTime(self,idrecord, range1, range2):
                     self.radacTimeFromFile = self.radacHeaderObj.radacTime.value
                     radacTimeByFrame = numpy.zeros((self.radacHeaderObj.npulses))
                     #radacTimeByFrame = dataset[idrecord - 1,range1]
                     #radacTimeByFrame = dataset[idrecord,range2]
                     return radacTimeByFrame
                 def readBeamCode(self, idrecord, range1, range2):
                     dataset = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode')
                     beamcodeByFrame = numpy.zeros((self.radacHeaderObj.npulses))
                     self.beamCodesFromFile = dataset.value
                     #beamcodeByFrame[range1] = dataset[idrecord - 1, range1]
                     #beamcodeByFrame[range2] = dataset[idrecord, range2]
                     beamcodeByFrame[range1] = dataset[idrecord, range1]
                     beamcodeByFrame[range2] = dataset[idrecord, range2]
                     return beamcodeByFrame
                 def __setDataByFrame(self):
                     ndata = 2 # porque es complejo
                     dataByFrame = numpy.zeros((self.radacHeaderObj.npulses, self.radacHeaderObj.nsamples, ndata))
                     return dataByFrame
                 def __readDataSet(self):
                     dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Data')
                     return dataset
                 def __setDataBlock(self,):
                     real = self.dataByFrame[:,:,0] #asumo que 0 es real
                     imag = self.dataByFrame[:,:,1] #asumo que 1 es imaginario
                     datablock = real + imag*1j #armo el complejo
                     return datablock
                 def readSamples_version1(self,idrecord):
                     #estas tres primeras lineas solo se deben ejecutar una vez
                     if self.flagIsNewFile:
                         self.idpulse_range1, self.idpulse_range2 = self.radacHeaderObj.getIndexRangeToPulse(0)
                         self.dataByFrame = self.__setDataByFrame()
                         self.beamCodeByFrame = self.readBeamCode(idrecord, self.idpulse_range1, self.idpulse_range2)
                         self.radacTimeByFrame = self.readRadacTime(idrecord, self.idpulse_range1, self.idpulse_range2)
                         #reading dataset
                         self.dataset = self.__readDataSet()
                     if idrecord == 0:
                         if len(numpy.where(self.dataByFrame!=0.0)[0]) or len(numpy.where(self.dataByFrame!=0.0)[1]) or len(numpy.where(self.dataByFrame!=0.0)[2]):
                             #falta agregar una condicion para datos discontinuos
                             #por defecto une los datos del record anterior
                             self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]
                             #timepulse
                             self.radacTimeByFrame[self.idpulse_range2] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range2]
                         else:
                             self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]
                             self.radacTimeByFrame[self.idpulse_range1] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range1]
                         datablock = self.__setDataBlock()
                         return datablock
                     self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord - 1,self.idpulse_range1, :, :]
                     self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]
                     datablock = self.__setDataBlock()
                     self.flagIsNewFile = 0
                     self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]
                     return datablock
                 def readSamples(self,idrecord):
                     if self.flagIsNewFile:
                         self.dataByFrame = self.__setDataByFrame()
                         self.beamCodeByFrame = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode').value[idrecord, :]
                         #reading ranges
                         self.readRanges()
                         #reading dataset
                         self.dataset = self.__readDataSet()
                     self.flagIsNewFile = 0
                     self.radacTimeByFrame = self.radacHeaderObj.radacTime.value[idrecord, :]
                     self.dataByFrame = self.dataset[idrecord, :, :, :]
                     datablock = self.__setDataBlock()
                     return datablock
                 def readDataBlock(self):
                     #self.datablock = self.readSamples(self.idrecord_count)
                     self.datablock = self.readSamples(self.idrecord_count)
                     #print 'record:', self.idrecord_count
                     self.idrecord_count += 1
                     self.profileIndex = 0
                     if self.idrecord_count >= self.radacHeaderObj.nrecords:
                         self.idrecord_count = 0
                         self.flagIsNewFile = 1
                 def readNextBlock(self):
                     self.readDataBlock()
                     if self.flagIsNewFile:
                         self.__setNextFile()
                     pass
                 def __hasNotDataInBuffer(self):
                     #self.radacHeaderObj.npulses debe ser otra variable para considerar el numero de pulsos a tomar en el primer y ultimo record
                     if self.profileIndex >= self.radacHeaderObj.npulses:
                         return 1
                     return 0
                 def printUTC(self):
                     print self.dataOut.utctime
                     print ''
                 def setObjProperties(self):
                     self.dataOut.heightList = self.rangeFromFile/1000.0 #km
                     self.dataOut.nProfiles = self.radacHeaderObj.npulses
+                    self.dataOut.ippSeconds = self.ippSeconds_fromfile
                     self.dataOut.timeInterval = self.dataOut.ippSeconds * self.dataOut.nCohInt
+                    self.dataOut.frequency = self.frequency_h5file
                     self.dataOut.nBaud = None
                     self.dataOut.nCode = None
                     self.dataOut.code = None
                     self.dataOut.beamCodeDict = self.beamCodeDict
                     self.dataOut.beamRangeDict = self.beamRangeDict
                 def getData(self):
                     if self.flagNoMoreFiles:
                         self.dataOut.flagNoData = True
                         print 'Process finished'
                         return 0
                     if self.__hasNotDataInBuffer():
                         self.readNextBlock()
             #             if not( self.readNextBlock() ):
             #                 return 0
             #             self.getFirstHeader()
                     if self.datablock == None: # setear esta condicion cuando no hayan datos por leers
                         self.dataOut.flagNoData = True
                         return 0
                     self.dataOut.data = numpy.reshape(self.datablock[self.profileIndex,:],(1,-1))
                     self.dataOut.utctime = self.radacTimeByFrame[self.profileIndex]
                     self.dataOut.flagNoData = False
                     self.profileIndex += 1
                     return self.dataOut.data
                 def run(self, **kwargs):
                     if not(self.isConfig):
                         self.setup(**kwargs)
                         self.setObjProperties()
                         self.isConfig = True
                     self.getData()

1

'''

1

'''

2

3

$Author: murco $

3

$Author: murco $

4

$Id: JRODataIO.py 169 2012-11-19 21:57:03Z murco $

4

$Id: JRODataIO.py 169 2012-11-19 21:57:03Z murco $

5

'''

5

'''

6

7

import os, sys

7

import os, sys

8

import glob

8

import glob

9

import time

9

import time

10

import numpy

10

import numpy

11

import fnmatch

11

import fnmatch

12

import time, datetime

12

import time, datetime

13

import h5py

13

import h5py

14

import re

14

from xml.etree.ElementTree import Element, SubElement, ElementTree

15

from xml.etree.ElementTree import Element, SubElement, ElementTree

15

try:

16

try:

16

import pyfits

17

import pyfits

17

except:

18

except:

18

print "pyfits module has not been imported, it should be installed to save files in fits format"

19

print "pyfits module has not been imported, it should be installed to save files in fits format"

19

20

from jrodata import *

21

from jrodata import *

21

from jroheaderIO import *

22

from jroheaderIO import *

22

from jroprocessing import *

23

from jroprocessing import *

23

24

LOCALTIME = True #-18000

25

LOCALTIME = True #-18000

25

26

def isNumber(str):

27

def isNumber(str):

27

"""

28

"""

28

Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.

29

Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.

29

30

Excepciones:

31

Excepciones:

31

Si un determinado string no puede ser convertido a numero

32

Si un determinado string no puede ser convertido a numero

32

Input:

33

Input:

33

str, string al cual se le analiza para determinar si convertible a un numero o no

34

str, string al cual se le analiza para determinar si convertible a un numero o no

34

35

Return:

36

Return:

36

True : si el string es uno numerico

37

True : si el string es uno numerico

37

False : no es un string numerico

38

False : no es un string numerico

38

"""

39

"""

39

try:

40

try:

40

float( str )

41

float( str )

41

return True

42

return True

42

except:

43

except:

43

return False

44

return False

44

45

def isThisFileinRange(filename, startUTSeconds, endUTSeconds):

46

def isThisFileinRange(filename, startUTSeconds, endUTSeconds):

46

"""

47

"""

47

Esta funcion determina si un archivo de datos se encuentra o no dentro del rango de fecha especificado.

48

Esta funcion determina si un archivo de datos se encuentra o no dentro del rango de fecha especificado.

48

49

Inputs:

50

Inputs:

50

filename : nombre completo del archivo de datos en formato Jicamarca (.r)

51

filename : nombre completo del archivo de datos en formato Jicamarca (.r)

51

52

startUTSeconds : fecha inicial del rango seleccionado. La fecha esta dada en

53

startUTSeconds : fecha inicial del rango seleccionado. La fecha esta dada en

53

segundos contados desde 01/01/1970.

54

segundos contados desde 01/01/1970.

54

endUTSeconds : fecha final del rango seleccionado. La fecha esta dada en

55

endUTSeconds : fecha final del rango seleccionado. La fecha esta dada en

55

segundos contados desde 01/01/1970.

56

segundos contados desde 01/01/1970.

56

57

Return:

58

Return:

58

Boolean : Retorna True si el archivo de datos contiene datos en el rango de

59

Boolean : Retorna True si el archivo de datos contiene datos en el rango de

59

fecha especificado, de lo contrario retorna False.

60

fecha especificado, de lo contrario retorna False.

60

61

Excepciones:

62

Excepciones:

62

Si el archivo no existe o no puede ser abierto

63

Si el archivo no existe o no puede ser abierto

63

Si la cabecera no puede ser leida.

64

Si la cabecera no puede ser leida.

64

65

"""

66

"""

66

basicHeaderObj = BasicHeader(LOCALTIME)

67

basicHeaderObj = BasicHeader(LOCALTIME)

67

68

try:

69

try:

69

fp = open(filename,'rb')

70

fp = open(filename,'rb')

70

except:

71

except:

71

raise IOError, "The file %s can't be opened" %(filename)

72

raise IOError, "The file %s can't be opened" %(filename)

72

73

sts = basicHeaderObj.read(fp)

74

sts = basicHeaderObj.read(fp)

74

fp.close()

75

fp.close()

75

76

if not(sts):

77

if not(sts):

77

print "Skipping the file %s because it has not a valid header" %(filename)

78

print "Skipping the file %s because it has not a valid header" %(filename)

78

return 0

79

return 0

79

80

if not ((startUTSeconds <= basicHeaderObj.utc) and (endUTSeconds > basicHeaderObj.utc)):

81

if not ((startUTSeconds <= basicHeaderObj.utc) and (endUTSeconds > basicHeaderObj.utc)):

81

return 0

82

return 0

82

83

return 1

84

return 1

84

85

def isFileinThisTime(filename, startTime, endTime):

86

def isFileinThisTime(filename, startTime, endTime):

86

"""

87

"""

87

Retorna 1 si el archivo de datos se encuentra dentro del rango de horas especificado.

88

Retorna 1 si el archivo de datos se encuentra dentro del rango de horas especificado.

88

89

Inputs:

90

Inputs:

90

filename : nombre completo del archivo de datos en formato Jicamarca (.r)

91

filename : nombre completo del archivo de datos en formato Jicamarca (.r)

91

92

startTime : tiempo inicial del rango seleccionado en formato datetime.time

93

startTime : tiempo inicial del rango seleccionado en formato datetime.time

93

94

endTime : tiempo final del rango seleccionado en formato datetime.time

95

endTime : tiempo final del rango seleccionado en formato datetime.time

95

96

Return:

97

Return:

97

Boolean : Retorna True si el archivo de datos contiene datos en el rango de

98

Boolean : Retorna True si el archivo de datos contiene datos en el rango de

98

fecha especificado, de lo contrario retorna False.

99

fecha especificado, de lo contrario retorna False.

99

100

Excepciones:

101

Excepciones:

101

Si el archivo no existe o no puede ser abierto

102

Si el archivo no existe o no puede ser abierto

102

Si la cabecera no puede ser leida.

103

Si la cabecera no puede ser leida.

103

104

"""

105

"""

105

106

107

try:

108

try:

108

fp = open(filename,'rb')

109

fp = open(filename,'rb')

109

except:

110

except:

110

raise IOError, "The file %s can't be opened" %(filename)

111

raise IOError, "The file %s can't be opened" %(filename)

111

112

basicHeaderObj = BasicHeader(LOCALTIME)

113

basicHeaderObj = BasicHeader(LOCALTIME)

113

sts = basicHeaderObj.read(fp)

114

sts = basicHeaderObj.read(fp)

114

fp.close()

115

fp.close()

115

116

thisDatetime = basicHeaderObj.datatime

117

thisDatetime = basicHeaderObj.datatime

117

thisTime = basicHeaderObj.datatime.time()

118

thisTime = basicHeaderObj.datatime.time()

118

119

if not(sts):

120

if not(sts):

120

print "Skipping the file %s because it has not a valid header" %(filename)

121

print "Skipping the file %s because it has not a valid header" %(filename)

121

return None

122

return None

122

123

if not ((startTime <= thisTime) and (endTime > thisTime)):

124

if not ((startTime <= thisTime) and (endTime > thisTime)):

124

return None

125

return None

125

126

return thisDatetime

127

return thisDatetime

127

128

def getFileFromSet(path,ext,set):

129

def getFileFromSet(path,ext,set):

129

validFilelist = []

130

validFilelist = []

130

fileList = os.listdir(path)

131

fileList = os.listdir(path)

131

132

# 0 1234 567 89A BCDE

133

# 0 1234 567 89A BCDE

133

# H YYYY DDD SSS .ext

134

# H YYYY DDD SSS .ext

134

135

for file in fileList:

136

for file in fileList:

136

try:

137

try:

137

year = int(file[1:5])

138

year = int(file[1:5])

138

doy = int(file[5:8])

139

doy = int(file[5:8])

139

140

141

except:

142

except:

142

continue

143

continue

143

144

if (os.path.splitext(file)[-1].lower() != ext.lower()):

145

if (os.path.splitext(file)[-1].lower() != ext.lower()):

145

continue

146

continue

146

147

validFilelist.append(file)

148

validFilelist.append(file)

148

149

myfile = fnmatch.filter(validFilelist,'*%4.4d%3.3d%3.3d*'%(year,doy,set))

150

myfile = fnmatch.filter(validFilelist,'*%4.4d%3.3d%3.3d*'%(year,doy,set))

150

151

if len(myfile)!= 0:

152

if len(myfile)!= 0:

152

return myfile[0]

153

return myfile[0]

153

else:

154

else:

154

filename = '*%4.4d%3.3d%3.3d%s'%(year,doy,set,ext.lower())

155

filename = '*%4.4d%3.3d%3.3d%s'%(year,doy,set,ext.lower())

155

print 'the filename %s does not exist'%filename

156

print 'the filename %s does not exist'%filename

156

print '...going to the last file: '

157

print '...going to the last file: '

157

158

if validFilelist:

159

if validFilelist:

159

validFilelist = sorted( validFilelist, key=str.lower )

160

validFilelist = sorted( validFilelist, key=str.lower )

160

return validFilelist[-1]

161

return validFilelist[-1]

161

162

return None

163

return None

163

164

165

def getlastFileFromPath(path, ext):

166

def getlastFileFromPath(path, ext):

166

"""

167

"""

167

Depura el fileList dejando solo los que cumplan el formato de "PYYYYDDDSSS.ext"

168

Depura el fileList dejando solo los que cumplan el formato de "PYYYYDDDSSS.ext"

168

al final de la depuracion devuelve el ultimo file de la lista que quedo.

169

al final de la depuracion devuelve el ultimo file de la lista que quedo.

169

170

Input:

171

Input:

171

fileList : lista conteniendo todos los files (sin path) que componen una determinada carpeta

172

fileList : lista conteniendo todos los files (sin path) que componen una determinada carpeta

172

ext : extension de los files contenidos en una carpeta

173

ext : extension de los files contenidos en una carpeta

173

174

Return:

175

Return:

175

El ultimo file de una determinada carpeta, no se considera el path.

176

El ultimo file de una determinada carpeta, no se considera el path.

176

"""

177

"""

177

validFilelist = []

178

validFilelist = []

178

fileList = os.listdir(path)

179

fileList = os.listdir(path)

179

180

# 0 1234 567 89A BCDE

181

# 0 1234 567 89A BCDE

181

# H YYYY DDD SSS .ext

182

# H YYYY DDD SSS .ext

182

183

for file in fileList:

184

for file in fileList:

184

try:

185

try:

185

year = int(file[1:5])

186

year = int(file[1:5])

186

doy = int(file[5:8])

187

doy = int(file[5:8])

187

188

189

except:

190

except:

190

continue

191

continue

191

192

if (os.path.splitext(file)[-1].lower() != ext.lower()):

193

if (os.path.splitext(file)[-1].lower() != ext.lower()):

193

continue

194

continue

194

195

validFilelist.append(file)

196

validFilelist.append(file)

196

197

if validFilelist:

198

if validFilelist:

198

validFilelist = sorted( validFilelist, key=str.lower )

199

validFilelist = sorted( validFilelist, key=str.lower )

199

return validFilelist[-1]

200

return validFilelist[-1]

200

201

return None

202

return None

202

203

def checkForRealPath(path, foldercounter, year, doy, set, ext):

204

def checkForRealPath(path, foldercounter, year, doy, set, ext):

204

"""

205

"""

205

Por ser Linux Case Sensitive entonces checkForRealPath encuentra el nombre correcto de un path,

206

Por ser Linux Case Sensitive entonces checkForRealPath encuentra el nombre correcto de un path,

206

Prueba por varias combinaciones de nombres entre mayusculas y minusculas para determinar

207

Prueba por varias combinaciones de nombres entre mayusculas y minusculas para determinar

207

el path exacto de un determinado file.

208

el path exacto de un determinado file.

208

209

Example :

210

Example :

210

nombre correcto del file es .../.../D2009307/P2009307367.ext

211

nombre correcto del file es .../.../D2009307/P2009307367.ext

211

212

Entonces la funcion prueba con las siguientes combinaciones

213

Entonces la funcion prueba con las siguientes combinaciones

213

.../.../y2009307367.ext

214

.../.../y2009307367.ext

214

.../.../Y2009307367.ext

215

.../.../Y2009307367.ext

215

.../.../x2009307/y2009307367.ext

216

.../.../x2009307/y2009307367.ext

216

.../.../x2009307/Y2009307367.ext

217

.../.../x2009307/Y2009307367.ext

217

.../.../X2009307/y2009307367.ext

218

.../.../X2009307/y2009307367.ext

218

.../.../X2009307/Y2009307367.ext

219

.../.../X2009307/Y2009307367.ext

219

siendo para este caso, la ultima combinacion de letras, identica al file buscado

220

siendo para este caso, la ultima combinacion de letras, identica al file buscado

220

221

Return:

222

Return:

222

Si encuentra la cobinacion adecuada devuelve el path completo y el nombre del file

223

Si encuentra la cobinacion adecuada devuelve el path completo y el nombre del file

223

caso contrario devuelve None como path y el la ultima combinacion de nombre en mayusculas

224

caso contrario devuelve None como path y el la ultima combinacion de nombre en mayusculas

224

para el filename

225

para el filename

225

"""

226

"""

226

fullfilename = None

227

fullfilename = None

227

find_flag = False

228

find_flag = False

228

filename = None

229

filename = None

229

230

prefixDirList = [None,'d','D']

231

prefixDirList = [None,'d','D']

231

if ext.lower() == ".r": #voltage

232

if ext.lower() == ".r": #voltage

232

prefixFileList = ['d','D']

233

prefixFileList = ['d','D']

233

elif ext.lower() == ".pdata": #spectra

234

elif ext.lower() == ".pdata": #spectra

234

prefixFileList = ['p','P']

235

prefixFileList = ['p','P']

235

else:

236

else:

236

return None, filename

237

return None, filename

237

238

#barrido por las combinaciones posibles

239

#barrido por las combinaciones posibles

239

for prefixDir in prefixDirList:

240

for prefixDir in prefixDirList:

240

thispath = path

241

thispath = path

241

if prefixDir != None:

242

if prefixDir != None:

242

#formo el nombre del directorio xYYYYDDD (x=d o x=D)

243

#formo el nombre del directorio xYYYYDDD (x=d o x=D)

243

if foldercounter == 0:

244

if foldercounter == 0:

244

thispath = os.path.join(path, "%s%04d%03d" % ( prefixDir, year, doy ))

245

thispath = os.path.join(path, "%s%04d%03d" % ( prefixDir, year, doy ))

245

else:

246

else:

246

thispath = os.path.join(path, "%s%04d%03d_%02d" % ( prefixDir, year, doy , foldercounter))

247

thispath = os.path.join(path, "%s%04d%03d_%02d" % ( prefixDir, year, doy , foldercounter))

247

for prefixFile in prefixFileList: #barrido por las dos combinaciones posibles de "D"

248

for prefixFile in prefixFileList: #barrido por las dos combinaciones posibles de "D"

248

filename = "%s%04d%03d%03d%s" % ( prefixFile, year, doy, set, ext ) #formo el nombre del file xYYYYDDDSSS.ext

249

filename = "%s%04d%03d%03d%s" % ( prefixFile, year, doy, set, ext ) #formo el nombre del file xYYYYDDDSSS.ext

249

fullfilename = os.path.join( thispath, filename ) #formo el path completo

250

fullfilename = os.path.join( thispath, filename ) #formo el path completo

250

251

if os.path.exists( fullfilename ): #verifico que exista

252

if os.path.exists( fullfilename ): #verifico que exista

252

find_flag = True

253

find_flag = True

253

break

254

break

254

if find_flag:

255

if find_flag:

255

break

256

break

256

257

if not(find_flag):

258

if not(find_flag):

258

return None, filename

259

return None, filename

259

260

return fullfilename, filename

261

return fullfilename, filename

261

262

def isDoyFolder(folder):

263

def isDoyFolder(folder):

263

try:

264

try:

264

year = int(folder[1:5])

265

year = int(folder[1:5])

265

except:

266

except:

266

return 0

267

return 0

267

268

try:

269

try:

269

doy = int(folder[5:8])

270

doy = int(folder[5:8])

270

except:

271

except:

271

return 0

272

return 0

272

273

return 1

274

return 1

274

275

class JRODataIO:

276

class JRODataIO:

276

277

c = 3E8

278

c = 3E8

278

279

isConfig = False

280

isConfig = False

280

281

basicHeaderObj = BasicHeader(LOCALTIME)

282

basicHeaderObj = BasicHeader(LOCALTIME)

282

283

systemHeaderObj = SystemHeader()

284

systemHeaderObj = SystemHeader()

284

285

radarControllerHeaderObj = RadarControllerHeader()

286

radarControllerHeaderObj = RadarControllerHeader()

286

287

processingHeaderObj = ProcessingHeader()

288

processingHeaderObj = ProcessingHeader()

288

289

online = 0

290

online = 0

290

291

dtype = None

292

dtype = None

292

293

pathList = []

294

pathList = []

294

295

filenameList = []

296

filenameList = []

296

297

filename = None

298

filename = None

298

299

ext = None

300

ext = None

300

301

flagIsNewFile = 1

302

flagIsNewFile = 1

302

303

flagTimeBlock = 0

304

flagTimeBlock = 0

304

305

flagIsNewBlock = 0

306

flagIsNewBlock = 0

306

307

fp = None

308

fp = None

308

309

firstHeaderSize = 0

310

firstHeaderSize = 0

310

311

basicHeaderSize = 24

312

basicHeaderSize = 24

312

313

versionFile = 1103

314

versionFile = 1103

314

315

fileSize = None

316

fileSize = None

316

317

ippSeconds = None

318

ippSeconds = None

318

319

fileSizeByHeader = None

320

fileSizeByHeader = None

320

321

fileIndex = None

322

fileIndex = None

322

323

profileIndex = None

324

profileIndex = None

324

325

blockIndex = None

326

blockIndex = None

326

327

nTotalBlocks = None

328

nTotalBlocks = None

328

329

maxTimeStep = 30

330

maxTimeStep = 30

330

331

lastUTTime = None

332

lastUTTime = None

332

333

datablock = None

334

datablock = None

334

335

dataOut = None

336

dataOut = None

336

337

blocksize = None

338

blocksize = None

338

339

def __init__(self):

340

def __init__(self):

340

341

raise ValueError, "Not implemented"

342

raise ValueError, "Not implemented"

342

343

def run(self):

344

def run(self):

344

345

raise ValueError, "Not implemented"

346

raise ValueError, "Not implemented"

346

347

def getOutput(self):

348

def getOutput(self):

348

349

return self.dataOut

350

return self.dataOut

350

351

class JRODataReader(JRODataIO, ProcessingUnit):

352

class JRODataReader(JRODataIO, ProcessingUnit):

352

353

nReadBlocks = 0

354

nReadBlocks = 0

354

355

delay = 10 #number of seconds waiting a new file

356

delay = 10 #number of seconds waiting a new file

356

357

nTries = 3 #quantity tries

358

nTries = 3 #quantity tries

358

359

nFiles = 3 #number of files for searching

360

nFiles = 3 #number of files for searching

360

361

path = None

362

path = None

362

363

foldercounter = 0

364

foldercounter = 0

364

365

flagNoMoreFiles = 0

366

flagNoMoreFiles = 0

366

367

datetimeList = []

368

datetimeList = []

368

369

__isFirstTimeOnline = 1

370

__isFirstTimeOnline = 1

370

371

__printInfo = True

372

__printInfo = True

372

373

profileIndex = None

374

profileIndex = None

374

375

def __init__(self):

376

def __init__(self):

376

377

"""

378

"""

378

379

"""

380

"""

380

381

raise ValueError, "This method has not been implemented"

382

raise ValueError, "This method has not been implemented"

382

383

384

def createObjByDefault(self):

385

def createObjByDefault(self):

385

"""

386

"""

386

387

"""

388

"""

388

raise ValueError, "This method has not been implemented"

389

raise ValueError, "This method has not been implemented"

389

390

def getBlockDimension(self):

391

def getBlockDimension(self):

391

392

raise ValueError, "No implemented"

393

raise ValueError, "No implemented"

393

394

def __searchFilesOffLine(self,

395

def __searchFilesOffLine(self,

395

path,

396

path,

396

startDate,

397

startDate,

397

endDate,

398

endDate,

398

startTime=datetime.time(0,0,0),

399

startTime=datetime.time(0,0,0),

399

endTime=datetime.time(23,59,59),

400

endTime=datetime.time(23,59,59),

400

set=None,

401

set=None,

401

expLabel='',

402

expLabel='',

402

ext='.r',

403

ext='.r',

403

walk=True):

404

walk=True):

404

405

pathList = []

406

pathList = []

406

407

if not walk:

408

if not walk:

408

#pathList.append(path)

409

#pathList.append(path)

409

multi_path = path.split(',')

410

multi_path = path.split(',')

410

for single_path in multi_path:

411

for single_path in multi_path:

411

pathList.append(single_path)

412

pathList.append(single_path)

412

413

else:

414

else:

414

#dirList = []

415

#dirList = []

415

multi_path = path.split(',')

416

multi_path = path.split(',')

416

for single_path in multi_path:

417

for single_path in multi_path:

417

dirList = []

418

dirList = []

418

for thisPath in os.listdir(single_path):

419

for thisPath in os.listdir(single_path):

419

if not os.path.isdir(os.path.join(single_path,thisPath)):

420

if not os.path.isdir(os.path.join(single_path,thisPath)):

420

continue

421

continue

421

if not isDoyFolder(thisPath):

422

if not isDoyFolder(thisPath):

422

continue

423

continue

423

424

dirList.append(thisPath)

425

dirList.append(thisPath)

425

426

if not(dirList):

427

if not(dirList):

427

return None, None

428

return None, None

428

429

thisDate = startDate

430

thisDate = startDate

430

431

while(thisDate <= endDate):

432

while(thisDate <= endDate):

432

year = thisDate.timetuple().tm_year

433

year = thisDate.timetuple().tm_year

433

doy = thisDate.timetuple().tm_yday

434

doy = thisDate.timetuple().tm_yday

434

435

matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')

436

matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')

436

if len(matchlist) == 0:

437

if len(matchlist) == 0:

437

thisDate += datetime.timedelta(1)

438

thisDate += datetime.timedelta(1)

438

continue

439

continue

439

for match in matchlist:

440

for match in matchlist:

440

pathList.append(os.path.join(single_path,match,expLabel))

441

pathList.append(os.path.join(single_path,match,expLabel))

441

442

thisDate += datetime.timedelta(1)

443

thisDate += datetime.timedelta(1)

443

444

if pathList == []:

445

if pathList == []:

445

print "Any folder was found for the date range: %s-%s" %(startDate, endDate)

446

print "Any folder was found for the date range: %s-%s" %(startDate, endDate)

446

return None, None

447

return None, None

447

448

print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)

449

print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)

449

450

filenameList = []

451

filenameList = []

451

datetimeList = []

452

datetimeList = []

452

pathDict = {}

453

pathDict = {}

453

filenameList_to_sort = []

454

filenameList_to_sort = []

454

455

for i in range(len(pathList)):

456

for i in range(len(pathList)):

456

457

thisPath = pathList[i]

458

thisPath = pathList[i]

458

459

fileList = glob.glob1(thisPath, "*%s" %ext)

460

fileList = glob.glob1(thisPath, "*%s" %ext)

460

fileList.sort()

461

fileList.sort()

461

pathDict.setdefault(fileList[0])

462

pathDict.setdefault(fileList[0])

462

pathDict[fileList[0]] = i

463

pathDict[fileList[0]] = i

463

filenameList_to_sort.append(fileList[0])

464

filenameList_to_sort.append(fileList[0])

464

465

filenameList_to_sort.sort()

466

filenameList_to_sort.sort()

466

467

for file in filenameList_to_sort:

468

for file in filenameList_to_sort:

468

thisPath = pathList[pathDict[file]]

469

thisPath = pathList[pathDict[file]]

469

470

fileList = glob.glob1(thisPath, "*%s" %ext)

471

fileList = glob.glob1(thisPath, "*%s" %ext)

471

fileList.sort()

472

fileList.sort()

472

473

for file in fileList:

474

for file in fileList:

474

475

filename = os.path.join(thisPath,file)

476

filename = os.path.join(thisPath,file)

476

thisDatetime = isFileinThisTime(filename, startTime, endTime)

477

thisDatetime = isFileinThisTime(filename, startTime, endTime)

477

478

if not(thisDatetime):

479

if not(thisDatetime):

479

continue

480

continue

480

481

filenameList.append(filename)

482

filenameList.append(filename)

482

datetimeList.append(thisDatetime)

483

datetimeList.append(thisDatetime)

483

484

if not(filenameList):

485

if not(filenameList):

485

print "Any file was found for the time range %s - %s" %(startTime, endTime)

486

print "Any file was found for the time range %s - %s" %(startTime, endTime)

486

return None, None

487

return None, None

487

488

print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)

489

print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)

489

print

490

print

490

491

for i in range(len(filenameList)):

492

for i in range(len(filenameList)):

492

print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())

493

print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())

493

494

self.filenameList = filenameList

495

self.filenameList = filenameList

495

self.datetimeList = datetimeList

496

self.datetimeList = datetimeList

496

497

return pathList, filenameList

498

return pathList, filenameList

498

499

def __searchFilesOnLine(self, path, expLabel = "", ext = None, walk=True, set=None):

500

def __searchFilesOnLine(self, path, expLabel = "", ext = None, walk=True, set=None):

500

501

"""

502

"""

502

Busca el ultimo archivo de la ultima carpeta (determinada o no por startDateTime) y

503

Busca el ultimo archivo de la ultima carpeta (determinada o no por startDateTime) y

503

devuelve el archivo encontrado ademas de otros datos.

504

devuelve el archivo encontrado ademas de otros datos.

504

505

Input:

506

Input:

506

path : carpeta donde estan contenidos los files que contiene data

507

path : carpeta donde estan contenidos los files que contiene data

507

508

expLabel : Nombre del subexperimento (subfolder)

509

expLabel : Nombre del subexperimento (subfolder)

509

510

ext : extension de los files

511

ext : extension de los files

511

512

walk : Si es habilitado no realiza busquedas dentro de los ubdirectorios (doypath)

513

walk : Si es habilitado no realiza busquedas dentro de los ubdirectorios (doypath)

513

514

Return:

515

Return:

515

directory : eL directorio donde esta el file encontrado

516

directory : eL directorio donde esta el file encontrado

516

filename : el ultimo file de una determinada carpeta

517

filename : el ultimo file de una determinada carpeta

517

year : el anho

518

year : el anho

518

doy : el numero de dia del anho

519

doy : el numero de dia del anho

519

set : el set del archivo

520

set : el set del archivo

520

521

522

"""

523

"""

523

dirList = []

524

dirList = []

524

525

if not walk:

526

if not walk:

526

fullpath = path

527

fullpath = path

527

foldercounter = 0

528

foldercounter = 0

528

else:

529

else:

529

#Filtra solo los directorios

530

#Filtra solo los directorios

530

for thisPath in os.listdir(path):

531

for thisPath in os.listdir(path):

531

if not os.path.isdir(os.path.join(path,thisPath)):

532

if not os.path.isdir(os.path.join(path,thisPath)):

532

continue

533

continue

533

if not isDoyFolder(thisPath):

534

if not isDoyFolder(thisPath):

534

continue

535

continue

535

536

dirList.append(thisPath)

537

dirList.append(thisPath)

537

538

if not(dirList):

539

if not(dirList):

539

return None, None, None, None, None, None

540

return None, None, None, None, None, None

540

541

dirList = sorted( dirList, key=str.lower )

542

dirList = sorted( dirList, key=str.lower )

542

543

doypath = dirList[-1]

544

doypath = dirList[-1]

544

foldercounter = int(doypath.split('_')[1]) if len(doypath.split('_'))>1 else 0

545

foldercounter = int(doypath.split('_')[1]) if len(doypath.split('_'))>1 else 0

545

fullpath = os.path.join(path, doypath, expLabel)

546

fullpath = os.path.join(path, doypath, expLabel)

546

547

548

print "%s folder was found: " %(fullpath )

549

print "%s folder was found: " %(fullpath )

549

550

if set == None:

551

if set == None:

551

filename = getlastFileFromPath(fullpath, ext)

552

filename = getlastFileFromPath(fullpath, ext)

552

else:

553

else:

553

filename = getFileFromSet(fullpath, ext, set)

554

filename = getFileFromSet(fullpath, ext, set)

554

555

if not(filename):

556

if not(filename):

556

return None, None, None, None, None, None

557

return None, None, None, None, None, None

557

558

print "%s file was found" %(filename)

559

print "%s file was found" %(filename)

559

560

if not(self.__verifyFile(os.path.join(fullpath, filename))):

561

if not(self.__verifyFile(os.path.join(fullpath, filename))):

561

return None, None, None, None, None, None

562

return None, None, None, None, None, None

562

563

year = int( filename[1:5] )

564

year = int( filename[1:5] )

564

doy = int( filename[5:8] )

565

doy = int( filename[5:8] )

565

set = int( filename[8:11] )

566

set = int( filename[8:11] )

566

567

return fullpath, foldercounter, filename, year, doy, set

568

return fullpath, foldercounter, filename, year, doy, set

568

569

def __setNextFileOffline(self):

570

def __setNextFileOffline(self):

570

571

idFile = self.fileIndex

572

idFile = self.fileIndex

572

573

while (True):

574

while (True):

574

idFile += 1

575

idFile += 1

575

if not(idFile < len(self.filenameList)):

576

if not(idFile < len(self.filenameList)):

576

self.flagNoMoreFiles = 1

577

self.flagNoMoreFiles = 1

577

print "No more Files"

578

print "No more Files"

578

return 0

579

return 0

579

580

filename = self.filenameList[idFile]

581

filename = self.filenameList[idFile]

581

582

if not(self.__verifyFile(filename)):

583

if not(self.__verifyFile(filename)):

583

continue

584

continue

584

585

fileSize = os.path.getsize(filename)

586

fileSize = os.path.getsize(filename)

586

fp = open(filename,'rb')

587

fp = open(filename,'rb')

587

break

588

break

588

589

self.flagIsNewFile = 1

590

self.flagIsNewFile = 1

590

self.fileIndex = idFile

591

self.fileIndex = idFile

591

self.filename = filename

592

self.filename = filename

592

self.fileSize = fileSize

593

self.fileSize = fileSize

593

self.fp = fp

594

self.fp = fp

594

595

print "Setting the file: %s"%self.filename

596

print "Setting the file: %s"%self.filename

596

597

return 1

598

return 1

598

599

def __setNextFileOnline(self):

600

def __setNextFileOnline(self):

600

"""

601

"""

601

Busca el siguiente file que tenga suficiente data para ser leida, dentro de un folder especifico, si

602

Busca el siguiente file que tenga suficiente data para ser leida, dentro de un folder especifico, si

602

no encuentra un file valido espera un tiempo determinado y luego busca en los posibles n files

603

no encuentra un file valido espera un tiempo determinado y luego busca en los posibles n files

603

siguientes.

604

siguientes.

604

605

Affected:

606

Affected:

606

self.flagIsNewFile

607

self.flagIsNewFile

607

self.filename

608

self.filename

608

self.fileSize

609

self.fileSize

609

self.fp

610

self.fp

610

self.set

611

self.set

611

self.flagNoMoreFiles

612

self.flagNoMoreFiles

612

613

Return:

614

Return:

614

0 : si luego de una busqueda del siguiente file valido este no pudo ser encontrado

615

0 : si luego de una busqueda del siguiente file valido este no pudo ser encontrado

615

1 : si el file fue abierto con exito y esta listo a ser leido

616

1 : si el file fue abierto con exito y esta listo a ser leido

616

617

Excepciones:

618

Excepciones:

618

Si un determinado file no puede ser abierto

619

Si un determinado file no puede ser abierto

619

"""

620

"""

620

nFiles = 0

621

nFiles = 0

621

fileOk_flag = False

622

fileOk_flag = False

622

firstTime_flag = True

623

firstTime_flag = True

623

624

self.set += 1

625

self.set += 1

625

626

if self.set > 999:

627

if self.set > 999:

627

self.set = 0

628

self.set = 0

628

self.foldercounter += 1

629

self.foldercounter += 1

629

630

#busca el 1er file disponible

631

#busca el 1er file disponible

631

fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )

632

fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )

632

if fullfilename:

633

if fullfilename:

633

if self.__verifyFile(fullfilename, False):

634

if self.__verifyFile(fullfilename, False):

634

fileOk_flag = True

635

fileOk_flag = True

635

636

#si no encuentra un file entonces espera y vuelve a buscar

637

#si no encuentra un file entonces espera y vuelve a buscar

637

if not(fileOk_flag):

638

if not(fileOk_flag):

638

for nFiles in range(self.nFiles+1): #busco en los siguientes self.nFiles+1 files posibles

639

for nFiles in range(self.nFiles+1): #busco en los siguientes self.nFiles+1 files posibles

639

640

if firstTime_flag: #si es la 1era vez entonces hace el for self.nTries veces

641

if firstTime_flag: #si es la 1era vez entonces hace el for self.nTries veces

641

tries = self.nTries

642

tries = self.nTries

642

else:

643

else:

643

tries = 1 #si no es la 1era vez entonces solo lo hace una vez

644

tries = 1 #si no es la 1era vez entonces solo lo hace una vez

644

645

for nTries in range( tries ):

646

for nTries in range( tries ):

646

if firstTime_flag:

647

if firstTime_flag:

647

print "\tWaiting %0.2f sec for the file \"%s\" , try %03d ..." % ( self.delay, filename, nTries+1 )

648

print "\tWaiting %0.2f sec for the file \"%s\" , try %03d ..." % ( self.delay, filename, nTries+1 )

648

time.sleep( self.delay )

649

time.sleep( self.delay )

649

else:

650

else:

650

print "\tSearching next \"%s%04d%03d%03d%s\" file ..." % (self.optchar, self.year, self.doy, self.set, self.ext)

651

print "\tSearching next \"%s%04d%03d%03d%s\" file ..." % (self.optchar, self.year, self.doy, self.set, self.ext)

651

652

fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )

653

fullfilename, filename = checkForRealPath( self.path, self.foldercounter, self.year, self.doy, self.set, self.ext )

653

if fullfilename:

654

if fullfilename:

654

if self.__verifyFile(fullfilename):

655

if self.__verifyFile(fullfilename):

655

fileOk_flag = True

656

fileOk_flag = True

656

break

657

break

657

658

if fileOk_flag:

659

if fileOk_flag:

659

break

660

break

660

661

firstTime_flag = False

662

firstTime_flag = False

662

663

print "\tSkipping the file \"%s\" due to this file doesn't exist" % filename

664

print "\tSkipping the file \"%s\" due to this file doesn't exist" % filename

664

self.set += 1

665

self.set += 1

665

666

if nFiles == (self.nFiles-1): #si no encuentro el file buscado cambio de carpeta y busco en la siguiente carpeta

667

if nFiles == (self.nFiles-1): #si no encuentro el file buscado cambio de carpeta y busco en la siguiente carpeta

667

self.set = 0

668

self.set = 0

668

self.doy += 1

669

self.doy += 1

669

self.foldercounter = 0

670

self.foldercounter = 0

670

671

if fileOk_flag:

672

if fileOk_flag:

672

self.fileSize = os.path.getsize( fullfilename )

673

self.fileSize = os.path.getsize( fullfilename )

673

self.filename = fullfilename

674

self.filename = fullfilename

674

self.flagIsNewFile = 1

675

self.flagIsNewFile = 1

675

if self.fp != None: self.fp.close()

676

if self.fp != None: self.fp.close()

676

self.fp = open(fullfilename, 'rb')

677

self.fp = open(fullfilename, 'rb')

677

self.flagNoMoreFiles = 0

678

self.flagNoMoreFiles = 0

678

print 'Setting the file: %s' % fullfilename

679

print 'Setting the file: %s' % fullfilename

679

else:

680

else:

680

self.fileSize = 0

681

self.fileSize = 0

681

self.filename = None

682

self.filename = None

682

self.flagIsNewFile = 0

683

self.flagIsNewFile = 0

683

self.fp = None

684

self.fp = None

684

self.flagNoMoreFiles = 1

685

self.flagNoMoreFiles = 1

685

print 'No more Files'

686

print 'No more Files'

686

687

return fileOk_flag

688

return fileOk_flag

688

689

690

def setNextFile(self):

691

def setNextFile(self):

691

if self.fp != None:

692

if self.fp != None:

692

self.fp.close()

693

self.fp.close()

693

694

if self.online:

695

if self.online:

695

newFile = self.__setNextFileOnline()

696

newFile = self.__setNextFileOnline()

696

else:

697

else:

697

newFile = self.__setNextFileOffline()

698

newFile = self.__setNextFileOffline()

698

699

if not(newFile):

700

if not(newFile):

700

return 0

701

return 0

701

702

self.__readFirstHeader()

703

self.__readFirstHeader()

703

self.nReadBlocks = 0

704

self.nReadBlocks = 0

704

return 1

705

return 1

705

706

def __waitNewBlock(self):

707

def __waitNewBlock(self):

707

"""

708

"""

708

Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.

709

Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.

709

710

Si el modo de lectura es OffLine siempre retorn 0

711

Si el modo de lectura es OffLine siempre retorn 0

711

"""

712

"""

712

if not self.online:

713

if not self.online:

713

return 0

714

return 0

714

715

if (self.nReadBlocks >= self.processingHeaderObj.dataBlocksPerFile):

716

if (self.nReadBlocks >= self.processingHeaderObj.dataBlocksPerFile):

716

return 0

717

return 0

717

718

currentPointer = self.fp.tell()

719

currentPointer = self.fp.tell()

719

720

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

721

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

721

722

for nTries in range( self.nTries ):

723

for nTries in range( self.nTries ):

723

724

self.fp.close()

725

self.fp.close()

725

self.fp = open( self.filename, 'rb' )

726

self.fp = open( self.filename, 'rb' )

726

self.fp.seek( currentPointer )

727

self.fp.seek( currentPointer )

727

728

self.fileSize = os.path.getsize( self.filename )

729

self.fileSize = os.path.getsize( self.filename )

729

currentSize = self.fileSize - currentPointer

730

currentSize = self.fileSize - currentPointer

730

731

if ( currentSize >= neededSize ):

732

if ( currentSize >= neededSize ):

732

self.__rdBasicHeader()

733

self.__rdBasicHeader()

733

return 1

734

return 1

734

735

if self.fileSize == self.fileSizeByHeader:

736

if self.fileSize == self.fileSizeByHeader:

736

# self.flagEoF = True

737

# self.flagEoF = True

737

return 0

738

return 0

738

739

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

740

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

740

time.sleep( self.delay )

741

time.sleep( self.delay )

741

742

743

return 0

744

return 0

744

745

def waitDataBlock(self,pointer_location):

746

def waitDataBlock(self,pointer_location):

746

747

currentPointer = pointer_location

748

currentPointer = pointer_location

748

749

neededSize = self.processingHeaderObj.blockSize #+ self.basicHeaderSize

750

neededSize = self.processingHeaderObj.blockSize #+ self.basicHeaderSize

750

751

for nTries in range( self.nTries ):

752

for nTries in range( self.nTries ):

752

self.fp.close()

753

self.fp.close()

753

self.fp = open( self.filename, 'rb' )

754

self.fp = open( self.filename, 'rb' )

754

self.fp.seek( currentPointer )

755

self.fp.seek( currentPointer )

755

756

self.fileSize = os.path.getsize( self.filename )

757

self.fileSize = os.path.getsize( self.filename )

757

currentSize = self.fileSize - currentPointer

758

currentSize = self.fileSize - currentPointer

758

759

if ( currentSize >= neededSize ):

760

if ( currentSize >= neededSize ):

760

return 1

761

return 1

761

762

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

763

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

763

time.sleep( self.delay )

764

time.sleep( self.delay )

764

765

return 0

766

return 0

766

767

768

def __jumpToLastBlock(self):

769

def __jumpToLastBlock(self):

769

770

if not(self.__isFirstTimeOnline):

771

if not(self.__isFirstTimeOnline):

771

return

772

return

772

773

csize = self.fileSize - self.fp.tell()

774

csize = self.fileSize - self.fp.tell()

774

blocksize = self.processingHeaderObj.blockSize

775

blocksize = self.processingHeaderObj.blockSize

775

776

#salta el primer bloque de datos

777

#salta el primer bloque de datos

777

if csize > self.processingHeaderObj.blockSize:

778

if csize > self.processingHeaderObj.blockSize:

778

self.fp.seek(self.fp.tell() + blocksize)

779

self.fp.seek(self.fp.tell() + blocksize)

779

else:

780

else:

780

return

781

return

781

782

csize = self.fileSize - self.fp.tell()

783

csize = self.fileSize - self.fp.tell()

783

neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize

784

neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize

784

while True:

785

while True:

785

786

if self.fp.tell()<self.fileSize:

787

if self.fp.tell()<self.fileSize:

787

self.fp.seek(self.fp.tell() + neededsize)

788

self.fp.seek(self.fp.tell() + neededsize)

788

else:

789

else:

789

self.fp.seek(self.fp.tell() - neededsize)

790

self.fp.seek(self.fp.tell() - neededsize)

790

break

791

break

791

792

# csize = self.fileSize - self.fp.tell()

793

# csize = self.fileSize - self.fp.tell()

793

# neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize

794

# neededsize = self.processingHeaderObj.blockSize + self.basicHeaderSize

794

# factor = int(csize/neededsize)

795

# factor = int(csize/neededsize)

795

# if factor > 0:

796

# if factor > 0:

796

# self.fp.seek(self.fp.tell() + factor*neededsize)

797

# self.fp.seek(self.fp.tell() + factor*neededsize)

797

798

self.flagIsNewFile = 0

799

self.flagIsNewFile = 0

799

self.__isFirstTimeOnline = 0

800

self.__isFirstTimeOnline = 0

800

801

802

def __setNewBlock(self):

803

def __setNewBlock(self):

803

804

if self.fp == None:

805

if self.fp == None:

805

return 0

806

return 0

806

807

if self.online:

808

if self.online:

808

self.__jumpToLastBlock()

809

self.__jumpToLastBlock()

809

810

if self.flagIsNewFile:

811

if self.flagIsNewFile:

811

return 1

812

return 1

812

813

self.lastUTTime = self.basicHeaderObj.utc

814

self.lastUTTime = self.basicHeaderObj.utc

814

currentSize = self.fileSize - self.fp.tell()

815

currentSize = self.fileSize - self.fp.tell()

815

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

816

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

816

817

if (currentSize >= neededSize):

818

if (currentSize >= neededSize):

818

self.__rdBasicHeader()

819

self.__rdBasicHeader()

819

return 1

820

return 1

820

821

if self.__waitNewBlock():

822

if self.__waitNewBlock():

822

return 1

823

return 1

823

824

if not(self.setNextFile()):

825

if not(self.setNextFile()):

825

return 0

826

return 0

826

827

deltaTime = self.basicHeaderObj.utc - self.lastUTTime #

828

deltaTime = self.basicHeaderObj.utc - self.lastUTTime #

828

829

self.flagTimeBlock = 0

830

self.flagTimeBlock = 0

830

831

if deltaTime > self.maxTimeStep:

832

if deltaTime > self.maxTimeStep:

832

self.flagTimeBlock = 1

833

self.flagTimeBlock = 1

833

834

return 1

835

return 1

835

836

837

def readNextBlock(self):

838

def readNextBlock(self):

838

if not(self.__setNewBlock()):

839

if not(self.__setNewBlock()):

839

return 0

840

return 0

840

841

if not(self.readBlock()):

842

if not(self.readBlock()):

842

return 0

843

return 0

843

844

return 1

845

return 1

845

846

def __rdProcessingHeader(self, fp=None):

847

def __rdProcessingHeader(self, fp=None):

847

if fp == None:

848

if fp == None:

848

fp = self.fp

849

fp = self.fp

849

850

self.processingHeaderObj.read(fp)

851

self.processingHeaderObj.read(fp)

851

852

def __rdRadarControllerHeader(self, fp=None):

853

def __rdRadarControllerHeader(self, fp=None):

853

if fp == None:

854

if fp == None:

854

fp = self.fp

855

fp = self.fp

855

856

self.radarControllerHeaderObj.read(fp)

857

self.radarControllerHeaderObj.read(fp)

857

858

def __rdSystemHeader(self, fp=None):

859

def __rdSystemHeader(self, fp=None):

859

if fp == None:

860

if fp == None:

860

fp = self.fp

861

fp = self.fp

861

862

self.systemHeaderObj.read(fp)

863

self.systemHeaderObj.read(fp)

863

864

def __rdBasicHeader(self, fp=None):

865

def __rdBasicHeader(self, fp=None):

865

if fp == None:

866

if fp == None:

866

fp = self.fp

867

fp = self.fp

867

868

self.basicHeaderObj.read(fp)

869

self.basicHeaderObj.read(fp)

869

870

871

def __readFirstHeader(self):

872

def __readFirstHeader(self):

872

self.__rdBasicHeader()

873

self.__rdBasicHeader()

873

self.__rdSystemHeader()

874

self.__rdSystemHeader()

874

self.__rdRadarControllerHeader()

875

self.__rdRadarControllerHeader()

875

self.__rdProcessingHeader()

876

self.__rdProcessingHeader()

876

877

self.firstHeaderSize = self.basicHeaderObj.size

878

self.firstHeaderSize = self.basicHeaderObj.size

878

879

datatype = int(numpy.log2((self.processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))

880

datatype = int(numpy.log2((self.processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))

880

if datatype == 0:

881

if datatype == 0:

881

datatype_str = numpy.dtype([('real','<i1'),('imag','<i1')])

882

datatype_str = numpy.dtype([('real','<i1'),('imag','<i1')])

882

elif datatype == 1:

883

elif datatype == 1:

883

datatype_str = numpy.dtype([('real','<i2'),('imag','<i2')])

884

datatype_str = numpy.dtype([('real','<i2'),('imag','<i2')])

884

elif datatype == 2:

885

elif datatype == 2:

885

datatype_str = numpy.dtype([('real','<i4'),('imag','<i4')])

886

datatype_str = numpy.dtype([('real','<i4'),('imag','<i4')])

886

elif datatype == 3:

887

elif datatype == 3:

887

datatype_str = numpy.dtype([('real','<i8'),('imag','<i8')])

888

datatype_str = numpy.dtype([('real','<i8'),('imag','<i8')])

888

elif datatype == 4:

889

elif datatype == 4:

889

datatype_str = numpy.dtype([('real','<f4'),('imag','<f4')])

890

datatype_str = numpy.dtype([('real','<f4'),('imag','<f4')])

890

elif datatype == 5:

891

elif datatype == 5:

891

datatype_str = numpy.dtype([('real','<f8'),('imag','<f8')])

892

datatype_str = numpy.dtype([('real','<f8'),('imag','<f8')])

892

else:

893

else:

893

raise ValueError, 'Data type was not defined'

894

raise ValueError, 'Data type was not defined'

894

895

self.dtype = datatype_str

896

self.dtype = datatype_str

896

self.ippSeconds = 2 * 1000 * self.radarControllerHeaderObj.ipp / self.c

897

self.ippSeconds = 2 * 1000 * self.radarControllerHeaderObj.ipp / self.c

897

self.fileSizeByHeader = self.processingHeaderObj.dataBlocksPerFile * self.processingHeaderObj.blockSize + self.firstHeaderSize + self.basicHeaderSize*(self.processingHeaderObj.dataBlocksPerFile - 1)

898

self.fileSizeByHeader = self.processingHeaderObj.dataBlocksPerFile * self.processingHeaderObj.blockSize + self.firstHeaderSize + self.basicHeaderSize*(self.processingHeaderObj.dataBlocksPerFile - 1)

898

# self.dataOut.channelList = numpy.arange(self.systemHeaderObj.numChannels)

899

# self.dataOut.channelList = numpy.arange(self.systemHeaderObj.numChannels)

899

# self.dataOut.channelIndexList = numpy.arange(self.systemHeaderObj.numChannels)

900

# self.dataOut.channelIndexList = numpy.arange(self.systemHeaderObj.numChannels)

900

self.getBlockDimension()

901

self.getBlockDimension()

901

902

903

def __verifyFile(self, filename, msgFlag=True):

904

def __verifyFile(self, filename, msgFlag=True):

904

msg = None

905

msg = None

905

try:

906

try:

906

fp = open(filename, 'rb')

907

fp = open(filename, 'rb')

907

currentPosition = fp.tell()

908

currentPosition = fp.tell()

908

except:

909

except:

909

if msgFlag:

910

if msgFlag:

910

print "The file %s can't be opened" % (filename)

911

print "The file %s can't be opened" % (filename)

911

return False

912

return False

912

913

neededSize = self.processingHeaderObj.blockSize + self.firstHeaderSize

914

neededSize = self.processingHeaderObj.blockSize + self.firstHeaderSize

914

915

if neededSize == 0:

916

if neededSize == 0:

916

basicHeaderObj = BasicHeader(LOCALTIME)

917

basicHeaderObj = BasicHeader(LOCALTIME)

917

systemHeaderObj = SystemHeader()

918

systemHeaderObj = SystemHeader()

918

radarControllerHeaderObj = RadarControllerHeader()

919

radarControllerHeaderObj = RadarControllerHeader()

919

processingHeaderObj = ProcessingHeader()

920

processingHeaderObj = ProcessingHeader()

920

921

try:

922

try:

922

if not( basicHeaderObj.read(fp) ): raise IOError

923

if not( basicHeaderObj.read(fp) ): raise IOError

923

if not( systemHeaderObj.read(fp) ): raise IOError

924

if not( systemHeaderObj.read(fp) ): raise IOError

924

if not( radarControllerHeaderObj.read(fp) ): raise IOError

925

if not( radarControllerHeaderObj.read(fp) ): raise IOError

925

if not( processingHeaderObj.read(fp) ): raise IOError

926

if not( processingHeaderObj.read(fp) ): raise IOError

926

data_type = int(numpy.log2((processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))

927

data_type = int(numpy.log2((processingHeaderObj.processFlags & PROCFLAG.DATATYPE_MASK))-numpy.log2(PROCFLAG.DATATYPE_CHAR))

927

928

neededSize = processingHeaderObj.blockSize + basicHeaderObj.size

929

neededSize = processingHeaderObj.blockSize + basicHeaderObj.size

929

930

except:

931

except:

931

if msgFlag:

932

if msgFlag:

932

print "\tThe file %s is empty or it hasn't enough data" % filename

933

print "\tThe file %s is empty or it hasn't enough data" % filename

933

934

fp.close()

935

fp.close()

935

return False

936

return False

936

else:

937

else:

937

msg = "\tSkipping the file %s due to it hasn't enough data" %filename

938

msg = "\tSkipping the file %s due to it hasn't enough data" %filename

938

939

fp.close()

940

fp.close()

940

fileSize = os.path.getsize(filename)

941

fileSize = os.path.getsize(filename)

941

currentSize = fileSize - currentPosition

942

currentSize = fileSize - currentPosition

942

if currentSize < neededSize:

943

if currentSize < neededSize:

943

if msgFlag and (msg != None):

944

if msgFlag and (msg != None):

944

print msg #print"\tSkipping the file %s due to it hasn't enough data" %filename

945

print msg #print"\tSkipping the file %s due to it hasn't enough data" %filename

945

return False

946

return False

946

947

return True

948

return True

948

949

def setup(self,

950

def setup(self,

950

path=None,

951

path=None,

951

startDate=None,

952

startDate=None,

952

endDate=None,

953

endDate=None,

953

startTime=datetime.time(0,0,0),

954

startTime=datetime.time(0,0,0),

954

endTime=datetime.time(23,59,59),

955

endTime=datetime.time(23,59,59),

955

set=None,

956

set=None,

956

expLabel = "",

957

expLabel = "",

957

ext = None,

958

ext = None,

958

online = False,

959

online = False,

959

delay = 60,

960

delay = 60,

960

walk = True):

961

walk = True):

961

962

if path == None:

963

if path == None:

963

raise ValueError, "The path is not valid"

964

raise ValueError, "The path is not valid"

964

965

if ext == None:

966

if ext == None:

966

ext = self.ext

967

ext = self.ext

967

968

if online:

969

if online:

969

print "Searching files in online mode..."

970

print "Searching files in online mode..."

970

971

for nTries in range( self.nTries ):

972

for nTries in range( self.nTries ):

972

fullpath, foldercounter, file, year, doy, set = self.__searchFilesOnLine(path=path, expLabel=expLabel, ext=ext, walk=walk, set=set)

973

fullpath, foldercounter, file, year, doy, set = self.__searchFilesOnLine(path=path, expLabel=expLabel, ext=ext, walk=walk, set=set)

973

974

if fullpath:

975

if fullpath:

975

break

976

break

976

977

print '\tWaiting %0.2f sec for an valid file in %s: try %02d ...' % (self.delay, path, nTries+1)

978

print '\tWaiting %0.2f sec for an valid file in %s: try %02d ...' % (self.delay, path, nTries+1)

978

time.sleep( self.delay )

979

time.sleep( self.delay )

979

980

if not(fullpath):

981

if not(fullpath):

981

print "There 'isn't valied files in %s" % path

982

print "There 'isn't valied files in %s" % path

982

return None

983

return None

983

984

self.year = year

985

self.year = year

985

self.doy = doy

986

self.doy = doy

986

self.set = set - 1

987

self.set = set - 1

987

self.path = path

988

self.path = path

988

self.foldercounter = foldercounter

989

self.foldercounter = foldercounter

989

last_set = None

990

last_set = None

990

991

else:

992

else:

992

print "Searching files in offline mode ..."

993

print "Searching files in offline mode ..."

993

pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,

994

pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,

994

startTime=startTime, endTime=endTime,

995

startTime=startTime, endTime=endTime,

995

set=set, expLabel=expLabel, ext=ext,

996

set=set, expLabel=expLabel, ext=ext,

996

walk=walk)

997

walk=walk)

997

998

if not(pathList):

999

if not(pathList):

999

print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,

1000

print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,

1000

datetime.datetime.combine(startDate,startTime).ctime(),

1001

datetime.datetime.combine(startDate,startTime).ctime(),

1001

datetime.datetime.combine(endDate,endTime).ctime())

1002

datetime.datetime.combine(endDate,endTime).ctime())

1002

1003

sys.exit(-1)

1004

sys.exit(-1)

1004

1005

1006

self.fileIndex = -1

1007

self.fileIndex = -1

1007

self.pathList = pathList

1008

self.pathList = pathList

1008

self.filenameList = filenameList

1009

self.filenameList = filenameList

1009

file_name = os.path.basename(filenameList[-1])

1010

file_name = os.path.basename(filenameList[-1])

1010

basename, ext = os.path.splitext(file_name)

1011

basename, ext = os.path.splitext(file_name)

1011

last_set = int(basename[-3:])

1012

last_set = int(basename[-3:])

1012

1013

self.online = online

1014

self.online = online

1014

self.delay = delay

1015

self.delay = delay

1015

ext = ext.lower()

1016

ext = ext.lower()

1016

self.ext = ext

1017

self.ext = ext

1017

1018

if not(self.setNextFile()):

1019

if not(self.setNextFile()):

1019

if (startDate!=None) and (endDate!=None):

1020

if (startDate!=None) and (endDate!=None):

1020

print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())

1021

print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())

1021

elif startDate != None:

1022

elif startDate != None:

1022

print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())

1023

print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())

1023

else:

1024

else:

1024

print "No files"

1025

print "No files"

1025

1026

sys.exit(-1)

1027

sys.exit(-1)

1027

1028

# self.updateDataHeader()

1029

# self.updateDataHeader()

1029

if last_set != None:

1030

if last_set != None:

1030

self.dataOut.last_block = last_set * self.processingHeaderObj.dataBlocksPerFile + self.basicHeaderObj.dataBlock

1031

self.dataOut.last_block = last_set * self.processingHeaderObj.dataBlocksPerFile + self.basicHeaderObj.dataBlock

1031

return self.dataOut

1032

return self.dataOut

1032

1033

def getBasicHeader(self):

1034

def getBasicHeader(self):

1034

1035

self.dataOut.utctime = self.basicHeaderObj.utc + self.basicHeaderObj.miliSecond/1000. + self.profileIndex * self.ippSeconds

1036

self.dataOut.utctime = self.basicHeaderObj.utc + self.basicHeaderObj.miliSecond/1000. + self.profileIndex * self.ippSeconds

1036

1037

self.dataOut.flagTimeBlock = self.flagTimeBlock

1038

self.dataOut.flagTimeBlock = self.flagTimeBlock

1038

1039

self.dataOut.timeZone = self.basicHeaderObj.timeZone

1040

self.dataOut.timeZone = self.basicHeaderObj.timeZone

1040

1041

self.dataOut.dstFlag = self.basicHeaderObj.dstFlag

1042

self.dataOut.dstFlag = self.basicHeaderObj.dstFlag

1042

1043

self.dataOut.errorCount = self.basicHeaderObj.errorCount

1044

self.dataOut.errorCount = self.basicHeaderObj.errorCount

1044

1045

self.dataOut.useLocalTime = self.basicHeaderObj.useLocalTime

1046

self.dataOut.useLocalTime = self.basicHeaderObj.useLocalTime

1046

1047

def getFirstHeader(self):

1048

def getFirstHeader(self):

1048

1049

raise ValueError, "This method has not been implemented"

1050

raise ValueError, "This method has not been implemented"

1050

1051

def getData():

1052

def getData():

1052

1053

raise ValueError, "This method has not been implemented"

1054

raise ValueError, "This method has not been implemented"

1054

1055

def hasNotDataInBuffer():

1056

def hasNotDataInBuffer():

1056

1057

raise ValueError, "This method has not been implemented"

1058

raise ValueError, "This method has not been implemented"

1058

1059

def readBlock():

1060

def readBlock():

1060

1061

raise ValueError, "This method has not been implemented"

1062

raise ValueError, "This method has not been implemented"

1062

1063

def isEndProcess(self):

1064

def isEndProcess(self):

1064

1065

return self.flagNoMoreFiles

1066

return self.flagNoMoreFiles

1066

1067

def printReadBlocks(self):

1068

def printReadBlocks(self):

1068

1069

print "Number of read blocks per file %04d" %self.nReadBlocks

1070

print "Number of read blocks per file %04d" %self.nReadBlocks

1070

1071

def printTotalBlocks(self):

1072

def printTotalBlocks(self):

1072

1073

print "Number of read blocks %04d" %self.nTotalBlocks

1074

print "Number of read blocks %04d" %self.nTotalBlocks

1074

1075

def printNumberOfBlock(self):

1076

def printNumberOfBlock(self):

1076

1077

if self.flagIsNewBlock:

1078

if self.flagIsNewBlock:

1078

print "Block No. %04d, Total blocks %04d -> %s" %(self.basicHeaderObj.dataBlock, self.nTotalBlocks, self.dataOut.datatime.ctime())

1079

print "Block No. %04d, Total blocks %04d -> %s" %(self.basicHeaderObj.dataBlock, self.nTotalBlocks, self.dataOut.datatime.ctime())

1079

self.dataOut.blocknow = self.basicHeaderObj.dataBlock

1080

self.dataOut.blocknow = self.basicHeaderObj.dataBlock

1080

def printInfo(self):

1081

def printInfo(self):

1081

1082

if self.__printInfo == False:

1083

if self.__printInfo == False:

1083

return

1084

return

1084

1085

self.basicHeaderObj.printInfo()

1086

self.basicHeaderObj.printInfo()

1086

self.systemHeaderObj.printInfo()

1087

self.systemHeaderObj.printInfo()

1087

self.radarControllerHeaderObj.printInfo()

1088

self.radarControllerHeaderObj.printInfo()

1088

self.processingHeaderObj.printInfo()

1089

self.processingHeaderObj.printInfo()

1089

1090

self.__printInfo = False

1091

self.__printInfo = False

1091

1092

1093

def run(self, **kwargs):

1094

def run(self, **kwargs):

1094

1095

if not(self.isConfig):

1096

if not(self.isConfig):

1096

1097

# self.dataOut = dataOut

1098

# self.dataOut = dataOut

1098

self.setup(**kwargs)

1099

self.setup(**kwargs)

1099

self.isConfig = True

1100

self.isConfig = True

1100

1101

self.getData()

1102

self.getData()

1102

1103

class JRODataWriter(JRODataIO, Operation):

1104

class JRODataWriter(JRODataIO, Operation):

1104

1105

"""

1106

"""

1106

Esta clase permite escribir datos a archivos procesados (.r o ,pdata). La escritura

1107

Esta clase permite escribir datos a archivos procesados (.r o ,pdata). La escritura

1107

de los datos siempre se realiza por bloques.

1108

de los datos siempre se realiza por bloques.

1108

"""

1109

"""

1109

1110

blockIndex = 0

1111

blockIndex = 0

1111

1112

path = None

1113

path = None

1113

1114

setFile = None

1115

setFile = None

1115

1116

profilesPerBlock = None

1117

profilesPerBlock = None

1117

1118

blocksPerFile = None

1119

blocksPerFile = None

1119

1120

nWriteBlocks = 0

1121

nWriteBlocks = 0

1121

1122

def __init__(self, dataOut=None):

1123

def __init__(self, dataOut=None):

1123

raise ValueError, "Not implemented"

1124

raise ValueError, "Not implemented"

1124

1125

1126

def hasAllDataInBuffer(self):

1127

def hasAllDataInBuffer(self):

1127

raise ValueError, "Not implemented"

1128

raise ValueError, "Not implemented"

1128

1129

1130

def setBlockDimension(self):

1131

def setBlockDimension(self):

1131

raise ValueError, "Not implemented"

1132

raise ValueError, "Not implemented"

1132

1133

1134

def writeBlock(self):

1135

def writeBlock(self):

1135

raise ValueError, "No implemented"

1136

raise ValueError, "No implemented"

1136

1137

1138

def putData(self):

1139

def putData(self):

1139

raise ValueError, "No implemented"

1140

raise ValueError, "No implemented"

1140

1141

1142

def setBasicHeader(self):

1143

def setBasicHeader(self):

1143

1144

self.basicHeaderObj.size = self.basicHeaderSize #bytes

1145

self.basicHeaderObj.size = self.basicHeaderSize #bytes

1145

self.basicHeaderObj.version = self.versionFile

1146

self.basicHeaderObj.version = self.versionFile

1146

self.basicHeaderObj.dataBlock = self.nTotalBlocks

1147

self.basicHeaderObj.dataBlock = self.nTotalBlocks

1147

1148

utc = numpy.floor(self.dataOut.utctime)

1149

utc = numpy.floor(self.dataOut.utctime)

1149

milisecond = (self.dataOut.utctime - utc)* 1000.0

1150

milisecond = (self.dataOut.utctime - utc)* 1000.0

1150

1151

self.basicHeaderObj.utc = utc

1152

self.basicHeaderObj.utc = utc

1152

self.basicHeaderObj.miliSecond = milisecond

1153

self.basicHeaderObj.miliSecond = milisecond

1153

self.basicHeaderObj.timeZone = self.dataOut.timeZone

1154

self.basicHeaderObj.timeZone = self.dataOut.timeZone

1154

self.basicHeaderObj.dstFlag = self.dataOut.dstFlag

1155

self.basicHeaderObj.dstFlag = self.dataOut.dstFlag

1155

self.basicHeaderObj.errorCount = self.dataOut.errorCount

1156

self.basicHeaderObj.errorCount = self.dataOut.errorCount

1156

1157

def setFirstHeader(self):

1158

def setFirstHeader(self):

1158

"""

1159

"""

1159

Obtiene una copia del First Header

1160

Obtiene una copia del First Header

1160

1161

Affected:

1162

Affected:

1162

1163

self.basicHeaderObj

1164

self.basicHeaderObj

1164

self.systemHeaderObj

1165

self.systemHeaderObj

1165

self.radarControllerHeaderObj

1166

self.radarControllerHeaderObj

1166

self.processingHeaderObj self.

1167

self.processingHeaderObj self.

1167

1168

Return:

1169

Return:

1169

None

1170

None

1170

"""

1171

"""

1171

1172

raise ValueError, "No implemented"

1173

raise ValueError, "No implemented"

1173

1174

def __writeFirstHeader(self):

1175

def __writeFirstHeader(self):

1175

"""

1176

"""

1176

Escribe el primer header del file es decir el Basic header y el Long header (SystemHeader, RadarControllerHeader, ProcessingHeader)

1177

Escribe el primer header del file es decir el Basic header y el Long header (SystemHeader, RadarControllerHeader, ProcessingHeader)

1177

1178

Affected:

1179

Affected:

1179

__dataType

1180

__dataType

1180

1181

Return:

1182

Return:

1182

None

1183

None

1183

"""

1184

"""

1184

1185

# CALCULAR PARAMETROS

1186

# CALCULAR PARAMETROS

1186

1187

sizeLongHeader = self.systemHeaderObj.size + self.radarControllerHeaderObj.size + self.processingHeaderObj.size

1188

sizeLongHeader = self.systemHeaderObj.size + self.radarControllerHeaderObj.size + self.processingHeaderObj.size

1188

self.basicHeaderObj.size = self.basicHeaderSize + sizeLongHeader

1189

self.basicHeaderObj.size = self.basicHeaderSize + sizeLongHeader

1189

1190

self.basicHeaderObj.write(self.fp)

1191

self.basicHeaderObj.write(self.fp)

1191

self.systemHeaderObj.write(self.fp)

1192

self.systemHeaderObj.write(self.fp)

1192

self.radarControllerHeaderObj.write(self.fp)

1193

self.radarControllerHeaderObj.write(self.fp)

1193

self.processingHeaderObj.write(self.fp)

1194

self.processingHeaderObj.write(self.fp)

1194

1195

self.dtype = self.dataOut.dtype

1196

self.dtype = self.dataOut.dtype

1196

1197

def __setNewBlock(self):

1198

def __setNewBlock(self):

1198

"""

1199

"""

1199

Si es un nuevo file escribe el First Header caso contrario escribe solo el Basic Header

1200

Si es un nuevo file escribe el First Header caso contrario escribe solo el Basic Header

1200

1201

Return:

1202

Return:

1202

0 : si no pudo escribir nada

1203

0 : si no pudo escribir nada

1203

1 : Si escribio el Basic el First Header

1204

1 : Si escribio el Basic el First Header

1204

"""

1205

"""

1205

if self.fp == None:

1206

if self.fp == None:

1206

self.setNextFile()

1207

self.setNextFile()

1207

1208

if self.flagIsNewFile:

1209

if self.flagIsNewFile:

1209

return 1

1210

return 1

1210

1211

if self.blockIndex < self.processingHeaderObj.dataBlocksPerFile:

1212

if self.blockIndex < self.processingHeaderObj.dataBlocksPerFile:

1212

self.basicHeaderObj.write(self.fp)

1213

self.basicHeaderObj.write(self.fp)

1213

return 1

1214

return 1

1214

1215

if not( self.setNextFile() ):

1216

if not( self.setNextFile() ):

1216

return 0

1217

return 0

1217

1218

return 1

1219

return 1

1219

1220

1221

def writeNextBlock(self):

1222

def writeNextBlock(self):

1222

"""

1223

"""

1223

Selecciona el bloque siguiente de datos y los escribe en un file

1224

Selecciona el bloque siguiente de datos y los escribe en un file

1224

1225

Return:

1226

Return:

1226

0 : Si no hizo pudo escribir el bloque de datos

1227

0 : Si no hizo pudo escribir el bloque de datos

1227

1 : Si no pudo escribir el bloque de datos

1228

1 : Si no pudo escribir el bloque de datos

1228

"""

1229

"""

1229

if not( self.__setNewBlock() ):

1230

if not( self.__setNewBlock() ):

1230

return 0

1231

return 0

1231

1232

self.writeBlock()

1233

self.writeBlock()

1233

1234

return 1

1235

return 1

1235

1236

def setNextFile(self):

1237

def setNextFile(self):

1237

"""

1238

"""

1238

Determina el siguiente file que sera escrito

1239

Determina el siguiente file que sera escrito

1239

1240

Affected:

1241

Affected:

1241

self.filename

1242

self.filename

1242

self.subfolder

1243

self.subfolder

1243

self.fp

1244

self.fp

1244

self.setFile

1245

self.setFile

1245

self.flagIsNewFile

1246

self.flagIsNewFile

1246

1247

Return:

1248

Return:

1248

0 : Si el archivo no puede ser escrito

1249

0 : Si el archivo no puede ser escrito

1249

1 : Si el archivo esta listo para ser escrito

1250

1 : Si el archivo esta listo para ser escrito

1250

"""

1251

"""

1251

ext = self.ext

1252

ext = self.ext

1252

path = self.path

1253

path = self.path

1253

1254

if self.fp != None:

1255

if self.fp != None:

1255

self.fp.close()

1256

self.fp.close()

1256

1257

timeTuple = time.localtime( self.dataOut.utctime)

1258

timeTuple = time.localtime( self.dataOut.utctime)

1258

subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)

1259

subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)

1259

1260

fullpath = os.path.join( path, subfolder )

1261

fullpath = os.path.join( path, subfolder )

1261

if not( os.path.exists(fullpath) ):

1262

if not( os.path.exists(fullpath) ):

1262

os.mkdir(fullpath)

1263

os.mkdir(fullpath)

1263

self.setFile = -1 #inicializo mi contador de seteo

1264

self.setFile = -1 #inicializo mi contador de seteo

1264

else:

1265

else:

1265

filesList = os.listdir( fullpath )

1266

filesList = os.listdir( fullpath )

1266

if len( filesList ) > 0:

1267

if len( filesList ) > 0:

1267

filesList = sorted( filesList, key=str.lower )

1268

filesList = sorted( filesList, key=str.lower )

1268

filen = filesList[-1]

1269

filen = filesList[-1]

1269

# el filename debera tener el siguiente formato

1270

# el filename debera tener el siguiente formato

1270

# 0 1234 567 89A BCDE (hex)

1271

# 0 1234 567 89A BCDE (hex)

1271

# x YYYY DDD SSS .ext

1272

# x YYYY DDD SSS .ext

1272

if isNumber( filen[8:11] ):

1273

if isNumber( filen[8:11] ):

1273

self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file

1274

self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file

1274

else:

1275

else:

1275

self.setFile = -1

1276

self.setFile = -1

1276

else:

1277

else:

1277

self.setFile = -1 #inicializo mi contador de seteo

1278

self.setFile = -1 #inicializo mi contador de seteo

1278

1279

setFile = self.setFile

1280

setFile = self.setFile

1280

setFile += 1

1281

setFile += 1

1281

1282

file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,

1283

file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,

1283

timeTuple.tm_year,

1284

timeTuple.tm_year,

1284

timeTuple.tm_yday,

1285

timeTuple.tm_yday,

1285

setFile,

1286

setFile,

1286

ext )

1287

ext )

1287

1288

filename = os.path.join( path, subfolder, file )

1289

filename = os.path.join( path, subfolder, file )

1289

1290

fp = open( filename,'wb' )

1291

fp = open( filename,'wb' )

1291

1292

self.blockIndex = 0

1293

self.blockIndex = 0

1293

1294

#guardando atributos

1295

#guardando atributos

1295

self.filename = filename

1296

self.filename = filename

1296

self.subfolder = subfolder

1297

self.subfolder = subfolder

1297

self.fp = fp

1298

self.fp = fp

1298

self.setFile = setFile

1299

self.setFile = setFile

1299

self.flagIsNewFile = 1

1300

self.flagIsNewFile = 1

1300

1301

self.setFirstHeader()

1302

self.setFirstHeader()

1302

1303

print 'Writing the file: %s'%self.filename

1304

print 'Writing the file: %s'%self.filename

1304

1305

self.__writeFirstHeader()

1306

self.__writeFirstHeader()

1306

1307

return 1

1308

return 1

1308

1309

def setup(self, dataOut, path, blocksPerFile, profilesPerBlock=64, set=0, ext=None):

1310

def setup(self, dataOut, path, blocksPerFile, profilesPerBlock=64, set=0, ext=None):

1310

"""

1311

"""

1311

Setea el tipo de formato en la cual sera guardada la data y escribe el First Header

1312

Setea el tipo de formato en la cual sera guardada la data y escribe el First Header

1312

1313

Inputs:

1314

Inputs:

1314

path : el path destino en el cual se escribiran los files a crear

1315

path : el path destino en el cual se escribiran los files a crear

1315

format : formato en el cual sera salvado un file

1316

format : formato en el cual sera salvado un file

1316

set : el setebo del file

1317

set : el setebo del file

1317

1318

Return:

1319

Return:

1319

0 : Si no realizo un buen seteo

1320

0 : Si no realizo un buen seteo

1320

1 : Si realizo un buen seteo

1321

1 : Si realizo un buen seteo

1321

"""

1322

"""

1322

1323

if ext == None:

1324

if ext == None:

1324

ext = self.ext

1325

ext = self.ext

1325

1326

ext = ext.lower()

1327

ext = ext.lower()

1327

1328

self.ext = ext

1329

self.ext = ext

1329

1330

self.path = path

1331

self.path = path

1331

1332

self.setFile = set - 1

1333

self.setFile = set - 1

1333

1334

self.blocksPerFile = blocksPerFile

1335

self.blocksPerFile = blocksPerFile

1335

1336

self.profilesPerBlock = profilesPerBlock

1337

self.profilesPerBlock = profilesPerBlock

1337

1338

self.dataOut = dataOut

1339

self.dataOut = dataOut

1339

1340

if not(self.setNextFile()):

1341

if not(self.setNextFile()):

1341

print "There isn't a next file"

1342

print "There isn't a next file"

1342

return 0

1343

return 0

1343

1344

self.setBlockDimension()

1345

self.setBlockDimension()

1345

1346

return 1

1347

return 1

1347

1348

def run(self, dataOut, **kwargs):

1349

def run(self, dataOut, **kwargs):

1349

1350

if not(self.isConfig):

1351

if not(self.isConfig):

1351

1352

self.setup(dataOut, **kwargs)

1353

self.setup(dataOut, **kwargs)

1353

self.isConfig = True

1354

self.isConfig = True

1354

1355

self.putData()

1356

self.putData()

1356

1357

class VoltageReader(JRODataReader):

1358

class VoltageReader(JRODataReader):

1358

"""

1359

"""

1359

Esta clase permite leer datos de voltage desde archivos en formato rawdata (.r). La lectura

1360

Esta clase permite leer datos de voltage desde archivos en formato rawdata (.r). La lectura

1360

de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones:

1361

de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones:

1361

perfiles*alturas*canales) son almacenados en la variable "buffer".

1362

perfiles*alturas*canales) son almacenados en la variable "buffer".

1362

1363

perfiles * alturas * canales

1364

perfiles * alturas * canales

1364

1365

Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,

1366

Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,

1366

RadarControllerHeader y Voltage. Los tres primeros se usan para almacenar informacion de la

1367

RadarControllerHeader y Voltage. Los tres primeros se usan para almacenar informacion de la

1367

cabecera de datos (metadata), y el cuarto (Voltage) para obtener y almacenar un perfil de

1368

cabecera de datos (metadata), y el cuarto (Voltage) para obtener y almacenar un perfil de

1368

datos desde el "buffer" cada vez que se ejecute el metodo "getData".

1369

datos desde el "buffer" cada vez que se ejecute el metodo "getData".

1369

1370

Example:

1371

Example:

1371

1372

dpath = "/home/myuser/data"

1373

dpath = "/home/myuser/data"

1373

1374

startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)

1375

startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)

1375

1376

endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)

1377

endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)

1377

1378

readerObj = VoltageReader()

1379

readerObj = VoltageReader()

1379

1380

readerObj.setup(dpath, startTime, endTime)

1381

readerObj.setup(dpath, startTime, endTime)

1381

1382

while(True):

1383

while(True):

1383

1384

#to get one profile

1385

#to get one profile

1385

profile = readerObj.getData()

1386

profile = readerObj.getData()

1386

1387

#print the profile

1388

#print the profile

1388

print profile

1389

print profile

1389

1390

#If you want to see all datablock

1391

#If you want to see all datablock

1391

print readerObj.datablock

1392

print readerObj.datablock

1392

1393

if readerObj.flagNoMoreFiles:

1394

if readerObj.flagNoMoreFiles:

1394

break

1395

break

1395

1396

"""

1397

"""

1397

1398

ext = ".r"

1399

ext = ".r"

1399

1400

optchar = "D"

1401

optchar = "D"

1401

dataOut = None

1402

dataOut = None

1402

1403

1404

def __init__(self):

1405

def __init__(self):

1405

"""

1406

"""

1406

Inicializador de la clase VoltageReader para la lectura de datos de voltage.

1407

Inicializador de la clase VoltageReader para la lectura de datos de voltage.

1407

1408

Input:

1409

Input:

1409

dataOut : Objeto de la clase Voltage. Este objeto sera utilizado para

1410

dataOut : Objeto de la clase Voltage. Este objeto sera utilizado para

1410

almacenar un perfil de datos cada vez que se haga un requerimiento

1411

almacenar un perfil de datos cada vez que se haga un requerimiento

1411

(getData). El perfil sera obtenido a partir del buffer de datos,

1412

(getData). El perfil sera obtenido a partir del buffer de datos,

1412

si el buffer esta vacio se hara un nuevo proceso de lectura de un

1413

si el buffer esta vacio se hara un nuevo proceso de lectura de un

1413

bloque de datos.

1414

bloque de datos.

1414

Si este parametro no es pasado se creara uno internamente.

1415

Si este parametro no es pasado se creara uno internamente.

1415

1416

Variables afectadas:

1417

Variables afectadas:

1417

self.dataOut

1418

self.dataOut

1418

1419

Return:

1420

Return:

1420

None

1421

None

1421

"""

1422

"""

1422

1423

self.isConfig = False

1424

self.isConfig = False

1424

1425

self.datablock = None

1426

self.datablock = None

1426

1427

self.utc = 0

1428

self.utc = 0

1428

1429

self.ext = ".r"

1430

self.ext = ".r"

1430

1431

self.optchar = "D"

1432

self.optchar = "D"

1432

1433

self.basicHeaderObj = BasicHeader(LOCALTIME)

1434

self.basicHeaderObj = BasicHeader(LOCALTIME)

1434

1435

self.systemHeaderObj = SystemHeader()

1436

self.systemHeaderObj = SystemHeader()

1436

1437

self.radarControllerHeaderObj = RadarControllerHeader()

1438

self.radarControllerHeaderObj = RadarControllerHeader()

1438

1439

self.processingHeaderObj = ProcessingHeader()

1440

self.processingHeaderObj = ProcessingHeader()

1440

1441

self.online = 0

1442

self.online = 0

1442

1443

self.fp = None

1444

self.fp = None

1444

1445

self.idFile = None

1446

self.idFile = None

1446

1447

self.dtype = None

1448

self.dtype = None

1448

1449

self.fileSizeByHeader = None

1450

self.fileSizeByHeader = None

1450

1451

self.filenameList = []

1452

self.filenameList = []

1452

1453

self.filename = None

1454

self.filename = None

1454

1455

self.fileSize = None

1456

self.fileSize = None

1456

1457

self.firstHeaderSize = 0

1458

self.firstHeaderSize = 0

1458

1459

self.basicHeaderSize = 24

1460

self.basicHeaderSize = 24

1460

1461

self.pathList = []

1462

self.pathList = []

1462

1463

self.filenameList = []

1464

self.filenameList = []

1464

1465

self.lastUTTime = 0

1466

self.lastUTTime = 0

1466

1467

self.maxTimeStep = 30

1468

self.maxTimeStep = 30

1468

1469

self.flagNoMoreFiles = 0

1470

self.flagNoMoreFiles = 0

1470

1471

self.set = 0

1472

self.set = 0

1472

1473

self.path = None

1474

self.path = None

1474

1475

self.profileIndex = 2**32-1

1476

self.profileIndex = 2**32-1

1476

1477

self.delay = 3 #seconds

1478

self.delay = 3 #seconds

1478

1479

self.nTries = 3 #quantity tries

1480

self.nTries = 3 #quantity tries

1480

1481

self.nFiles = 3 #number of files for searching

1482

self.nFiles = 3 #number of files for searching

1482

1483

self.nReadBlocks = 0

1484

self.nReadBlocks = 0

1484

1485

self.flagIsNewFile = 1

1486

self.flagIsNewFile = 1

1486

1487

self.__isFirstTimeOnline = 1

1488

self.__isFirstTimeOnline = 1

1488

1489

self.ippSeconds = 0

1490

self.ippSeconds = 0

1490

1491

self.flagTimeBlock = 0

1492

self.flagTimeBlock = 0

1492

1493

self.flagIsNewBlock = 0

1494

self.flagIsNewBlock = 0

1494

1495

self.nTotalBlocks = 0

1496

self.nTotalBlocks = 0

1496

1497

self.blocksize = 0

1498

self.blocksize = 0

1498

1499

self.dataOut = self.createObjByDefault()

1500

self.dataOut = self.createObjByDefault()

1500

1501

def createObjByDefault(self):

1502

def createObjByDefault(self):

1502

1503

dataObj = Voltage()

1504

dataObj = Voltage()

1504

1505

return dataObj

1506

return dataObj

1506

1507

def __hasNotDataInBuffer(self):

1508

def __hasNotDataInBuffer(self):

1508

if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:

1509

if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:

1509

return 1

1510

return 1

1510

return 0

1511

return 0

1511

1512

1513

def getBlockDimension(self):

1514

def getBlockDimension(self):

1514

"""

1515

"""

1515

Obtiene la cantidad de puntos a leer por cada bloque de datos

1516

Obtiene la cantidad de puntos a leer por cada bloque de datos

1516

1517

Affected:

1518

Affected:

1518

self.blocksize

1519

self.blocksize

1519

1520

Return:

1521

Return:

1521

None

1522

None

1522

"""

1523

"""

1523

pts2read = self.processingHeaderObj.profilesPerBlock * self.processingHeaderObj.nHeights * self.systemHeaderObj.nChannels

1524

pts2read = self.processingHeaderObj.profilesPerBlock * self.processingHeaderObj.nHeights * self.systemHeaderObj.nChannels

1524

self.blocksize = pts2read

1525

self.blocksize = pts2read

1525

1526

1527

def readBlock(self):

1528

def readBlock(self):

1528

"""

1529

"""

1529

readBlock lee el bloque de datos desde la posicion actual del puntero del archivo

1530

readBlock lee el bloque de datos desde la posicion actual del puntero del archivo

1530

(self.fp) y actualiza todos los parametros relacionados al bloque de datos

1531

(self.fp) y actualiza todos los parametros relacionados al bloque de datos

1531

(metadata + data). La data leida es almacenada en el buffer y el contador del buffer

1532

(metadata + data). La data leida es almacenada en el buffer y el contador del buffer

1532

es seteado a 0

1533

es seteado a 0

1533

1534

Inputs:

1535

Inputs:

1535

None

1536

None

1536

1537

Return:

1538

Return:

1538

None

1539

None

1539

1540

Affected:

1541

Affected:

1541

self.profileIndex

1542

self.profileIndex

1542

self.datablock

1543

self.datablock

1543

self.flagIsNewFile

1544

self.flagIsNewFile

1544

self.flagIsNewBlock

1545

self.flagIsNewBlock

1545

self.nTotalBlocks

1546

self.nTotalBlocks

1546

1547

Exceptions:

1548

Exceptions:

1548

Si un bloque leido no es un bloque valido

1549

Si un bloque leido no es un bloque valido

1549

"""

1550

"""

1550

current_pointer_location = self.fp.tell()

1551

current_pointer_location = self.fp.tell()

1551

junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )

1552

junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )

1552

1553

try:

1554

try:

1554

junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )

1555

junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )

1555

except:

1556

except:

1556

#print "The read block (%3d) has not enough data" %self.nReadBlocks

1557

#print "The read block (%3d) has not enough data" %self.nReadBlocks

1557

1558

if self.waitDataBlock(pointer_location=current_pointer_location):

1559

if self.waitDataBlock(pointer_location=current_pointer_location):

1559

junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )

1560

junk = numpy.fromfile( self.fp, self.dtype, self.blocksize )

1560

junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )

1561

junk = junk.reshape( (self.processingHeaderObj.profilesPerBlock, self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels) )

1561

# return 0

1562

# return 0

1562

1563

junk = numpy.transpose(junk, (2,0,1))

1564

junk = numpy.transpose(junk, (2,0,1))

1564

self.datablock = junk['real'] + junk['imag']*1j

1565

self.datablock = junk['real'] + junk['imag']*1j

1565

1566

self.profileIndex = 0

1567

self.profileIndex = 0

1567

1568

self.flagIsNewFile = 0

1569

self.flagIsNewFile = 0

1569

self.flagIsNewBlock = 1

1570

self.flagIsNewBlock = 1

1570

1571

self.nTotalBlocks += 1

1572

self.nTotalBlocks += 1

1572

self.nReadBlocks += 1

1573

self.nReadBlocks += 1

1573

1574

return 1

1575

return 1

1575

1576

def getFirstHeader(self):

1577

def getFirstHeader(self):

1577

1578

self.dataOut.dtype = self.dtype

1579

self.dataOut.dtype = self.dtype

1579

1580

self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock

1581

self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock

1581

1582

xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight

1583

xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight

1583

1584

self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)

1585

self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)

1585

1586

self.dataOut.channelList = range(self.systemHeaderObj.nChannels)

1587

self.dataOut.channelList = range(self.systemHeaderObj.nChannels)

1587

1588

self.dataOut.ippSeconds = self.ippSeconds

1589

self.dataOut.ippSeconds = self.ippSeconds

1589

1590

self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt

1591

self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt

1591

1592

self.dataOut.nCohInt = self.processingHeaderObj.nCohInt

1593

self.dataOut.nCohInt = self.processingHeaderObj.nCohInt

1593

1594

self.dataOut.flagShiftFFT = False

1595

self.dataOut.flagShiftFFT = False

1595

1596

if self.radarControllerHeaderObj.code != None:

1597

if self.radarControllerHeaderObj.code != None:

1597

1598

self.dataOut.nCode = self.radarControllerHeaderObj.nCode

1599

self.dataOut.nCode = self.radarControllerHeaderObj.nCode

1599

1600

self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud

1601

self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud

1601

1602

self.dataOut.code = self.radarControllerHeaderObj.code

1603

self.dataOut.code = self.radarControllerHeaderObj.code

1603

1604

self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()

1605

self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()

1605

1606

self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()

1607

self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()

1607

1608

self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada

1609

self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada

1609

1610

self.dataOut.flagDeflipData = False #asumo q la data no esta sin flip

1611

self.dataOut.flagDeflipData = False #asumo q la data no esta sin flip

1611

1612

self.dataOut.flagShiftFFT = False

1613

self.dataOut.flagShiftFFT = False

1613

1614

def getData(self):

1615

def getData(self):

1615

"""

1616

"""

1616

getData obtiene una unidad de datos del buffer de lectura y la copia a la clase "Voltage"

1617

getData obtiene una unidad de datos del buffer de lectura y la copia a la clase "Voltage"

1617

con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de

1618

con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de

1618

lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"

1619

lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"

1619

1620

Ademas incrementa el contador del buffer en 1.

1621

Ademas incrementa el contador del buffer en 1.

1621

1622

Return:

1623

Return:

1623

data : retorna un perfil de voltages (alturas * canales) copiados desde el

1624

data : retorna un perfil de voltages (alturas * canales) copiados desde el

1624

buffer. Si no hay mas archivos a leer retorna None.

1625

buffer. Si no hay mas archivos a leer retorna None.

1625

1626

Variables afectadas:

1627

Variables afectadas:

1627

self.dataOut

1628

self.dataOut

1628

self.profileIndex

1629

self.profileIndex

1629

1630

Affected:

1631

Affected:

1631

self.dataOut

1632

self.dataOut

1632

self.profileIndex

1633

self.profileIndex

1633

self.flagTimeBlock

1634

self.flagTimeBlock

1634

self.flagIsNewBlock

1635

self.flagIsNewBlock

1635

"""

1636

"""

1636

1637

if self.flagNoMoreFiles:

1638

if self.flagNoMoreFiles:

1638

self.dataOut.flagNoData = True

1639

self.dataOut.flagNoData = True

1639

print 'Process finished'

1640

print 'Process finished'

1640

return 0

1641

return 0

1641

1642

self.flagTimeBlock = 0

1643

self.flagTimeBlock = 0

1643

self.flagIsNewBlock = 0

1644

self.flagIsNewBlock = 0

1644

1645

if self.__hasNotDataInBuffer():

1646

if self.__hasNotDataInBuffer():

1646

1647

if not( self.readNextBlock() ):

1648

if not( self.readNextBlock() ):

1648

return 0

1649

return 0

1649

1650

self.getFirstHeader()

1651

self.getFirstHeader()

1651

1652

if self.datablock == None:

1653

if self.datablock == None:

1653

self.dataOut.flagNoData = True

1654

self.dataOut.flagNoData = True

1654

return 0

1655

return 0

1655

1656

self.dataOut.data = self.datablock[:,self.profileIndex,:]

1657

self.dataOut.data = self.datablock[:,self.profileIndex,:]

1657

1658

self.dataOut.flagNoData = False

1659

self.dataOut.flagNoData = False

1659

1660

self.getBasicHeader()

1661

self.getBasicHeader()

1661

1662

self.profileIndex += 1

1663

self.profileIndex += 1

1663

1664

self.dataOut.realtime = self.online

1665

self.dataOut.realtime = self.online

1665

1666

return self.dataOut.data

1667

return self.dataOut.data

1667

1668

1669

class VoltageWriter(JRODataWriter):

1670

class VoltageWriter(JRODataWriter):

1670

"""

1671

"""

1671

Esta clase permite escribir datos de voltajes a archivos procesados (.r). La escritura

1672

Esta clase permite escribir datos de voltajes a archivos procesados (.r). La escritura

1672

de los datos siempre se realiza por bloques.

1673

de los datos siempre se realiza por bloques.

1673

"""

1674

"""

1674

1675

ext = ".r"

1676

ext = ".r"

1676

1677

optchar = "D"

1678

optchar = "D"

1678

1679

shapeBuffer = None

1680

shapeBuffer = None

1680

1681

1682

def __init__(self):

1683

def __init__(self):

1683

"""

1684

"""

1684

Inicializador de la clase VoltageWriter para la escritura de datos de espectros.

1685

Inicializador de la clase VoltageWriter para la escritura de datos de espectros.

1685

1686

Affected:

1687

Affected:

1687

self.dataOut

1688

self.dataOut

1688

1689

Return: None

1690

Return: None

1690

"""

1691

"""

1691

1692

self.nTotalBlocks = 0

1693

self.nTotalBlocks = 0

1693

1694

self.profileIndex = 0

1695

self.profileIndex = 0

1695

1696

self.isConfig = False

1697

self.isConfig = False

1697

1698

self.fp = None

1699

self.fp = None

1699

1700

self.flagIsNewFile = 1

1701

self.flagIsNewFile = 1

1701

1702

self.nTotalBlocks = 0

1703

self.nTotalBlocks = 0

1703

1704

self.flagIsNewBlock = 0

1705

self.flagIsNewBlock = 0

1705

1706

self.setFile = None

1707

self.setFile = None

1707

1708

self.dtype = None

1709

self.dtype = None

1709

1710

self.path = None

1711

self.path = None

1711

1712

self.filename = None

1713

self.filename = None

1713

1714

self.basicHeaderObj = BasicHeader(LOCALTIME)

1715

self.basicHeaderObj = BasicHeader(LOCALTIME)

1715

1716

self.systemHeaderObj = SystemHeader()

1717

self.systemHeaderObj = SystemHeader()

1717

1718

self.radarControllerHeaderObj = RadarControllerHeader()

1719

self.radarControllerHeaderObj = RadarControllerHeader()

1719

1720

self.processingHeaderObj = ProcessingHeader()

1721

self.processingHeaderObj = ProcessingHeader()

1721

1722

def hasAllDataInBuffer(self):

1723

def hasAllDataInBuffer(self):

1723

if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:

1724

if self.profileIndex >= self.processingHeaderObj.profilesPerBlock:

1724

return 1

1725

return 1

1725

return 0

1726

return 0

1726

1727

1728

def setBlockDimension(self):

1729

def setBlockDimension(self):

1729

"""

1730

"""

1730

Obtiene las formas dimensionales del los subbloques de datos que componen un bloque

1731

Obtiene las formas dimensionales del los subbloques de datos que componen un bloque

1731

1732

Affected:

1733

Affected:

1733

self.shape_spc_Buffer

1734

self.shape_spc_Buffer

1734

self.shape_cspc_Buffer

1735

self.shape_cspc_Buffer

1735

self.shape_dc_Buffer

1736

self.shape_dc_Buffer

1736

1737

Return: None

1738

Return: None

1738

"""

1739

"""

1739

self.shapeBuffer = (self.processingHeaderObj.profilesPerBlock,

1740

self.shapeBuffer = (self.processingHeaderObj.profilesPerBlock,

1740

self.processingHeaderObj.nHeights,

1741

self.processingHeaderObj.nHeights,

1741

self.systemHeaderObj.nChannels)

1742

self.systemHeaderObj.nChannels)

1742

1743

self.datablock = numpy.zeros((self.systemHeaderObj.nChannels,

1744

self.datablock = numpy.zeros((self.systemHeaderObj.nChannels,

1744

self.processingHeaderObj.profilesPerBlock,

1745

self.processingHeaderObj.profilesPerBlock,

1745

self.processingHeaderObj.nHeights),

1746

self.processingHeaderObj.nHeights),

1746

dtype=numpy.dtype('complex64'))

1747

dtype=numpy.dtype('complex64'))

1747

1748

1749

def writeBlock(self):

1750

def writeBlock(self):

1750

"""

1751

"""

1751

Escribe el buffer en el file designado

1752

Escribe el buffer en el file designado

1752

1753

Affected:

1754

Affected:

1754

self.profileIndex

1755

self.profileIndex

1755

self.flagIsNewFile

1756

self.flagIsNewFile

1756

self.flagIsNewBlock

1757

self.flagIsNewBlock

1757

self.nTotalBlocks

1758

self.nTotalBlocks

1758

self.blockIndex

1759

self.blockIndex

1759

1760

Return: None

1761

Return: None

1761

"""

1762

"""

1762

data = numpy.zeros( self.shapeBuffer, self.dtype )

1763

data = numpy.zeros( self.shapeBuffer, self.dtype )

1763

1764

junk = numpy.transpose(self.datablock, (1,2,0))

1765

junk = numpy.transpose(self.datablock, (1,2,0))

1765

1766

data['real'] = junk.real

1767

data['real'] = junk.real

1767

data['imag'] = junk.imag

1768

data['imag'] = junk.imag

1768

1769

data = data.reshape( (-1) )

1770

data = data.reshape( (-1) )

1770

1771

data.tofile( self.fp )

1772

data.tofile( self.fp )

1772

1773

self.datablock.fill(0)

1774

self.datablock.fill(0)

1774

1775

self.profileIndex = 0

1776

self.profileIndex = 0

1776

self.flagIsNewFile = 0

1777

self.flagIsNewFile = 0

1777

self.flagIsNewBlock = 1

1778

self.flagIsNewBlock = 1

1778

1779

self.blockIndex += 1

1780

self.blockIndex += 1

1780

self.nTotalBlocks += 1

1781

self.nTotalBlocks += 1

1781

1782

def putData(self):

1783

def putData(self):

1783

"""

1784

"""

1784

Setea un bloque de datos y luego los escribe en un file

1785

Setea un bloque de datos y luego los escribe en un file

1785

1786

Affected:

1787

Affected:

1787

self.flagIsNewBlock

1788

self.flagIsNewBlock

1788

self.profileIndex

1789

self.profileIndex

1789

1790

Return:

1791

Return:

1791

0 : Si no hay data o no hay mas files que puedan escribirse

1792

0 : Si no hay data o no hay mas files que puedan escribirse

1792

1 : Si se escribio la data de un bloque en un file

1793

1 : Si se escribio la data de un bloque en un file

1793

"""

1794

"""

1794

if self.dataOut.flagNoData:

1795

if self.dataOut.flagNoData:

1795

return 0

1796

return 0

1796

1797

self.flagIsNewBlock = 0

1798

self.flagIsNewBlock = 0

1798

1799

if self.dataOut.flagTimeBlock:

1800

if self.dataOut.flagTimeBlock:

1800

1801

self.datablock.fill(0)

1802

self.datablock.fill(0)

1802

self.profileIndex = 0

1803

self.profileIndex = 0

1803

self.setNextFile()

1804

self.setNextFile()

1804

1805

if self.profileIndex == 0:

1806

if self.profileIndex == 0:

1806

self.setBasicHeader()

1807

self.setBasicHeader()

1807

1808

self.datablock[:,self.profileIndex,:] = self.dataOut.data

1809

self.datablock[:,self.profileIndex,:] = self.dataOut.data

1809

1810

self.profileIndex += 1

1811

self.profileIndex += 1

1811

1812

if self.hasAllDataInBuffer():

1813

if self.hasAllDataInBuffer():

1813

#if self.flagIsNewFile:

1814

#if self.flagIsNewFile:

1814

self.writeNextBlock()

1815

self.writeNextBlock()

1815

# self.setFirstHeader()

1816

# self.setFirstHeader()

1816

1817

return 1

1818

return 1

1818

1819

def __getProcessFlags(self):

1820

def __getProcessFlags(self):

1820

1821

processFlags = 0

1822

processFlags = 0

1822

1823

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

1824

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

1824

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

1825

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

1825

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

1826

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

1826

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

1827

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

1827

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

1828

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

1828

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

1829

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

1829

1830

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

1831

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

1831

1832

1833

1834

datatypeValueList = [PROCFLAG.DATATYPE_CHAR,

1835

datatypeValueList = [PROCFLAG.DATATYPE_CHAR,

1835

PROCFLAG.DATATYPE_SHORT,

1836

PROCFLAG.DATATYPE_SHORT,

1836

PROCFLAG.DATATYPE_LONG,

1837

PROCFLAG.DATATYPE_LONG,

1837

PROCFLAG.DATATYPE_INT64,

1838

PROCFLAG.DATATYPE_INT64,

1838

PROCFLAG.DATATYPE_FLOAT,

1839

PROCFLAG.DATATYPE_FLOAT,

1839

PROCFLAG.DATATYPE_DOUBLE]

1840

PROCFLAG.DATATYPE_DOUBLE]

1840

1841

1842

for index in range(len(dtypeList)):

1843

for index in range(len(dtypeList)):

1843

if self.dataOut.dtype == dtypeList[index]:

1844

if self.dataOut.dtype == dtypeList[index]:

1844

dtypeValue = datatypeValueList[index]

1845

dtypeValue = datatypeValueList[index]

1845

break

1846

break

1846

1847

processFlags += dtypeValue

1848

processFlags += dtypeValue

1848

1849

if self.dataOut.flagDecodeData:

1850

if self.dataOut.flagDecodeData:

1850

processFlags += PROCFLAG.DECODE_DATA

1851

processFlags += PROCFLAG.DECODE_DATA

1851

1852

if self.dataOut.flagDeflipData:

1853

if self.dataOut.flagDeflipData:

1853

processFlags += PROCFLAG.DEFLIP_DATA

1854

processFlags += PROCFLAG.DEFLIP_DATA

1854

1855

if self.dataOut.code != None:

1856

if self.dataOut.code != None:

1856

processFlags += PROCFLAG.DEFINE_PROCESS_CODE

1857

processFlags += PROCFLAG.DEFINE_PROCESS_CODE

1857

1858

if self.dataOut.nCohInt > 1:

1859

if self.dataOut.nCohInt > 1:

1859

processFlags += PROCFLAG.COHERENT_INTEGRATION

1860

processFlags += PROCFLAG.COHERENT_INTEGRATION

1860

1861

return processFlags

1862

return processFlags

1862

1863

1864

def __getBlockSize(self):

1865

def __getBlockSize(self):

1865

'''

1866

'''

1866

Este metodos determina el cantidad de bytes para un bloque de datos de tipo Voltage

1867

Este metodos determina el cantidad de bytes para un bloque de datos de tipo Voltage

1867

'''

1868

'''

1868

1869

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

1870

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

1870

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

1871

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

1871

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

1872

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

1872

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

1873

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

1873

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

1874

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

1874

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

1875

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

1875

1876

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

1877

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

1877

datatypeValueList = [1,2,4,8,4,8]

1878

datatypeValueList = [1,2,4,8,4,8]

1878

for index in range(len(dtypeList)):

1879

for index in range(len(dtypeList)):

1879

if self.dataOut.dtype == dtypeList[index]:

1880

if self.dataOut.dtype == dtypeList[index]:

1880

datatypeValue = datatypeValueList[index]

1881

datatypeValue = datatypeValueList[index]

1881

break

1882

break

1882

1883

blocksize = int(self.dataOut.nHeights * self.dataOut.nChannels * self.profilesPerBlock * datatypeValue * 2)

1884

blocksize = int(self.dataOut.nHeights * self.dataOut.nChannels * self.profilesPerBlock * datatypeValue * 2)

1884

1885

return blocksize

1886

return blocksize

1886

1887

def setFirstHeader(self):

1888

def setFirstHeader(self):

1888

1889

"""

1890

"""

1890

Obtiene una copia del First Header

1891

Obtiene una copia del First Header

1891

1892

Affected:

1893

Affected:

1893

self.systemHeaderObj

1894

self.systemHeaderObj

1894

self.radarControllerHeaderObj

1895

self.radarControllerHeaderObj

1895

self.dtype

1896

self.dtype

1896

1897

Return:

1898

Return:

1898

None

1899

None

1899

"""

1900

"""

1900

1901

self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()

1902

self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()

1902

self.systemHeaderObj.nChannels = self.dataOut.nChannels

1903

self.systemHeaderObj.nChannels = self.dataOut.nChannels

1903

self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()

1904

self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()

1904

1905

self.setBasicHeader()

1906

self.setBasicHeader()

1906

1907

processingHeaderSize = 40 # bytes

1908

processingHeaderSize = 40 # bytes

1908

self.processingHeaderObj.dtype = 0 # Voltage

1909

self.processingHeaderObj.dtype = 0 # Voltage

1909

self.processingHeaderObj.blockSize = self.__getBlockSize()

1910

self.processingHeaderObj.blockSize = self.__getBlockSize()

1910

self.processingHeaderObj.profilesPerBlock = self.profilesPerBlock

1911

self.processingHeaderObj.profilesPerBlock = self.profilesPerBlock

1911

self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile

1912

self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile

1912

self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows

1913

self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows

1913

self.processingHeaderObj.processFlags = self.__getProcessFlags()

1914

self.processingHeaderObj.processFlags = self.__getProcessFlags()

1914

self.processingHeaderObj.nCohInt = self.dataOut.nCohInt

1915

self.processingHeaderObj.nCohInt = self.dataOut.nCohInt

1915

self.processingHeaderObj.nIncohInt = 1 # Cuando la data de origen es de tipo Voltage

1916

self.processingHeaderObj.nIncohInt = 1 # Cuando la data de origen es de tipo Voltage

1916

self.processingHeaderObj.totalSpectra = 0 # Cuando la data de origen es de tipo Voltage

1917

self.processingHeaderObj.totalSpectra = 0 # Cuando la data de origen es de tipo Voltage

1917

1918

# if self.dataOut.code != None:

1919

# if self.dataOut.code != None:

1919

# self.processingHeaderObj.code = self.dataOut.code

1920

# self.processingHeaderObj.code = self.dataOut.code

1920

# self.processingHeaderObj.nCode = self.dataOut.nCode

1921

# self.processingHeaderObj.nCode = self.dataOut.nCode

1921

# self.processingHeaderObj.nBaud = self.dataOut.nBaud

1922

# self.processingHeaderObj.nBaud = self.dataOut.nBaud

1922

# codesize = int(8 + 4 * self.dataOut.nCode * self.dataOut.nBaud)

1923

# codesize = int(8 + 4 * self.dataOut.nCode * self.dataOut.nBaud)

1923

# processingHeaderSize += codesize

1924

# processingHeaderSize += codesize

1924

1925

if self.processingHeaderObj.nWindows != 0:

1926

if self.processingHeaderObj.nWindows != 0:

1926

self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]

1927

self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]

1927

self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

1928

self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

1928

self.processingHeaderObj.nHeights = self.dataOut.nHeights

1929

self.processingHeaderObj.nHeights = self.dataOut.nHeights

1929

self.processingHeaderObj.samplesWin = self.dataOut.nHeights

1930

self.processingHeaderObj.samplesWin = self.dataOut.nHeights

1930

processingHeaderSize += 12

1931

processingHeaderSize += 12

1931

1932

self.processingHeaderObj.size = processingHeaderSize

1933

self.processingHeaderObj.size = processingHeaderSize

1933

1934

class SpectraReader(JRODataReader):

1935

class SpectraReader(JRODataReader):

1935

"""

1936

"""

1936

Esta clase permite leer datos de espectros desde archivos procesados (.pdata). La lectura

1937

Esta clase permite leer datos de espectros desde archivos procesados (.pdata). La lectura

1937

de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones)

1938

de los datos siempre se realiza por bloques. Los datos leidos (array de 3 dimensiones)

1938

son almacenados en tres buffer's para el Self Spectra, el Cross Spectra y el DC Channel.

1939

son almacenados en tres buffer's para el Self Spectra, el Cross Spectra y el DC Channel.

1939

1940

paresCanalesIguales * alturas * perfiles (Self Spectra)

1941

paresCanalesIguales * alturas * perfiles (Self Spectra)

1941

paresCanalesDiferentes * alturas * perfiles (Cross Spectra)

1942

paresCanalesDiferentes * alturas * perfiles (Cross Spectra)

1942

canales * alturas (DC Channels)

1943

canales * alturas (DC Channels)

1943

1944

Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,

1945

Esta clase contiene instancias (objetos) de las clases BasicHeader, SystemHeader,

1945

RadarControllerHeader y Spectra. Los tres primeros se usan para almacenar informacion de la

1946

RadarControllerHeader y Spectra. Los tres primeros se usan para almacenar informacion de la

1946

cabecera de datos (metadata), y el cuarto (Spectra) para obtener y almacenar un bloque de

1947

cabecera de datos (metadata), y el cuarto (Spectra) para obtener y almacenar un bloque de

1947

datos desde el "buffer" cada vez que se ejecute el metodo "getData".

1948

datos desde el "buffer" cada vez que se ejecute el metodo "getData".

1948

1949

Example:

1950

Example:

1950

dpath = "/home/myuser/data"

1951

dpath = "/home/myuser/data"

1951

1952

startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)

1953

startTime = datetime.datetime(2010,1,20,0,0,0,0,0,0)

1953

1954

endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)

1955

endTime = datetime.datetime(2010,1,21,23,59,59,0,0,0)

1955

1956

readerObj = SpectraReader()

1957

readerObj = SpectraReader()

1957

1958

readerObj.setup(dpath, startTime, endTime)

1959

readerObj.setup(dpath, startTime, endTime)

1959

1960

while(True):

1961

while(True):

1961

1962

readerObj.getData()

1963

readerObj.getData()

1963

1964

print readerObj.data_spc

1965

print readerObj.data_spc

1965

1966

print readerObj.data_cspc

1967

print readerObj.data_cspc

1967

1968

print readerObj.data_dc

1969

print readerObj.data_dc

1969

1970

if readerObj.flagNoMoreFiles:

1971

if readerObj.flagNoMoreFiles:

1971

break

1972

break

1972

1973

"""

1974

"""

1974

1975

pts2read_SelfSpectra = 0

1976

pts2read_SelfSpectra = 0

1976

1977

pts2read_CrossSpectra = 0

1978

pts2read_CrossSpectra = 0

1978

1979

pts2read_DCchannels = 0

1980

pts2read_DCchannels = 0

1980

1981

ext = ".pdata"

1982

ext = ".pdata"

1982

1983

optchar = "P"

1984

optchar = "P"

1984

1985

dataOut = None

1986

dataOut = None

1986

1987

nRdChannels = None

1988

nRdChannels = None

1988

1989

nRdPairs = None

1990

nRdPairs = None

1990

1991

rdPairList = []

1992

rdPairList = []

1992

1993

def __init__(self):

1994

def __init__(self):

1994

"""

1995

"""

1995

Inicializador de la clase SpectraReader para la lectura de datos de espectros.

1996

Inicializador de la clase SpectraReader para la lectura de datos de espectros.

1996

1997

Inputs:

1998

Inputs:

1998

dataOut : Objeto de la clase Spectra. Este objeto sera utilizado para

1999

dataOut : Objeto de la clase Spectra. Este objeto sera utilizado para

1999

almacenar un perfil de datos cada vez que se haga un requerimiento

2000

almacenar un perfil de datos cada vez que se haga un requerimiento

2000

(getData). El perfil sera obtenido a partir del buffer de datos,

2001

(getData). El perfil sera obtenido a partir del buffer de datos,

2001

si el buffer esta vacio se hara un nuevo proceso de lectura de un

2002

si el buffer esta vacio se hara un nuevo proceso de lectura de un

2002

bloque de datos.

2003

bloque de datos.

2003

Si este parametro no es pasado se creara uno internamente.

2004

Si este parametro no es pasado se creara uno internamente.

2004

2005

Affected:

2006

Affected:

2006

self.dataOut

2007

self.dataOut

2007

2008

Return : None

2009

Return : None

2009

"""

2010

"""

2010

2011

self.isConfig = False

2012

self.isConfig = False

2012

2013

self.pts2read_SelfSpectra = 0

2014

self.pts2read_SelfSpectra = 0

2014

2015

self.pts2read_CrossSpectra = 0

2016

self.pts2read_CrossSpectra = 0

2016

2017

self.pts2read_DCchannels = 0

2018

self.pts2read_DCchannels = 0

2018

2019

self.datablock = None

2020

self.datablock = None

2020

2021

self.utc = None

2022

self.utc = None

2022

2023

self.ext = ".pdata"

2024

self.ext = ".pdata"

2024

2025

self.optchar = "P"

2026

self.optchar = "P"

2026

2027

self.basicHeaderObj = BasicHeader(LOCALTIME)

2028

self.basicHeaderObj = BasicHeader(LOCALTIME)

2028

2029

self.systemHeaderObj = SystemHeader()

2030

self.systemHeaderObj = SystemHeader()

2030

2031

self.radarControllerHeaderObj = RadarControllerHeader()

2032

self.radarControllerHeaderObj = RadarControllerHeader()

2032

2033

self.processingHeaderObj = ProcessingHeader()

2034

self.processingHeaderObj = ProcessingHeader()

2034

2035

self.online = 0

2036

self.online = 0

2036

2037

self.fp = None

2038

self.fp = None

2038

2039

self.idFile = None

2040

self.idFile = None

2040

2041

self.dtype = None

2042

self.dtype = None

2042

2043

self.fileSizeByHeader = None

2044

self.fileSizeByHeader = None

2044

2045

self.filenameList = []

2046

self.filenameList = []

2046

2047

self.filename = None

2048

self.filename = None

2048

2049

self.fileSize = None

2050

self.fileSize = None

2050

2051

self.firstHeaderSize = 0

2052

self.firstHeaderSize = 0

2052

2053

self.basicHeaderSize = 24

2054

self.basicHeaderSize = 24

2054

2055

self.pathList = []

2056

self.pathList = []

2056

2057

self.lastUTTime = 0

2058

self.lastUTTime = 0

2058

2059

self.maxTimeStep = 30

2060

self.maxTimeStep = 30

2060

2061

self.flagNoMoreFiles = 0

2062

self.flagNoMoreFiles = 0

2062

2063

self.set = 0

2064

self.set = 0

2064

2065

self.path = None

2066

self.path = None

2066

2067

self.delay = 60 #seconds

2068

self.delay = 60 #seconds

2068

2069

self.nTries = 3 #quantity tries

2070

self.nTries = 3 #quantity tries

2070

2071

self.nFiles = 3 #number of files for searching

2072

self.nFiles = 3 #number of files for searching

2072

2073

self.nReadBlocks = 0

2074

self.nReadBlocks = 0

2074

2075

self.flagIsNewFile = 1

2076

self.flagIsNewFile = 1

2076

2077

self.__isFirstTimeOnline = 1

2078

self.__isFirstTimeOnline = 1

2078

2079

self.ippSeconds = 0

2080

self.ippSeconds = 0

2080

2081

self.flagTimeBlock = 0

2082

self.flagTimeBlock = 0

2082

2083

self.flagIsNewBlock = 0

2084

self.flagIsNewBlock = 0

2084

2085

self.nTotalBlocks = 0

2086

self.nTotalBlocks = 0

2086

2087

self.blocksize = 0

2088

self.blocksize = 0

2088

2089

self.dataOut = self.createObjByDefault()

2090

self.dataOut = self.createObjByDefault()

2090

2091

self.profileIndex = 1 #Always

2092

self.profileIndex = 1 #Always

2092

2093

2094

def createObjByDefault(self):

2095

def createObjByDefault(self):

2095

2096

dataObj = Spectra()

2097

dataObj = Spectra()

2097

2098

return dataObj

2099

return dataObj

2099

2100

def __hasNotDataInBuffer(self):

2101

def __hasNotDataInBuffer(self):

2101

return 1

2102

return 1

2102

2103

2104

def getBlockDimension(self):

2105

def getBlockDimension(self):

2105

"""

2106

"""

2106

Obtiene la cantidad de puntos a leer por cada bloque de datos

2107

Obtiene la cantidad de puntos a leer por cada bloque de datos

2107

2108

Affected:

2109

Affected:

2109

self.nRdChannels

2110

self.nRdChannels

2110

self.nRdPairs

2111

self.nRdPairs

2111

self.pts2read_SelfSpectra

2112

self.pts2read_SelfSpectra

2112

self.pts2read_CrossSpectra

2113

self.pts2read_CrossSpectra

2113

self.pts2read_DCchannels

2114

self.pts2read_DCchannels

2114

self.blocksize

2115

self.blocksize

2115

self.dataOut.nChannels

2116

self.dataOut.nChannels

2116

self.dataOut.nPairs

2117

self.dataOut.nPairs

2117

2118

Return:

2119

Return:

2119

None

2120

None

2120

"""

2121

"""

2121

self.nRdChannels = 0

2122

self.nRdChannels = 0

2122

self.nRdPairs = 0

2123

self.nRdPairs = 0

2123

self.rdPairList = []

2124

self.rdPairList = []

2124

2125

for i in range(0, self.processingHeaderObj.totalSpectra*2, 2):

2126

for i in range(0, self.processingHeaderObj.totalSpectra*2, 2):

2126

if self.processingHeaderObj.spectraComb[i] == self.processingHeaderObj.spectraComb[i+1]:

2127

if self.processingHeaderObj.spectraComb[i] == self.processingHeaderObj.spectraComb[i+1]:

2127

self.nRdChannels = self.nRdChannels + 1 #par de canales iguales

2128

self.nRdChannels = self.nRdChannels + 1 #par de canales iguales

2128

else:

2129

else:

2129

self.nRdPairs = self.nRdPairs + 1 #par de canales diferentes

2130

self.nRdPairs = self.nRdPairs + 1 #par de canales diferentes

2130

self.rdPairList.append((self.processingHeaderObj.spectraComb[i], self.processingHeaderObj.spectraComb[i+1]))

2131

self.rdPairList.append((self.processingHeaderObj.spectraComb[i], self.processingHeaderObj.spectraComb[i+1]))

2131

2132

pts2read = self.processingHeaderObj.nHeights * self.processingHeaderObj.profilesPerBlock

2133

pts2read = self.processingHeaderObj.nHeights * self.processingHeaderObj.profilesPerBlock

2133

2134

self.pts2read_SelfSpectra = int(self.nRdChannels * pts2read)

2135

self.pts2read_SelfSpectra = int(self.nRdChannels * pts2read)

2135

self.blocksize = self.pts2read_SelfSpectra

2136

self.blocksize = self.pts2read_SelfSpectra

2136

2137

if self.processingHeaderObj.flag_cspc:

2138

if self.processingHeaderObj.flag_cspc:

2138

self.pts2read_CrossSpectra = int(self.nRdPairs * pts2read)

2139

self.pts2read_CrossSpectra = int(self.nRdPairs * pts2read)

2139

self.blocksize += self.pts2read_CrossSpectra

2140

self.blocksize += self.pts2read_CrossSpectra

2140

2141

if self.processingHeaderObj.flag_dc:

2142

if self.processingHeaderObj.flag_dc:

2142

self.pts2read_DCchannels = int(self.systemHeaderObj.nChannels * self.processingHeaderObj.nHeights)

2143

self.pts2read_DCchannels = int(self.systemHeaderObj.nChannels * self.processingHeaderObj.nHeights)

2143

self.blocksize += self.pts2read_DCchannels

2144

self.blocksize += self.pts2read_DCchannels

2144

2145

# self.blocksize = self.pts2read_SelfSpectra + self.pts2read_CrossSpectra + self.pts2read_DCchannels

2146

# self.blocksize = self.pts2read_SelfSpectra + self.pts2read_CrossSpectra + self.pts2read_DCchannels

2146

2147

2148

def readBlock(self):

2149

def readBlock(self):

2149

"""

2150

"""

2150

Lee el bloque de datos desde la posicion actual del puntero del archivo

2151

Lee el bloque de datos desde la posicion actual del puntero del archivo

2151

(self.fp) y actualiza todos los parametros relacionados al bloque de datos

2152

(self.fp) y actualiza todos los parametros relacionados al bloque de datos

2152

(metadata + data). La data leida es almacenada en el buffer y el contador del buffer

2153

(metadata + data). La data leida es almacenada en el buffer y el contador del buffer

2153

es seteado a 0

2154

es seteado a 0

2154

2155

Return: None

2156

Return: None

2156

2157

Variables afectadas:

2158

Variables afectadas:

2158

2159

self.flagIsNewFile

2160

self.flagIsNewFile

2160

self.flagIsNewBlock

2161

self.flagIsNewBlock

2161

self.nTotalBlocks

2162

self.nTotalBlocks

2162

self.data_spc

2163

self.data_spc

2163

self.data_cspc

2164

self.data_cspc

2164

self.data_dc

2165

self.data_dc

2165

2166

Exceptions:

2167

Exceptions:

2167

Si un bloque leido no es un bloque valido

2168

Si un bloque leido no es un bloque valido

2168

"""

2169

"""

2169

blockOk_flag = False

2170

blockOk_flag = False

2170

fpointer = self.fp.tell()

2171

fpointer = self.fp.tell()

2171

2172

spc = numpy.fromfile( self.fp, self.dtype[0], self.pts2read_SelfSpectra )

2173

spc = numpy.fromfile( self.fp, self.dtype[0], self.pts2read_SelfSpectra )

2173

spc = spc.reshape( (self.nRdChannels, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D

2174

spc = spc.reshape( (self.nRdChannels, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D

2174

2175

if self.processingHeaderObj.flag_cspc:

2176

if self.processingHeaderObj.flag_cspc:

2176

cspc = numpy.fromfile( self.fp, self.dtype, self.pts2read_CrossSpectra )

2177

cspc = numpy.fromfile( self.fp, self.dtype, self.pts2read_CrossSpectra )

2177

cspc = cspc.reshape( (self.nRdPairs, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D

2178

cspc = cspc.reshape( (self.nRdPairs, self.processingHeaderObj.nHeights, self.processingHeaderObj.profilesPerBlock) ) #transforma a un arreglo 3D

2178

2179

if self.processingHeaderObj.flag_dc:

2180

if self.processingHeaderObj.flag_dc:

2180

dc = numpy.fromfile( self.fp, self.dtype, self.pts2read_DCchannels ) #int(self.processingHeaderObj.nHeights*self.systemHeaderObj.nChannels) )

2181

dc = numpy.fromfile( self.fp, self.dtype, self.pts2read_DCchannels ) #int(self.processingHeaderObj.nHeights*self.systemHeaderObj.nChannels) )

2181

dc = dc.reshape( (self.systemHeaderObj.nChannels, self.processingHeaderObj.nHeights) ) #transforma a un arreglo 2D

2182

dc = dc.reshape( (self.systemHeaderObj.nChannels, self.processingHeaderObj.nHeights) ) #transforma a un arreglo 2D

2182

2183

2184

if not(self.processingHeaderObj.shif_fft):

2185

if not(self.processingHeaderObj.shif_fft):

2185

#desplaza a la derecha en el eje 2 determinadas posiciones

2186

#desplaza a la derecha en el eje 2 determinadas posiciones

2186

shift = int(self.processingHeaderObj.profilesPerBlock/2)

2187

shift = int(self.processingHeaderObj.profilesPerBlock/2)

2187

spc = numpy.roll( spc, shift , axis=2 )

2188

spc = numpy.roll( spc, shift , axis=2 )

2188

2189

if self.processingHeaderObj.flag_cspc:

2190

if self.processingHeaderObj.flag_cspc:

2190

#desplaza a la derecha en el eje 2 determinadas posiciones

2191

#desplaza a la derecha en el eje 2 determinadas posiciones

2191

cspc = numpy.roll( cspc, shift, axis=2 )

2192

cspc = numpy.roll( cspc, shift, axis=2 )

2192

2193

# self.processingHeaderObj.shif_fft = True

2194

# self.processingHeaderObj.shif_fft = True

2194

2195

spc = numpy.transpose( spc, (0,2,1) )

2196

spc = numpy.transpose( spc, (0,2,1) )

2196

self.data_spc = spc

2197

self.data_spc = spc

2197

2198

if self.processingHeaderObj.flag_cspc:

2199

if self.processingHeaderObj.flag_cspc:

2199

cspc = numpy.transpose( cspc, (0,2,1) )

2200

cspc = numpy.transpose( cspc, (0,2,1) )

2200

self.data_cspc = cspc['real'] + cspc['imag']*1j

2201

self.data_cspc = cspc['real'] + cspc['imag']*1j

2201

else:

2202

else:

2202

self.data_cspc = None

2203

self.data_cspc = None

2203

2204

if self.processingHeaderObj.flag_dc:

2205

if self.processingHeaderObj.flag_dc:

2205

self.data_dc = dc['real'] + dc['imag']*1j

2206

self.data_dc = dc['real'] + dc['imag']*1j

2206

else:

2207

else:

2207

self.data_dc = None

2208

self.data_dc = None

2208

2209

self.flagIsNewFile = 0

2210

self.flagIsNewFile = 0

2210

self.flagIsNewBlock = 1

2211

self.flagIsNewBlock = 1

2211

2212

self.nTotalBlocks += 1

2213

self.nTotalBlocks += 1

2213

self.nReadBlocks += 1

2214

self.nReadBlocks += 1

2214

2215

return 1

2216

return 1

2216

2217

def getFirstHeader(self):

2218

def getFirstHeader(self):

2218

2219

self.dataOut.dtype = self.dtype

2220

self.dataOut.dtype = self.dtype

2220

2221

self.dataOut.nPairs = self.nRdPairs

2222

self.dataOut.nPairs = self.nRdPairs

2222

2223

self.dataOut.pairsList = self.rdPairList

2224

self.dataOut.pairsList = self.rdPairList

2224

2225

self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock

2226

self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock

2226

2227

self.dataOut.nFFTPoints = self.processingHeaderObj.profilesPerBlock

2228

self.dataOut.nFFTPoints = self.processingHeaderObj.profilesPerBlock

2228

2229

self.dataOut.nCohInt = self.processingHeaderObj.nCohInt

2230

self.dataOut.nCohInt = self.processingHeaderObj.nCohInt

2230

2231

self.dataOut.nIncohInt = self.processingHeaderObj.nIncohInt

2232

self.dataOut.nIncohInt = self.processingHeaderObj.nIncohInt

2232

2233

xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight

2234

xf = self.processingHeaderObj.firstHeight + self.processingHeaderObj.nHeights*self.processingHeaderObj.deltaHeight

2234

2235

self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)

2236

self.dataOut.heightList = numpy.arange(self.processingHeaderObj.firstHeight, xf, self.processingHeaderObj.deltaHeight)

2236

2237

self.dataOut.channelList = range(self.systemHeaderObj.nChannels)

2238

self.dataOut.channelList = range(self.systemHeaderObj.nChannels)

2238

2239

self.dataOut.ippSeconds = self.ippSeconds

2240

self.dataOut.ippSeconds = self.ippSeconds

2240

2241

self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt * self.processingHeaderObj.nIncohInt * self.dataOut.nFFTPoints

2242

self.dataOut.timeInterval = self.ippSeconds * self.processingHeaderObj.nCohInt * self.processingHeaderObj.nIncohInt * self.dataOut.nFFTPoints

2242

2243

self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()

2244

self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()

2244

2245

self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()

2246

self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()

2246

2247

self.dataOut.flagShiftFFT = self.processingHeaderObj.shif_fft

2248

self.dataOut.flagShiftFFT = self.processingHeaderObj.shif_fft

2248

2249

self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada

2250

self.dataOut.flagDecodeData = False #asumo q la data no esta decodificada

2250

2251

self.dataOut.flagDeflipData = True #asumo q la data no esta sin flip

2252

self.dataOut.flagDeflipData = True #asumo q la data no esta sin flip

2252

2253

if self.radarControllerHeaderObj.code != None:

2254

if self.radarControllerHeaderObj.code != None:

2254

2255

self.dataOut.nCode = self.radarControllerHeaderObj.nCode

2256

self.dataOut.nCode = self.radarControllerHeaderObj.nCode

2256

2257

self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud

2258

self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud

2258

2259

self.dataOut.code = self.radarControllerHeaderObj.code

2260

self.dataOut.code = self.radarControllerHeaderObj.code

2260

2261

self.dataOut.flagDecodeData = True

2262

self.dataOut.flagDecodeData = True

2262

2263

def getData(self):

2264

def getData(self):

2264

"""

2265

"""

2265

Copia el buffer de lectura a la clase "Spectra",

2266

Copia el buffer de lectura a la clase "Spectra",

2266

con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de

2267

con todos los parametros asociados a este (metadata). cuando no hay datos en el buffer de

2267

lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"

2268

lectura es necesario hacer una nueva lectura de los bloques de datos usando "readNextBlock"

2268

2269

Return:

2270

Return:

2270

0 : Si no hay mas archivos disponibles

2271

0 : Si no hay mas archivos disponibles

2271

1 : Si hizo una buena copia del buffer

2272

1 : Si hizo una buena copia del buffer

2272

2273

Affected:

2274

Affected:

2274

self.dataOut

2275

self.dataOut

2275

2276

self.flagTimeBlock

2277

self.flagTimeBlock

2277

self.flagIsNewBlock

2278

self.flagIsNewBlock

2278

"""

2279

"""

2279

2280

if self.flagNoMoreFiles:

2281

if self.flagNoMoreFiles:

2281

self.dataOut.flagNoData = True

2282

self.dataOut.flagNoData = True

2282

print 'Process finished'

2283

print 'Process finished'

2283

return 0

2284

return 0

2284

2285

self.flagTimeBlock = 0

2286

self.flagTimeBlock = 0

2286

self.flagIsNewBlock = 0

2287

self.flagIsNewBlock = 0

2287

2288

if self.__hasNotDataInBuffer():

2289

if self.__hasNotDataInBuffer():

2289

2290

if not( self.readNextBlock() ):

2291

if not( self.readNextBlock() ):

2291

self.dataOut.flagNoData = True

2292

self.dataOut.flagNoData = True

2292

return 0

2293

return 0

2293

2294

#data es un numpy array de 3 dmensiones (perfiles, alturas y canales)

2295

#data es un numpy array de 3 dmensiones (perfiles, alturas y canales)

2295

2296

if self.data_dc == None:

2297

if self.data_dc == None:

2297

self.dataOut.flagNoData = True

2298

self.dataOut.flagNoData = True

2298

return 0

2299

return 0

2299

2300

self.getBasicHeader()

2301

self.getBasicHeader()

2301

2302

self.getFirstHeader()

2303

self.getFirstHeader()

2303

2304

self.dataOut.data_spc = self.data_spc

2305

self.dataOut.data_spc = self.data_spc

2305

2306

self.dataOut.data_cspc = self.data_cspc

2307

self.dataOut.data_cspc = self.data_cspc

2307

2308

self.dataOut.data_dc = self.data_dc

2309

self.dataOut.data_dc = self.data_dc

2309

2310

self.dataOut.flagNoData = False

2311

self.dataOut.flagNoData = False

2311

2312

self.dataOut.realtime = self.online

2313

self.dataOut.realtime = self.online

2313

2314

return self.dataOut.data_spc

2315

return self.dataOut.data_spc

2315

2316

2317

class SpectraWriter(JRODataWriter):

2318

class SpectraWriter(JRODataWriter):

2318

2319

"""

2320

"""

2320

Esta clase permite escribir datos de espectros a archivos procesados (.pdata). La escritura

2321

Esta clase permite escribir datos de espectros a archivos procesados (.pdata). La escritura

2321

de los datos siempre se realiza por bloques.

2322

de los datos siempre se realiza por bloques.

2322

"""

2323

"""

2323

2324

ext = ".pdata"

2325

ext = ".pdata"

2325

2326

optchar = "P"

2327

optchar = "P"

2327

2328

shape_spc_Buffer = None

2329

shape_spc_Buffer = None

2329

2330

shape_cspc_Buffer = None

2331

shape_cspc_Buffer = None

2331

2332

shape_dc_Buffer = None

2333

shape_dc_Buffer = None

2333

2334

data_spc = None

2335

data_spc = None

2335

2336

data_cspc = None

2337

data_cspc = None

2337

2338

data_dc = None

2339

data_dc = None

2339

2340

# dataOut = None

2341

# dataOut = None

2341

2342

def __init__(self):

2343

def __init__(self):

2343

"""

2344

"""

2344

Inicializador de la clase SpectraWriter para la escritura de datos de espectros.

2345

Inicializador de la clase SpectraWriter para la escritura de datos de espectros.

2345

2346

Affected:

2347

Affected:

2347

self.dataOut

2348

self.dataOut

2348

self.basicHeaderObj

2349

self.basicHeaderObj

2349

self.systemHeaderObj

2350

self.systemHeaderObj

2350

self.radarControllerHeaderObj

2351

self.radarControllerHeaderObj

2351

self.processingHeaderObj

2352

self.processingHeaderObj

2352

2353

Return: None

2354

Return: None

2354

"""

2355

"""

2355

2356

self.isConfig = False

2357

self.isConfig = False

2357

2358

self.nTotalBlocks = 0

2359

self.nTotalBlocks = 0

2359

2360

self.data_spc = None

2361

self.data_spc = None

2361

2362

self.data_cspc = None

2363

self.data_cspc = None

2363

2364

self.data_dc = None

2365

self.data_dc = None

2365

2366

self.fp = None

2367

self.fp = None

2367

2368

self.flagIsNewFile = 1

2369

self.flagIsNewFile = 1

2369

2370

self.nTotalBlocks = 0

2371

self.nTotalBlocks = 0

2371

2372

self.flagIsNewBlock = 0

2373

self.flagIsNewBlock = 0

2373

2374

self.setFile = None

2375

self.setFile = None

2375

2376

self.dtype = None

2377

self.dtype = None

2377

2378

self.path = None

2379

self.path = None

2379

2380

self.noMoreFiles = 0

2381

self.noMoreFiles = 0

2381

2382

self.filename = None

2383

self.filename = None

2383

2384

self.basicHeaderObj = BasicHeader(LOCALTIME)

2385

self.basicHeaderObj = BasicHeader(LOCALTIME)

2385

2386

self.systemHeaderObj = SystemHeader()

2387

self.systemHeaderObj = SystemHeader()

2387

2388

self.radarControllerHeaderObj = RadarControllerHeader()

2389

self.radarControllerHeaderObj = RadarControllerHeader()

2389

2390

self.processingHeaderObj = ProcessingHeader()

2391

self.processingHeaderObj = ProcessingHeader()

2391

2392

2393

def hasAllDataInBuffer(self):

2394

def hasAllDataInBuffer(self):

2394

return 1

2395

return 1

2395

2396

2397

def setBlockDimension(self):

2398

def setBlockDimension(self):

2398

"""

2399

"""

2399

Obtiene las formas dimensionales del los subbloques de datos que componen un bloque

2400

Obtiene las formas dimensionales del los subbloques de datos que componen un bloque

2400

2401

Affected:

2402

Affected:

2402

self.shape_spc_Buffer

2403

self.shape_spc_Buffer

2403

self.shape_cspc_Buffer

2404

self.shape_cspc_Buffer

2404

self.shape_dc_Buffer

2405

self.shape_dc_Buffer

2405

2406

Return: None

2407

Return: None

2407

"""

2408

"""

2408

self.shape_spc_Buffer = (self.dataOut.nChannels,

2409

self.shape_spc_Buffer = (self.dataOut.nChannels,

2409

self.processingHeaderObj.nHeights,

2410

self.processingHeaderObj.nHeights,

2410

self.processingHeaderObj.profilesPerBlock)

2411

self.processingHeaderObj.profilesPerBlock)

2411

2412

self.shape_cspc_Buffer = (self.dataOut.nPairs,

2413

self.shape_cspc_Buffer = (self.dataOut.nPairs,

2413

self.processingHeaderObj.nHeights,

2414

self.processingHeaderObj.nHeights,

2414

self.processingHeaderObj.profilesPerBlock)

2415

self.processingHeaderObj.profilesPerBlock)

2415

2416

self.shape_dc_Buffer = (self.dataOut.nChannels,

2417

self.shape_dc_Buffer = (self.dataOut.nChannels,

2417

self.processingHeaderObj.nHeights)

2418

self.processingHeaderObj.nHeights)

2418

2419

2420

def writeBlock(self):

2421

def writeBlock(self):

2421

"""

2422

"""

2422

Escribe el buffer en el file designado

2423

Escribe el buffer en el file designado

2423

2424

Affected:

2425

Affected:

2425

self.data_spc

2426

self.data_spc

2426

self.data_cspc

2427

self.data_cspc

2427

self.data_dc

2428

self.data_dc

2428

self.flagIsNewFile

2429

self.flagIsNewFile

2429

self.flagIsNewBlock

2430

self.flagIsNewBlock

2430

self.nTotalBlocks

2431

self.nTotalBlocks

2431

self.nWriteBlocks

2432

self.nWriteBlocks

2432

2433

Return: None

2434

Return: None

2434

"""

2435

"""

2435

2436

spc = numpy.transpose( self.data_spc, (0,2,1) )

2437

spc = numpy.transpose( self.data_spc, (0,2,1) )

2437

if not( self.processingHeaderObj.shif_fft ):

2438

if not( self.processingHeaderObj.shif_fft ):

2438

spc = numpy.roll( spc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones

2439

spc = numpy.roll( spc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones

2439

data = spc.reshape((-1))

2440

data = spc.reshape((-1))

2440

data = data.astype(self.dtype[0])

2441

data = data.astype(self.dtype[0])

2441

data.tofile(self.fp)

2442

data.tofile(self.fp)

2442

2443

if self.data_cspc != None:

2444

if self.data_cspc != None:

2444

data = numpy.zeros( self.shape_cspc_Buffer, self.dtype )

2445

data = numpy.zeros( self.shape_cspc_Buffer, self.dtype )

2445

cspc = numpy.transpose( self.data_cspc, (0,2,1) )

2446

cspc = numpy.transpose( self.data_cspc, (0,2,1) )

2446

if not( self.processingHeaderObj.shif_fft ):

2447

if not( self.processingHeaderObj.shif_fft ):

2447

cspc = numpy.roll( cspc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones

2448

cspc = numpy.roll( cspc, self.processingHeaderObj.profilesPerBlock/2, axis=2 ) #desplaza a la derecha en el eje 2 determinadas posiciones

2448

data['real'] = cspc.real

2449

data['real'] = cspc.real

2449

data['imag'] = cspc.imag

2450

data['imag'] = cspc.imag

2450

data = data.reshape((-1))

2451

data = data.reshape((-1))

2451

data.tofile(self.fp)

2452

data.tofile(self.fp)

2452

2453

if self.data_dc != None:

2454

if self.data_dc != None:

2454

data = numpy.zeros( self.shape_dc_Buffer, self.dtype )

2455

data = numpy.zeros( self.shape_dc_Buffer, self.dtype )

2455

dc = self.data_dc

2456

dc = self.data_dc

2456

data['real'] = dc.real

2457

data['real'] = dc.real

2457

data['imag'] = dc.imag

2458

data['imag'] = dc.imag

2458

data = data.reshape((-1))

2459

data = data.reshape((-1))

2459

data.tofile(self.fp)

2460

data.tofile(self.fp)

2460

2461

self.data_spc.fill(0)

2462

self.data_spc.fill(0)

2462

2463

if self.data_dc != None:

2464

if self.data_dc != None:

2464

self.data_dc.fill(0)

2465

self.data_dc.fill(0)

2465

2466

if self.data_cspc != None:

2467

if self.data_cspc != None:

2467

self.data_cspc.fill(0)

2468

self.data_cspc.fill(0)

2468

2469

self.flagIsNewFile = 0

2470

self.flagIsNewFile = 0

2470

self.flagIsNewBlock = 1

2471

self.flagIsNewBlock = 1

2471

self.nTotalBlocks += 1

2472

self.nTotalBlocks += 1

2472

self.nWriteBlocks += 1

2473

self.nWriteBlocks += 1

2473

self.blockIndex += 1

2474

self.blockIndex += 1

2474

2475

2476

def putData(self):

2477

def putData(self):

2477

"""

2478

"""

2478

Setea un bloque de datos y luego los escribe en un file

2479

Setea un bloque de datos y luego los escribe en un file

2479

2480

Affected:

2481

Affected:

2481

self.data_spc

2482

self.data_spc

2482

self.data_cspc

2483

self.data_cspc

2483

self.data_dc

2484

self.data_dc

2484

2485

Return:

2486

Return:

2486

0 : Si no hay data o no hay mas files que puedan escribirse

2487

0 : Si no hay data o no hay mas files que puedan escribirse

2487

1 : Si se escribio la data de un bloque en un file

2488

1 : Si se escribio la data de un bloque en un file

2488

"""

2489

"""

2489

2490

if self.dataOut.flagNoData:

2491

if self.dataOut.flagNoData:

2491

return 0

2492

return 0

2492

2493

self.flagIsNewBlock = 0

2494

self.flagIsNewBlock = 0

2494

2495

if self.dataOut.flagTimeBlock:

2496

if self.dataOut.flagTimeBlock:

2496

self.data_spc.fill(0)

2497

self.data_spc.fill(0)

2497

self.data_cspc.fill(0)

2498

self.data_cspc.fill(0)

2498

self.data_dc.fill(0)

2499

self.data_dc.fill(0)

2499

self.setNextFile()

2500

self.setNextFile()

2500

2501

if self.flagIsNewFile == 0:

2502

if self.flagIsNewFile == 0:

2502

self.setBasicHeader()

2503

self.setBasicHeader()

2503

2504

self.data_spc = self.dataOut.data_spc.copy()

2505

self.data_spc = self.dataOut.data_spc.copy()

2505

if self.dataOut.data_cspc != None:

2506

if self.dataOut.data_cspc != None:

2506

self.data_cspc = self.dataOut.data_cspc.copy()

2507

self.data_cspc = self.dataOut.data_cspc.copy()

2507

self.data_dc = self.dataOut.data_dc.copy()

2508

self.data_dc = self.dataOut.data_dc.copy()

2508

2509

# #self.processingHeaderObj.dataBlocksPerFile)

2510

# #self.processingHeaderObj.dataBlocksPerFile)

2510

if self.hasAllDataInBuffer():

2511

if self.hasAllDataInBuffer():

2511

# self.setFirstHeader()

2512

# self.setFirstHeader()

2512

self.writeNextBlock()

2513

self.writeNextBlock()

2513

2514

return 1

2515

return 1

2515

2516

2517

def __getProcessFlags(self):

2518

def __getProcessFlags(self):

2518

2519

processFlags = 0

2520

processFlags = 0

2520

2521

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

2522

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

2522

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

2523

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

2523

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

2524

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

2524

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

2525

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

2525

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

2526

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

2526

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

2527

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

2527

2528

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

2529

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

2529

2530

2531

2532

datatypeValueList = [PROCFLAG.DATATYPE_CHAR,

2533

datatypeValueList = [PROCFLAG.DATATYPE_CHAR,

2533

PROCFLAG.DATATYPE_SHORT,

2534

PROCFLAG.DATATYPE_SHORT,

2534

PROCFLAG.DATATYPE_LONG,

2535

PROCFLAG.DATATYPE_LONG,

2535

PROCFLAG.DATATYPE_INT64,

2536

PROCFLAG.DATATYPE_INT64,

2536

PROCFLAG.DATATYPE_FLOAT,

2537

PROCFLAG.DATATYPE_FLOAT,

2537

PROCFLAG.DATATYPE_DOUBLE]

2538

PROCFLAG.DATATYPE_DOUBLE]

2538

2539

2540

for index in range(len(dtypeList)):

2541

for index in range(len(dtypeList)):

2541

if self.dataOut.dtype == dtypeList[index]:

2542

if self.dataOut.dtype == dtypeList[index]:

2542

dtypeValue = datatypeValueList[index]

2543

dtypeValue = datatypeValueList[index]

2543

break

2544

break

2544

2545

processFlags += dtypeValue

2546

processFlags += dtypeValue

2546

2547

if self.dataOut.flagDecodeData:

2548

if self.dataOut.flagDecodeData:

2548

processFlags += PROCFLAG.DECODE_DATA

2549

processFlags += PROCFLAG.DECODE_DATA

2549

2550

if self.dataOut.flagDeflipData:

2551

if self.dataOut.flagDeflipData:

2551

processFlags += PROCFLAG.DEFLIP_DATA

2552

processFlags += PROCFLAG.DEFLIP_DATA

2552

2553

if self.dataOut.code != None:

2554

if self.dataOut.code != None:

2554

processFlags += PROCFLAG.DEFINE_PROCESS_CODE

2555

processFlags += PROCFLAG.DEFINE_PROCESS_CODE

2555

2556

if self.dataOut.nIncohInt > 1:

2557

if self.dataOut.nIncohInt > 1:

2557

processFlags += PROCFLAG.INCOHERENT_INTEGRATION

2558

processFlags += PROCFLAG.INCOHERENT_INTEGRATION

2558

2559

if self.dataOut.data_dc != None:

2560

if self.dataOut.data_dc != None:

2560

processFlags += PROCFLAG.SAVE_CHANNELS_DC

2561

processFlags += PROCFLAG.SAVE_CHANNELS_DC

2561

2562

return processFlags

2563

return processFlags

2563

2564

2565

def __getBlockSize(self):

2566

def __getBlockSize(self):

2566

'''

2567

'''

2567

Este metodos determina el cantidad de bytes para un bloque de datos de tipo Spectra

2568

Este metodos determina el cantidad de bytes para un bloque de datos de tipo Spectra

2568

'''

2569

'''

2569

2570

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

2571

dtype0 = numpy.dtype([('real','<i1'),('imag','<i1')])

2571

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

2572

dtype1 = numpy.dtype([('real','<i2'),('imag','<i2')])

2572

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

2573

dtype2 = numpy.dtype([('real','<i4'),('imag','<i4')])

2573

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

2574

dtype3 = numpy.dtype([('real','<i8'),('imag','<i8')])

2574

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

2575

dtype4 = numpy.dtype([('real','<f4'),('imag','<f4')])

2575

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

2576

dtype5 = numpy.dtype([('real','<f8'),('imag','<f8')])

2576

2577

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

2578

dtypeList = [dtype0, dtype1, dtype2, dtype3, dtype4, dtype5]

2578

datatypeValueList = [1,2,4,8,4,8]

2579

datatypeValueList = [1,2,4,8,4,8]

2579

for index in range(len(dtypeList)):

2580

for index in range(len(dtypeList)):

2580

if self.dataOut.dtype == dtypeList[index]:

2581

if self.dataOut.dtype == dtypeList[index]:

2581

datatypeValue = datatypeValueList[index]

2582

datatypeValue = datatypeValueList[index]

2582

break

2583

break

2583

2584

2585

pts2write = self.dataOut.nHeights * self.dataOut.nFFTPoints

2586

pts2write = self.dataOut.nHeights * self.dataOut.nFFTPoints

2586

2587

pts2write_SelfSpectra = int(self.dataOut.nChannels * pts2write)

2588

pts2write_SelfSpectra = int(self.dataOut.nChannels * pts2write)

2588

blocksize = (pts2write_SelfSpectra*datatypeValue)

2589

blocksize = (pts2write_SelfSpectra*datatypeValue)

2589

2590

if self.dataOut.data_cspc != None:

2591

if self.dataOut.data_cspc != None:

2591

pts2write_CrossSpectra = int(self.dataOut.nPairs * pts2write)

2592

pts2write_CrossSpectra = int(self.dataOut.nPairs * pts2write)

2592

blocksize += (pts2write_CrossSpectra*datatypeValue*2)

2593

blocksize += (pts2write_CrossSpectra*datatypeValue*2)

2593

2594

if self.dataOut.data_dc != None:

2595

if self.dataOut.data_dc != None:

2595

pts2write_DCchannels = int(self.dataOut.nChannels * self.dataOut.nHeights)

2596

pts2write_DCchannels = int(self.dataOut.nChannels * self.dataOut.nHeights)

2596

blocksize += (pts2write_DCchannels*datatypeValue*2)

2597

blocksize += (pts2write_DCchannels*datatypeValue*2)

2597

2598

blocksize = blocksize #* datatypeValue * 2 #CORREGIR ESTO

2599

blocksize = blocksize #* datatypeValue * 2 #CORREGIR ESTO

2599

2600

return blocksize

2601

return blocksize

2601

2602

def setFirstHeader(self):

2603

def setFirstHeader(self):

2603

2604

"""

2605

"""

2605

Obtiene una copia del First Header

2606

Obtiene una copia del First Header

2606

2607

Affected:

2608

Affected:

2608

self.systemHeaderObj

2609

self.systemHeaderObj

2609

self.radarControllerHeaderObj

2610

self.radarControllerHeaderObj

2610

self.dtype

2611

self.dtype

2611

2612

Return:

2613

Return:

2613

None

2614

None

2614

"""

2615

"""

2615

2616

self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()

2617

self.systemHeaderObj = self.dataOut.systemHeaderObj.copy()

2617

self.systemHeaderObj.nChannels = self.dataOut.nChannels

2618

self.systemHeaderObj.nChannels = self.dataOut.nChannels

2618

self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()

2619

self.radarControllerHeaderObj = self.dataOut.radarControllerHeaderObj.copy()

2619

old_code_size = self.dataOut.radarControllerHeaderObj.code_size

2620

old_code_size = self.dataOut.radarControllerHeaderObj.code_size

2620

new_code_size = int(numpy.ceil(self.dataOut.nBaud/32.))*self.dataOut.nCode*4

2621

new_code_size = int(numpy.ceil(self.dataOut.nBaud/32.))*self.dataOut.nCode*4

2621

self.radarControllerHeaderObj.size = self.radarControllerHeaderObj.size - old_code_size + new_code_size

2622

self.radarControllerHeaderObj.size = self.radarControllerHeaderObj.size - old_code_size + new_code_size

2622

2623

self.setBasicHeader()

2624

self.setBasicHeader()

2624

2625

processingHeaderSize = 40 # bytes

2626

processingHeaderSize = 40 # bytes

2626

self.processingHeaderObj.dtype = 1 # Spectra

2627

self.processingHeaderObj.dtype = 1 # Spectra

2627

self.processingHeaderObj.blockSize = self.__getBlockSize()

2628

self.processingHeaderObj.blockSize = self.__getBlockSize()

2628

self.processingHeaderObj.profilesPerBlock = self.dataOut.nFFTPoints

2629

self.processingHeaderObj.profilesPerBlock = self.dataOut.nFFTPoints

2629

self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile

2630

self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile

2630

self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows

2631

self.processingHeaderObj.nWindows = 1 #podria ser 1 o self.dataOut.processingHeaderObj.nWindows

2631

self.processingHeaderObj.processFlags = self.__getProcessFlags()

2632

self.processingHeaderObj.processFlags = self.__getProcessFlags()

2632

self.processingHeaderObj.nCohInt = self.dataOut.nCohInt# Se requiere para determinar el valor de timeInterval

2633

self.processingHeaderObj.nCohInt = self.dataOut.nCohInt# Se requiere para determinar el valor de timeInterval

2633

self.processingHeaderObj.nIncohInt = self.dataOut.nIncohInt

2634

self.processingHeaderObj.nIncohInt = self.dataOut.nIncohInt

2634

self.processingHeaderObj.totalSpectra = self.dataOut.nPairs + self.dataOut.nChannels

2635

self.processingHeaderObj.totalSpectra = self.dataOut.nPairs + self.dataOut.nChannels

2635

self.processingHeaderObj.shif_fft = self.dataOut.flagShiftFFT

2636

self.processingHeaderObj.shif_fft = self.dataOut.flagShiftFFT

2636

2637

if self.processingHeaderObj.totalSpectra > 0:

2638

if self.processingHeaderObj.totalSpectra > 0:

2638

channelList = []

2639

channelList = []

2639

for channel in range(self.dataOut.nChannels):

2640

for channel in range(self.dataOut.nChannels):

2640

channelList.append(channel)

2641

channelList.append(channel)

2641

channelList.append(channel)

2642

channelList.append(channel)

2642

2643

pairsList = []

2644

pairsList = []

2644

if self.dataOut.nPairs > 0:

2645

if self.dataOut.nPairs > 0:

2645

for pair in self.dataOut.pairsList:

2646

for pair in self.dataOut.pairsList:

2646

pairsList.append(pair[0])

2647

pairsList.append(pair[0])

2647

pairsList.append(pair[1])

2648

pairsList.append(pair[1])

2648

2649

spectraComb = channelList + pairsList

2650

spectraComb = channelList + pairsList

2650

spectraComb = numpy.array(spectraComb,dtype="u1")

2651

spectraComb = numpy.array(spectraComb,dtype="u1")

2651

self.processingHeaderObj.spectraComb = spectraComb

2652

self.processingHeaderObj.spectraComb = spectraComb

2652

sizeOfSpcComb = len(spectraComb)

2653

sizeOfSpcComb = len(spectraComb)

2653

processingHeaderSize += sizeOfSpcComb

2654

processingHeaderSize += sizeOfSpcComb

2654

2655

# The processing header should not have information about code

2656

# The processing header should not have information about code

2656

# if self.dataOut.code != None:

2657

# if self.dataOut.code != None:

2657

# self.processingHeaderObj.code = self.dataOut.code

2658

# self.processingHeaderObj.code = self.dataOut.code

2658

# self.processingHeaderObj.nCode = self.dataOut.nCode

2659

# self.processingHeaderObj.nCode = self.dataOut.nCode

2659

# self.processingHeaderObj.nBaud = self.dataOut.nBaud

2660

# self.processingHeaderObj.nBaud = self.dataOut.nBaud

2660

# nCodeSize = 4 # bytes

2661

# nCodeSize = 4 # bytes

2661

# nBaudSize = 4 # bytes

2662

# nBaudSize = 4 # bytes

2662

# codeSize = 4 # bytes

2663

# codeSize = 4 # bytes

2663

# sizeOfCode = int(nCodeSize + nBaudSize + codeSize * self.dataOut.nCode * self.dataOut.nBaud)

2664

# sizeOfCode = int(nCodeSize + nBaudSize + codeSize * self.dataOut.nCode * self.dataOut.nBaud)

2664

# processingHeaderSize += sizeOfCode

2665

# processingHeaderSize += sizeOfCode

2665

2666

if self.processingHeaderObj.nWindows != 0:

2667

if self.processingHeaderObj.nWindows != 0:

2667

self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]

2668

self.processingHeaderObj.firstHeight = self.dataOut.heightList[0]

2668

self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

2669

self.processingHeaderObj.deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

2669

self.processingHeaderObj.nHeights = self.dataOut.nHeights

2670

self.processingHeaderObj.nHeights = self.dataOut.nHeights

2670

self.processingHeaderObj.samplesWin = self.dataOut.nHeights

2671

self.processingHeaderObj.samplesWin = self.dataOut.nHeights

2671

sizeOfFirstHeight = 4

2672

sizeOfFirstHeight = 4

2672

sizeOfdeltaHeight = 4

2673

sizeOfdeltaHeight = 4

2673

sizeOfnHeights = 4

2674

sizeOfnHeights = 4

2674

sizeOfWindows = (sizeOfFirstHeight + sizeOfdeltaHeight + sizeOfnHeights)*self.processingHeaderObj.nWindows

2675

sizeOfWindows = (sizeOfFirstHeight + sizeOfdeltaHeight + sizeOfnHeights)*self.processingHeaderObj.nWindows

2675

processingHeaderSize += sizeOfWindows

2676

processingHeaderSize += sizeOfWindows

2676

2677

self.processingHeaderObj.size = processingHeaderSize

2678

self.processingHeaderObj.size = processingHeaderSize

2678

2679

class SpectraHeisWriter(Operation):

2680

class SpectraHeisWriter(Operation):

2680

# set = None

2681

# set = None

2681

setFile = None

2682

setFile = None

2682

idblock = None

2683

idblock = None

2683

doypath = None

2684

doypath = None

2684

subfolder = None

2685

subfolder = None

2685

2686

def __init__(self):

2687

def __init__(self):

2687

self.wrObj = FITS()

2688

self.wrObj = FITS()

2688

# self.dataOut = dataOut

2689

# self.dataOut = dataOut

2689

self.nTotalBlocks=0

2690

self.nTotalBlocks=0

2690

# self.set = None

2691

# self.set = None

2691

self.setFile = None

2692

self.setFile = None

2692

self.idblock = 0

2693

self.idblock = 0

2693

self.wrpath = None

2694

self.wrpath = None

2694

self.doypath = None

2695

self.doypath = None

2695

self.subfolder = None

2696

self.subfolder = None

2696

self.isConfig = False

2697

self.isConfig = False

2697

2698

def isNumber(str):

2699

def isNumber(str):

2699

"""

2700

"""

2700

Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.

2701

Chequea si el conjunto de caracteres que componen un string puede ser convertidos a un numero.

2701

2702

Excepciones:

2703

Excepciones:

2703

Si un determinado string no puede ser convertido a numero

2704

Si un determinado string no puede ser convertido a numero

2704

Input:

2705

Input:

2705

str, string al cual se le analiza para determinar si convertible a un numero o no

2706

str, string al cual se le analiza para determinar si convertible a un numero o no

2706

2707

Return:

2708

Return:

2708

True : si el string es uno numerico

2709

True : si el string es uno numerico

2709

False : no es un string numerico

2710

False : no es un string numerico

2710

"""

2711

"""

2711

try:

2712

try:

2712

float( str )

2713

float( str )

2713

return True

2714

return True

2714

except:

2715

except:

2715

return False

2716

return False

2716

2717

def setup(self, dataOut, wrpath):

2718

def setup(self, dataOut, wrpath):

2718

2719

if not(os.path.exists(wrpath)):

2720

if not(os.path.exists(wrpath)):

2720

os.mkdir(wrpath)

2721

os.mkdir(wrpath)

2721

2722

self.wrpath = wrpath

2723

self.wrpath = wrpath

2723

# self.setFile = 0

2724

# self.setFile = 0

2724

self.dataOut = dataOut

2725

self.dataOut = dataOut

2725

2726

def putData(self):

2727

def putData(self):

2727

name= time.localtime( self.dataOut.utctime)

2728

name= time.localtime( self.dataOut.utctime)

2728

ext=".fits"

2729

ext=".fits"

2729

2730

if self.doypath == None:

2731

if self.doypath == None:

2731

self.subfolder = 'F%4.4d%3.3d_%d' % (name.tm_year,name.tm_yday,time.mktime(datetime.datetime.now().timetuple()))

2732

self.subfolder = 'F%4.4d%3.3d_%d' % (name.tm_year,name.tm_yday,time.mktime(datetime.datetime.now().timetuple()))

2732

self.doypath = os.path.join( self.wrpath, self.subfolder )

2733

self.doypath = os.path.join( self.wrpath, self.subfolder )

2733

os.mkdir(self.doypath)

2734

os.mkdir(self.doypath)

2734

2735

if self.setFile == None:

2736

if self.setFile == None:

2736

# self.set = self.dataOut.set

2737

# self.set = self.dataOut.set

2737

self.setFile = 0

2738

self.setFile = 0

2738

# if self.set != self.dataOut.set:

2739

# if self.set != self.dataOut.set:

2739

## self.set = self.dataOut.set

2740

## self.set = self.dataOut.set

2740

# self.setFile = 0

2741

# self.setFile = 0

2741

2742

#make the filename

2743

#make the filename

2743

file = 'D%4.4d%3.3d_%3.3d%s' % (name.tm_year,name.tm_yday,self.setFile,ext)

2744

file = 'D%4.4d%3.3d_%3.3d%s' % (name.tm_year,name.tm_yday,self.setFile,ext)

2744

2745

filename = os.path.join(self.wrpath,self.subfolder, file)

2746

filename = os.path.join(self.wrpath,self.subfolder, file)

2746

2747

idblock = numpy.array([self.idblock],dtype="int64")

2748

idblock = numpy.array([self.idblock],dtype="int64")

2748

header=self.wrObj.cFImage(idblock=idblock,

2749

header=self.wrObj.cFImage(idblock=idblock,

2749

year=time.gmtime(self.dataOut.utctime).tm_year,

2750

year=time.gmtime(self.dataOut.utctime).tm_year,

2750

month=time.gmtime(self.dataOut.utctime).tm_mon,

2751

month=time.gmtime(self.dataOut.utctime).tm_mon,

2751

day=time.gmtime(self.dataOut.utctime).tm_mday,

2752

day=time.gmtime(self.dataOut.utctime).tm_mday,

2752

hour=time.gmtime(self.dataOut.utctime).tm_hour,

2753

hour=time.gmtime(self.dataOut.utctime).tm_hour,

2753

minute=time.gmtime(self.dataOut.utctime).tm_min,

2754

minute=time.gmtime(self.dataOut.utctime).tm_min,

2754

second=time.gmtime(self.dataOut.utctime).tm_sec)

2755

second=time.gmtime(self.dataOut.utctime).tm_sec)

2755

2756

c=3E8

2757

c=3E8

2757

deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

2758

deltaHeight = self.dataOut.heightList[1] - self.dataOut.heightList[0]

2758

freq=numpy.arange(-1*self.dataOut.nHeights/2.,self.dataOut.nHeights/2.)*(c/(2*deltaHeight*1000))

2759

freq=numpy.arange(-1*self.dataOut.nHeights/2.,self.dataOut.nHeights/2.)*(c/(2*deltaHeight*1000))

2759

2760

colList = []

2761

colList = []

2761

2762

colFreq=self.wrObj.setColF(name="freq", format=str(self.dataOut.nFFTPoints)+'E', array=freq)

2763

colFreq=self.wrObj.setColF(name="freq", format=str(self.dataOut.nFFTPoints)+'E', array=freq)

2763

2764

colList.append(colFreq)

2765

colList.append(colFreq)

2765

2766

nchannel=self.dataOut.nChannels

2767

nchannel=self.dataOut.nChannels

2767

2768

for i in range(nchannel):

2769

for i in range(nchannel):

2769

col = self.wrObj.writeData(name="PCh"+str(i+1),

2770

col = self.wrObj.writeData(name="PCh"+str(i+1),

2770

format=str(self.dataOut.nFFTPoints)+'E',

2771

format=str(self.dataOut.nFFTPoints)+'E',

2771

data=10*numpy.log10(self.dataOut.data_spc[i,:]))

2772

data=10*numpy.log10(self.dataOut.data_spc[i,:]))

2772

2773

colList.append(col)

2774

colList.append(col)

2774

2775

data=self.wrObj.Ctable(colList=colList)

2776

data=self.wrObj.Ctable(colList=colList)

2776

2777

self.wrObj.CFile(header,data)

2778

self.wrObj.CFile(header,data)

2778

2779

self.wrObj.wFile(filename)

2780

self.wrObj.wFile(filename)

2780

2781

#update the setFile

2782

#update the setFile

2782

self.setFile += 1

2783

self.setFile += 1

2783

self.idblock += 1

2784

self.idblock += 1

2784

2785

return 1

2786

return 1

2786

2787

def run(self, dataOut, **kwargs):

2788

def run(self, dataOut, **kwargs):

2788

2789

if not(self.isConfig):

2790

if not(self.isConfig):

2790

2791

self.setup(dataOut, **kwargs)

2792

self.setup(dataOut, **kwargs)

2792

self.isConfig = True

2793

self.isConfig = True

2793

2794

self.putData()

2795

self.putData()

2795

2796

2797

2798

class ParameterConf:

2799

class ParameterConf:

2799

ELEMENTNAME = 'Parameter'

2800

ELEMENTNAME = 'Parameter'

2800

def __init__(self):

2801

def __init__(self):

2801

self.name = ''

2802

self.name = ''

2802

self.value = ''

2803

self.value = ''

2803

2804

def readXml(self, parmElement):

2805

def readXml(self, parmElement):

2805

self.name = parmElement.get('name')

2806

self.name = parmElement.get('name')

2806

self.value = parmElement.get('value')

2807

self.value = parmElement.get('value')

2807

2808

def getElementName(self):

2809

def getElementName(self):

2809

return self.ELEMENTNAME

2810

return self.ELEMENTNAME

2810

2811

class Metadata:

2812

class Metadata:

2812

2813

def __init__(self, filename):

2814

def __init__(self, filename):

2814

self.parmConfObjList = []

2815

self.parmConfObjList = []

2815

self.readXml(filename)

2816

self.readXml(filename)

2816

2817

def readXml(self, filename):

2818

def readXml(self, filename):

2818

self.projectElement = None

2819

self.projectElement = None

2819

self.procUnitConfObjDict = {}

2820

self.procUnitConfObjDict = {}

2820

self.projectElement = ElementTree().parse(filename)

2821

self.projectElement = ElementTree().parse(filename)

2821

self.project = self.projectElement.tag

2822

self.project = self.projectElement.tag

2822

2823

parmElementList = self.projectElement.getiterator(ParameterConf().getElementName())

2824

parmElementList = self.projectElement.getiterator(ParameterConf().getElementName())

2824

2825

for parmElement in parmElementList:

2826

for parmElement in parmElementList:

2826

parmConfObj = ParameterConf()

2827

parmConfObj = ParameterConf()

2827

parmConfObj.readXml(parmElement)

2828

parmConfObj.readXml(parmElement)

2828

self.parmConfObjList.append(parmConfObj)

2829

self.parmConfObjList.append(parmConfObj)

2829

2830

class FitsWriter(Operation):

2831

class FitsWriter(Operation):

2831

2832

def __init__(self):

2833

def __init__(self):

2833

self.isConfig = False

2834

self.isConfig = False

2834

self.dataBlocksPerFile = None

2835

self.dataBlocksPerFile = None

2835

self.blockIndex = 0

2836

self.blockIndex = 0

2836

self.flagIsNewFile = 1

2837

self.flagIsNewFile = 1

2837

self.fitsObj = None

2838

self.fitsObj = None

2838

self.optchar = 'P'

2839

self.optchar = 'P'

2839

self.ext = '.fits'

2840

self.ext = '.fits'

2840

self.setFile = 0

2841

self.setFile = 0

2841

2842

def setFitsHeader(self, dataOut, metadatafile):

2843

def setFitsHeader(self, dataOut, metadatafile):

2843

2844

header_data = pyfits.PrimaryHDU()

2845

header_data = pyfits.PrimaryHDU()

2845

2846

metadata4fits = Metadata(metadatafile)

2847

metadata4fits = Metadata(metadatafile)

2847

for parameter in metadata4fits.parmConfObjList:

2848

for parameter in metadata4fits.parmConfObjList:

2848

parm_name = parameter.name

2849

parm_name = parameter.name

2849

parm_value = parameter.value

2850

parm_value = parameter.value

2850

2851

# if parm_value == 'fromdatadatetime':

2852

# if parm_value == 'fromdatadatetime':

2852

# value = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())

2853

# value = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())

2853

# elif parm_value == 'fromdataheights':

2854

# elif parm_value == 'fromdataheights':

2854

# value = dataOut.nHeights

2855

# value = dataOut.nHeights

2855

# elif parm_value == 'fromdatachannel':

2856

# elif parm_value == 'fromdatachannel':

2856

# value = dataOut.nChannels

2857

# value = dataOut.nChannels

2857

# elif parm_value == 'fromdatasamples':

2858

# elif parm_value == 'fromdatasamples':

2858

# value = dataOut.nFFTPoints

2859

# value = dataOut.nFFTPoints

2859

# else:

2860

# else:

2860

# value = parm_value

2861

# value = parm_value

2861

2862

header_data.header[parm_name] = parm_value

2863

header_data.header[parm_name] = parm_value

2863

2864

2865

header_data.header['DATETIME'] = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())

2866

header_data.header['DATETIME'] = time.strftime("%b %d %Y %H:%M:%S", dataOut.datatime.timetuple())

2866

header_data.header['CHANNELLIST'] = str(dataOut.channelList)

2867

header_data.header['CHANNELLIST'] = str(dataOut.channelList)

2867

header_data.header['NCHANNELS'] = dataOut.nChannels

2868

header_data.header['NCHANNELS'] = dataOut.nChannels

2868

#header_data.header['HEIGHTS'] = dataOut.heightList

2869

#header_data.header['HEIGHTS'] = dataOut.heightList

2869

header_data.header['NHEIGHTS'] = dataOut.nHeights

2870

header_data.header['NHEIGHTS'] = dataOut.nHeights

2870

2871

header_data.header['IPPSECONDS'] = dataOut.ippSeconds

2872

header_data.header['IPPSECONDS'] = dataOut.ippSeconds

2872

header_data.header['NCOHINT'] = dataOut.nCohInt

2873

header_data.header['NCOHINT'] = dataOut.nCohInt

2873

header_data.header['NINCOHINT'] = dataOut.nIncohInt

2874

header_data.header['NINCOHINT'] = dataOut.nIncohInt

2874

header_data.header['TIMEZONE'] = dataOut.timeZone

2875

header_data.header['TIMEZONE'] = dataOut.timeZone

2875

header_data.header['NBLOCK'] = self.blockIndex

2876

header_data.header['NBLOCK'] = self.blockIndex

2876

2877

header_data.writeto(self.filename)

2878

header_data.writeto(self.filename)

2878

2879

self.addExtension(dataOut.heightList,'HEIGHTLIST')

2880

self.addExtension(dataOut.heightList,'HEIGHTLIST')

2880

2881

2882

def setup(self, dataOut, path, dataBlocksPerFile, metadatafile):

2883

def setup(self, dataOut, path, dataBlocksPerFile, metadatafile):

2883

2884

self.path = path

2885

self.path = path

2885

self.dataOut = dataOut

2886

self.dataOut = dataOut

2886

self.metadatafile = metadatafile

2887

self.metadatafile = metadatafile

2887

self.dataBlocksPerFile = dataBlocksPerFile

2888

self.dataBlocksPerFile = dataBlocksPerFile

2888

2889

def open(self):

2890

def open(self):

2890

self.fitsObj = pyfits.open(self.filename, mode='update')

2891

self.fitsObj = pyfits.open(self.filename, mode='update')

2891

2892

2893

def addExtension(self, data, tagname):

2894

def addExtension(self, data, tagname):

2894

self.open()

2895

self.open()

2895

extension = pyfits.ImageHDU(data=data, name=tagname)

2896

extension = pyfits.ImageHDU(data=data, name=tagname)

2896

#extension.header['TAG'] = tagname

2897

#extension.header['TAG'] = tagname

2897

self.fitsObj.append(extension)

2898

self.fitsObj.append(extension)

2898

self.write()

2899

self.write()

2899

2900

def addData(self, data):

2901

def addData(self, data):

2901

self.open()

2902

self.open()

2902

extension = pyfits.ImageHDU(data=data, name=self.fitsObj[0].header['DATATYPE'])

2903

extension = pyfits.ImageHDU(data=data, name=self.fitsObj[0].header['DATATYPE'])

2903

extension.header['UTCTIME'] = self.dataOut.utctime

2904

extension.header['UTCTIME'] = self.dataOut.utctime

2904

self.fitsObj.append(extension)

2905

self.fitsObj.append(extension)

2905

self.blockIndex += 1

2906

self.blockIndex += 1

2906

self.fitsObj[0].header['NBLOCK'] = self.blockIndex

2907

self.fitsObj[0].header['NBLOCK'] = self.blockIndex

2907

2908

self.write()

2909

self.write()

2909

2910

def write(self):

2911

def write(self):

2911

2912

self.fitsObj.flush(verbose=True)

2913

self.fitsObj.flush(verbose=True)

2913

self.fitsObj.close()

2914

self.fitsObj.close()

2914

2915

2916

def setNextFile(self):

2917

def setNextFile(self):

2917

2918

ext = self.ext

2919

ext = self.ext

2919

path = self.path

2920

path = self.path

2920

2921

timeTuple = time.localtime( self.dataOut.utctime)

2922

timeTuple = time.localtime( self.dataOut.utctime)

2922

subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)

2923

subfolder = 'd%4.4d%3.3d' % (timeTuple.tm_year,timeTuple.tm_yday)

2923

2924

fullpath = os.path.join( path, subfolder )

2925

fullpath = os.path.join( path, subfolder )

2925

if not( os.path.exists(fullpath) ):

2926

if not( os.path.exists(fullpath) ):

2926

os.mkdir(fullpath)

2927

os.mkdir(fullpath)

2927

self.setFile = -1 #inicializo mi contador de seteo

2928

self.setFile = -1 #inicializo mi contador de seteo

2928

else:

2929

else:

2929

filesList = os.listdir( fullpath )

2930

filesList = os.listdir( fullpath )

2930

if len( filesList ) > 0:

2931

if len( filesList ) > 0:

2931

filesList = sorted( filesList, key=str.lower )

2932

filesList = sorted( filesList, key=str.lower )

2932

filen = filesList[-1]

2933

filen = filesList[-1]

2933

2934

if isNumber( filen[8:11] ):

2935

if isNumber( filen[8:11] ):

2935

self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file

2936

self.setFile = int( filen[8:11] ) #inicializo mi contador de seteo al seteo del ultimo file

2936

else:

2937

else:

2937

self.setFile = -1

2938

self.setFile = -1

2938

else:

2939

else:

2939

self.setFile = -1 #inicializo mi contador de seteo

2940

self.setFile = -1 #inicializo mi contador de seteo

2940

2941

setFile = self.setFile

2942

setFile = self.setFile

2942

setFile += 1

2943

setFile += 1

2943

2944

file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,

2945

file = '%s%4.4d%3.3d%3.3d%s' % (self.optchar,

2945

timeTuple.tm_year,

2946

timeTuple.tm_year,

2946

timeTuple.tm_yday,

2947

timeTuple.tm_yday,

2947

setFile,

2948

setFile,

2948

ext )

2949

ext )

2949

2950

filename = os.path.join( path, subfolder, file )

2951

filename = os.path.join( path, subfolder, file )

2951

2952

self.blockIndex = 0

2953

self.blockIndex = 0

2953

self.filename = filename

2954

self.filename = filename

2954

self.setFile = setFile

2955

self.setFile = setFile

2955

self.flagIsNewFile = 1

2956

self.flagIsNewFile = 1

2956

2957

print 'Writing the file: %s'%self.filename

2958

print 'Writing the file: %s'%self.filename

2958

2959

self.setFitsHeader(self.dataOut, self.metadatafile)

2960

self.setFitsHeader(self.dataOut, self.metadatafile)

2960

2961

return 1

2962

return 1

2962

2963

def writeBlock(self):

2964

def writeBlock(self):

2964

self.addData(self.dataOut.data_spc)

2965

self.addData(self.dataOut.data_spc)

2965

self.flagIsNewFile = 0

2966

self.flagIsNewFile = 0

2966

2967

2968

def __setNewBlock(self):

2969

def __setNewBlock(self):

2969

2970

if self.flagIsNewFile:

2971

if self.flagIsNewFile:

2971

return 1

2972

return 1

2972

2973

if self.blockIndex < self.dataBlocksPerFile:

2974

if self.blockIndex < self.dataBlocksPerFile:

2974

return 1

2975

return 1

2975

2976

if not( self.setNextFile() ):

2977

if not( self.setNextFile() ):

2977

return 0

2978

return 0

2978

2979

return 1

2980

return 1

2980

2981

def writeNextBlock(self):

2982

def writeNextBlock(self):

2982

if not( self.__setNewBlock() ):

2983

if not( self.__setNewBlock() ):

2983

return 0

2984

return 0

2984

self.writeBlock()

2985

self.writeBlock()

2985

return 1

2986

return 1

2986

2987

def putData(self):

2988

def putData(self):

2988

if self.flagIsNewFile:

2989

if self.flagIsNewFile:

2989

self.setNextFile()

2990

self.setNextFile()

2990

self.writeNextBlock()

2991

self.writeNextBlock()

2991

2992

def run(self, dataOut, **kwargs):

2993

def run(self, dataOut, **kwargs):

2993

if not(self.isConfig):

2994

if not(self.isConfig):

2994

self.setup(dataOut, **kwargs)

2995

self.setup(dataOut, **kwargs)

2995

self.isConfig = True

2996

self.isConfig = True

2996

self.putData()

2997

self.putData()

2997

2998

2999

class FitsReader(ProcessingUnit):

3000

class FitsReader(ProcessingUnit):

3000

3001

# __TIMEZONE = time.timezone

3002

# __TIMEZONE = time.timezone

3002

3003

expName = None

3004

expName = None

3004

datetimestr = None

3005

datetimestr = None

3005

utc = None

3006

utc = None

3006

nChannels = None

3007

nChannels = None

3007

nSamples = None

3008

nSamples = None

3008

dataBlocksPerFile = None

3009

dataBlocksPerFile = None

3009

comments = None

3010

comments = None

3010

lastUTTime = None

3011

lastUTTime = None

3011

header_dict = None

3012

header_dict = None

3012

data = None

3013

data = None

3013

data_header_dict = None

3014

data_header_dict = None

3014

3015

def __init__(self):

3016

def __init__(self):

3016

self.isConfig = False

3017

self.isConfig = False

3017

self.ext = '.fits'

3018

self.ext = '.fits'

3018

self.setFile = 0

3019

self.setFile = 0

3019

self.flagNoMoreFiles = 0

3020

self.flagNoMoreFiles = 0

3020

self.flagIsNewFile = 1

3021

self.flagIsNewFile = 1

3021

self.flagTimeBlock = None

3022

self.flagTimeBlock = None

3022

self.fileIndex = None

3023

self.fileIndex = None

3023

self.filename = None

3024

self.filename = None

3024

self.fileSize = None

3025

self.fileSize = None

3025

self.fitsObj = None

3026

self.fitsObj = None

3026

self.timeZone = None

3027

self.timeZone = None

3027

self.nReadBlocks = 0

3028

self.nReadBlocks = 0

3028

self.nTotalBlocks = 0

3029

self.nTotalBlocks = 0

3029

self.dataOut = self.createObjByDefault()

3030

self.dataOut = self.createObjByDefault()

3030

self.maxTimeStep = 10# deberia ser definido por el usuario usando el metodo setup()

3031

self.maxTimeStep = 10# deberia ser definido por el usuario usando el metodo setup()

3031

self.blockIndex = 1

3032

self.blockIndex = 1

3032

3033

def createObjByDefault(self):

3034

def createObjByDefault(self):

3034

3035

dataObj = Fits()

3036

dataObj = Fits()

3036

3037

return dataObj

3038

return dataObj

3038

3039

def isFileinThisTime(self, filename, startTime, endTime, useLocalTime=False):

3040

def isFileinThisTime(self, filename, startTime, endTime, useLocalTime=False):

3040

try:

3041

try:

3041

fitsObj = pyfits.open(filename,'readonly')

3042

fitsObj = pyfits.open(filename,'readonly')

3042

except:

3043

except:

3043

raise IOError, "The file %s can't be opened" %(filename)

3044

raise IOError, "The file %s can't be opened" %(filename)

3044

3045

header = fitsObj[0].header

3046

header = fitsObj[0].header

3046

struct_time = time.strptime(header['DATETIME'], "%b %d %Y %H:%M:%S")

3047

struct_time = time.strptime(header['DATETIME'], "%b %d %Y %H:%M:%S")

3047

utc = time.mktime(struct_time) - time.timezone #TIMEZONE debe ser un parametro del header FITS

3048

utc = time.mktime(struct_time) - time.timezone #TIMEZONE debe ser un parametro del header FITS

3048

3049

ltc = utc

3050

ltc = utc

3050

if useLocalTime:

3051

if useLocalTime:

3051

ltc -= time.timezone

3052

ltc -= time.timezone

3052

thisDatetime = datetime.datetime.utcfromtimestamp(ltc)

3053

thisDatetime = datetime.datetime.utcfromtimestamp(ltc)

3053

thisTime = thisDatetime.time()

3054

thisTime = thisDatetime.time()

3054

3055

if not ((startTime <= thisTime) and (endTime > thisTime)):

3056

if not ((startTime <= thisTime) and (endTime > thisTime)):

3056

return None

3057

return None

3057

3058

return thisDatetime

3059

return thisDatetime

3059

3060

def __setNextFileOnline(self):

3061

def __setNextFileOnline(self):

3061

raise ValueError, "No implemented"

3062

raise ValueError, "No implemented"

3062

3063

def __setNextFileOffline(self):

3064

def __setNextFileOffline(self):

3064

idFile = self.fileIndex

3065

idFile = self.fileIndex

3065

3066

while (True):

3067

while (True):

3067

idFile += 1

3068

idFile += 1

3068

if not(idFile < len(self.filenameList)):

3069

if not(idFile < len(self.filenameList)):

3069

self.flagNoMoreFiles = 1

3070

self.flagNoMoreFiles = 1

3070

print "No more Files"

3071

print "No more Files"

3071

return 0

3072

return 0

3072

3073

filename = self.filenameList[idFile]

3074

filename = self.filenameList[idFile]

3074

3075

# if not(self.__verifyFile(filename)):

3076

# if not(self.__verifyFile(filename)):

3076

# continue

3077

# continue

3077

3078

fileSize = os.path.getsize(filename)

3079

fileSize = os.path.getsize(filename)

3079

fitsObj = pyfits.open(filename,'readonly')

3080

fitsObj = pyfits.open(filename,'readonly')

3080

break

3081

break

3081

3082

self.flagIsNewFile = 1

3083

self.flagIsNewFile = 1

3083

self.fileIndex = idFile

3084

self.fileIndex = idFile

3084

self.filename = filename

3085

self.filename = filename

3085

self.fileSize = fileSize

3086

self.fileSize = fileSize

3086

self.fitsObj = fitsObj

3087

self.fitsObj = fitsObj

3087

self.blockIndex = 0

3088

self.blockIndex = 0

3088

print "Setting the file: %s"%self.filename

3089

print "Setting the file: %s"%self.filename

3089

3090

return 1

3091

return 1

3091

3092

def readHeader(self):

3093

def readHeader(self):

3093

headerObj = self.fitsObj[0]

3094

headerObj = self.fitsObj[0]

3094

3095

self.header_dict = headerObj.header

3096

self.header_dict = headerObj.header

3096

if 'EXPNAME' in headerObj.header.keys():

3097

if 'EXPNAME' in headerObj.header.keys():

3097

self.expName = headerObj.header['EXPNAME']

3098

self.expName = headerObj.header['EXPNAME']

3098

3099

if 'DATATYPE' in headerObj.header.keys():

3100

if 'DATATYPE' in headerObj.header.keys():

3100

self.dataType = headerObj.header['DATATYPE']

3101

self.dataType = headerObj.header['DATATYPE']

3101

3102

self.datetimestr = headerObj.header['DATETIME']

3103

self.datetimestr = headerObj.header['DATETIME']

3103

channelList = headerObj.header['CHANNELLIST']

3104

channelList = headerObj.header['CHANNELLIST']

3104

channelList = channelList.split('[')

3105

channelList = channelList.split('[')

3105

channelList = channelList[1].split(']')

3106

channelList = channelList[1].split(']')

3106

channelList = channelList[0].split(',')

3107

channelList = channelList[0].split(',')

3107

channelList = [int(ch) for ch in channelList]

3108

channelList = [int(ch) for ch in channelList]

3108

self.channelList = channelList

3109

self.channelList = channelList

3109

self.nChannels = headerObj.header['NCHANNELS']

3110

self.nChannels = headerObj.header['NCHANNELS']

3110

self.nHeights = headerObj.header['NHEIGHTS']

3111

self.nHeights = headerObj.header['NHEIGHTS']

3111

self.ippSeconds = headerObj.header['IPPSECONDS']

3112

self.ippSeconds = headerObj.header['IPPSECONDS']

3112

self.nCohInt = headerObj.header['NCOHINT']

3113

self.nCohInt = headerObj.header['NCOHINT']

3113

self.nIncohInt = headerObj.header['NINCOHINT']

3114

self.nIncohInt = headerObj.header['NINCOHINT']

3114

self.dataBlocksPerFile = headerObj.header['NBLOCK']

3115

self.dataBlocksPerFile = headerObj.header['NBLOCK']

3115

self.timeZone = headerObj.header['TIMEZONE']

3116

self.timeZone = headerObj.header['TIMEZONE']

3116

3117

self.timeInterval = self.ippSeconds * self.nCohInt * self.nIncohInt

3118

self.timeInterval = self.ippSeconds * self.nCohInt * self.nIncohInt

3118

3119

if 'COMMENT' in headerObj.header.keys():

3120

if 'COMMENT' in headerObj.header.keys():

3120

self.comments = headerObj.header['COMMENT']

3121

self.comments = headerObj.header['COMMENT']

3121

3122

self.readHeightList()

3123

self.readHeightList()

3123

3124

def readHeightList(self):

3125

def readHeightList(self):

3125

self.blockIndex = self.blockIndex + 1

3126

self.blockIndex = self.blockIndex + 1

3126

obj = self.fitsObj[self.blockIndex]

3127

obj = self.fitsObj[self.blockIndex]

3127

self.heightList = obj.data

3128

self.heightList = obj.data

3128

self.blockIndex = self.blockIndex + 1

3129

self.blockIndex = self.blockIndex + 1

3129

3130

def readExtension(self):

3131

def readExtension(self):

3131

obj = self.fitsObj[self.blockIndex]

3132

obj = self.fitsObj[self.blockIndex]

3132

self.heightList = obj.data

3133

self.heightList = obj.data

3133

self.blockIndex = self.blockIndex + 1

3134

self.blockIndex = self.blockIndex + 1

3134

3135

def setNextFile(self):

3136

def setNextFile(self):

3136

3137

if self.online:

3138

if self.online:

3138

newFile = self.__setNextFileOnline()

3139

newFile = self.__setNextFileOnline()

3139

else:

3140

else:

3140

newFile = self.__setNextFileOffline()

3141

newFile = self.__setNextFileOffline()

3141

3142

if not(newFile):

3143

if not(newFile):

3143

return 0

3144

return 0

3144

3145

self.readHeader()

3146

self.readHeader()

3146

3147

self.nReadBlocks = 0

3148

self.nReadBlocks = 0

3148

# self.blockIndex = 1

3149

# self.blockIndex = 1

3149

return 1

3150

return 1

3150

3151

def __searchFilesOffLine(self,

3152

def __searchFilesOffLine(self,

3152

path,

3153

path,

3153

startDate,

3154

startDate,

3154

endDate,

3155

endDate,

3155

startTime=datetime.time(0,0,0),

3156

startTime=datetime.time(0,0,0),

3156

endTime=datetime.time(23,59,59),

3157

endTime=datetime.time(23,59,59),

3157

set=None,

3158

set=None,

3158

expLabel='',

3159

expLabel='',

3159

ext='.fits',

3160

ext='.fits',

3160

walk=True):

3161

walk=True):

3161

3162

pathList = []

3163

pathList = []

3163

3164

if not walk:

3165

if not walk:

3165

pathList.append(path)

3166

pathList.append(path)

3166

3167

else:

3168

else:

3168

dirList = []

3169

dirList = []

3169

for thisPath in os.listdir(path):

3170

for thisPath in os.listdir(path):

3170

if not os.path.isdir(os.path.join(path,thisPath)):

3171

if not os.path.isdir(os.path.join(path,thisPath)):

3171

continue

3172

continue

3172

if not isDoyFolder(thisPath):

3173

if not isDoyFolder(thisPath):

3173

continue

3174

continue

3174

3175

dirList.append(thisPath)

3176

dirList.append(thisPath)

3176

3177

if not(dirList):

3178

if not(dirList):

3178

return None, None

3179

return None, None

3179

3180

thisDate = startDate

3181

thisDate = startDate

3181

3182

while(thisDate <= endDate):

3183

while(thisDate <= endDate):

3183

year = thisDate.timetuple().tm_year

3184

year = thisDate.timetuple().tm_year

3184

doy = thisDate.timetuple().tm_yday

3185

doy = thisDate.timetuple().tm_yday

3185

3186

matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')

3187

matchlist = fnmatch.filter(dirList, '?' + '%4.4d%3.3d' % (year,doy) + '*')

3187

if len(matchlist) == 0:

3188

if len(matchlist) == 0:

3188

thisDate += datetime.timedelta(1)

3189

thisDate += datetime.timedelta(1)

3189

continue

3190

continue

3190

for match in matchlist:

3191

for match in matchlist:

3191

pathList.append(os.path.join(path,match,expLabel))

3192

pathList.append(os.path.join(path,match,expLabel))

3192

3193

thisDate += datetime.timedelta(1)

3194

thisDate += datetime.timedelta(1)

3194

3195

if pathList == []:

3196

if pathList == []:

3196

print "Any folder was found for the date range: %s-%s" %(startDate, endDate)

3197

print "Any folder was found for the date range: %s-%s" %(startDate, endDate)

3197

return None, None

3198

return None, None

3198

3199

print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)

3200

print "%d folder(s) was(were) found for the date range: %s - %s" %(len(pathList), startDate, endDate)

3200

3201

filenameList = []

3202

filenameList = []

3202

datetimeList = []

3203

datetimeList = []

3203

3204

for i in range(len(pathList)):

3205

for i in range(len(pathList)):

3205

3206

thisPath = pathList[i]

3207

thisPath = pathList[i]

3207

3208

fileList = glob.glob1(thisPath, "*%s" %ext)

3209

fileList = glob.glob1(thisPath, "*%s" %ext)

3209

fileList.sort()

3210

fileList.sort()

3210

3211

for file in fileList:

3212

for file in fileList:

3212

3213

filename = os.path.join(thisPath,file)

3214

filename = os.path.join(thisPath,file)

3214

thisDatetime = self.isFileinThisTime(filename, startTime, endTime)

3215

thisDatetime = self.isFileinThisTime(filename, startTime, endTime)

3215

3216

if not(thisDatetime):

3217

if not(thisDatetime):

3217

continue

3218

continue

3218

3219

filenameList.append(filename)

3220

filenameList.append(filename)

3220

datetimeList.append(thisDatetime)

3221

datetimeList.append(thisDatetime)

3221

3222

if not(filenameList):

3223

if not(filenameList):

3223

print "Any file was found for the time range %s - %s" %(startTime, endTime)

3224

print "Any file was found for the time range %s - %s" %(startTime, endTime)

3224

return None, None

3225

return None, None

3225

3226

print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)

3227

print "%d file(s) was(were) found for the time range: %s - %s" %(len(filenameList), startTime, endTime)

3227

print

3228

print

3228

3229

for i in range(len(filenameList)):

3230

for i in range(len(filenameList)):

3230

print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())

3231

print "%s -> [%s]" %(filenameList[i], datetimeList[i].ctime())

3231

3232

self.filenameList = filenameList

3233

self.filenameList = filenameList

3233

self.datetimeList = datetimeList

3234

self.datetimeList = datetimeList

3234

3235

return pathList, filenameList

3236

return pathList, filenameList

3236

3237

def setup(self, path=None,

3238

def setup(self, path=None,

3238

startDate=None,

3239

startDate=None,

3239

endDate=None,

3240

endDate=None,

3240

startTime=datetime.time(0,0,0),

3241

startTime=datetime.time(0,0,0),

3241

endTime=datetime.time(23,59,59),

3242

endTime=datetime.time(23,59,59),

3242

set=0,

3243

set=0,

3243

expLabel = "",

3244

expLabel = "",

3244

ext = None,

3245

ext = None,

3245

online = False,

3246

online = False,

3246

delay = 60,

3247

delay = 60,

3247

walk = True):

3248

walk = True):

3248

3249

if path == None:

3250

if path == None:

3250

raise ValueError, "The path is not valid"

3251

raise ValueError, "The path is not valid"

3251

3252

if ext == None:

3253

if ext == None:

3253

ext = self.ext

3254

ext = self.ext

3254

3255

if not(online):

3256

if not(online):

3256

print "Searching files in offline mode ..."

3257

print "Searching files in offline mode ..."

3257

pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,

3258

pathList, filenameList = self.__searchFilesOffLine(path, startDate=startDate, endDate=endDate,

3258

startTime=startTime, endTime=endTime,

3259

startTime=startTime, endTime=endTime,

3259

set=set, expLabel=expLabel, ext=ext,

3260

set=set, expLabel=expLabel, ext=ext,

3260

walk=walk)

3261

walk=walk)

3261

3262

if not(pathList):

3263

if not(pathList):

3263

print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,

3264

print "No *%s files into the folder %s \nfor the range: %s - %s"%(ext, path,

3264

datetime.datetime.combine(startDate,startTime).ctime(),

3265

datetime.datetime.combine(startDate,startTime).ctime(),

3265

datetime.datetime.combine(endDate,endTime).ctime())

3266

datetime.datetime.combine(endDate,endTime).ctime())

3266

3267

sys.exit(-1)

3268

sys.exit(-1)

3268

3269

self.fileIndex = -1

3270

self.fileIndex = -1

3270

self.pathList = pathList

3271

self.pathList = pathList

3271

self.filenameList = filenameList

3272

self.filenameList = filenameList

3272

3273

self.online = online

3274

self.online = online

3274

self.delay = delay

3275

self.delay = delay

3275

ext = ext.lower()

3276

ext = ext.lower()

3276

self.ext = ext

3277

self.ext = ext

3277

3278

if not(self.setNextFile()):

3279

if not(self.setNextFile()):

3279

if (startDate!=None) and (endDate!=None):

3280

if (startDate!=None) and (endDate!=None):

3280

print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())

3281

print "No files in range: %s - %s" %(datetime.datetime.combine(startDate,startTime).ctime(), datetime.datetime.combine(endDate,endTime).ctime())

3281

elif startDate != None:

3282

elif startDate != None:

3282

print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())

3283

print "No files in range: %s" %(datetime.datetime.combine(startDate,startTime).ctime())

3283

else:

3284

else:

3284

print "No files"

3285

print "No files"

3285

3286

sys.exit(-1)

3287

sys.exit(-1)

3287

3288

3289

3290

def readBlock(self):

3291

def readBlock(self):

3291

dataObj = self.fitsObj[self.blockIndex]

3292

dataObj = self.fitsObj[self.blockIndex]

3292

3293

self.data = dataObj.data

3294

self.data = dataObj.data

3294

self.data_header_dict = dataObj.header

3295

self.data_header_dict = dataObj.header

3295

self.utc = self.data_header_dict['UTCTIME']

3296

self.utc = self.data_header_dict['UTCTIME']

3296

3297

self.flagIsNewFile = 0

3298

self.flagIsNewFile = 0

3298

self.blockIndex += 1

3299

self.blockIndex += 1

3299

self.nTotalBlocks += 1

3300

self.nTotalBlocks += 1

3300

self.nReadBlocks += 1

3301

self.nReadBlocks += 1

3301

3302

return 1

3303

return 1

3303

3304

def __jumpToLastBlock(self):

3305

def __jumpToLastBlock(self):

3305

raise ValueError, "No implemented"

3306

raise ValueError, "No implemented"

3306

3307

def __waitNewBlock(self):

3308

def __waitNewBlock(self):

3308

"""

3309

"""

3309

Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.

3310

Return 1 si se encontro un nuevo bloque de datos, 0 de otra forma.

3310

3311

Si el modo de lectura es OffLine siempre retorn 0

3312

Si el modo de lectura es OffLine siempre retorn 0

3312

"""

3313

"""

3313

if not self.online:

3314

if not self.online:

3314

return 0

3315

return 0

3315

3316

if (self.nReadBlocks >= self.dataBlocksPerFile):

3317

if (self.nReadBlocks >= self.dataBlocksPerFile):

3317

return 0

3318

return 0

3318

3319

currentPointer = self.fp.tell()

3320

currentPointer = self.fp.tell()

3320

3321

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

3322

neededSize = self.processingHeaderObj.blockSize + self.basicHeaderSize

3322

3323

for nTries in range( self.nTries ):

3324

for nTries in range( self.nTries ):

3324

3325

self.fp.close()

3326

self.fp.close()

3326

self.fp = open( self.filename, 'rb' )

3327

self.fp = open( self.filename, 'rb' )

3327

self.fp.seek( currentPointer )

3328

self.fp.seek( currentPointer )

3328

3329

self.fileSize = os.path.getsize( self.filename )

3330

self.fileSize = os.path.getsize( self.filename )

3330

currentSize = self.fileSize - currentPointer

3331

currentSize = self.fileSize - currentPointer

3331

3332

if ( currentSize >= neededSize ):

3333

if ( currentSize >= neededSize ):

3333

self.__rdBasicHeader()

3334

self.__rdBasicHeader()

3334

return 1

3335

return 1

3335

3336

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

3337

print "\tWaiting %0.2f seconds for the next block, try %03d ..." % (self.delay, nTries+1)

3337

time.sleep( self.delay )

3338

time.sleep( self.delay )

3338

3339

3340

return 0

3341

return 0

3341

3342

def __setNewBlock(self):

3343

def __setNewBlock(self):

3343

3344

if self.online:

3345

if self.online:

3345

self.__jumpToLastBlock()

3346

self.__jumpToLastBlock()

3346

3347

if self.flagIsNewFile:

3348

if self.flagIsNewFile:

3348

return 1

3349

return 1

3349

3350

self.lastUTTime = self.utc

3351

self.lastUTTime = self.utc

3351

3352

if self.online:

3353

if self.online:

3353

if self.__waitNewBlock():

3354

if self.__waitNewBlock():

3354

return 1

3355

return 1

3355

3356

if self.nReadBlocks < self.dataBlocksPerFile:

3357

if self.nReadBlocks < self.dataBlocksPerFile:

3357

return 1

3358

return 1

3358

3359

if not(self.setNextFile()):

3360

if not(self.setNextFile()):

3360

return 0

3361

return 0

3361

3362

deltaTime = self.utc - self.lastUTTime

3363

deltaTime = self.utc - self.lastUTTime

3363

3364

self.flagTimeBlock = 0

3365

self.flagTimeBlock = 0

3365

3366

if deltaTime > self.maxTimeStep:

3367

if deltaTime > self.maxTimeStep:

3367

self.flagTimeBlock = 1

3368

self.flagTimeBlock = 1

3368

3369

return 1

3370

return 1

3370

3371

3372

def readNextBlock(self):

3373

def readNextBlock(self):

3373

if not(self.__setNewBlock()):

3374

if not(self.__setNewBlock()):

3374

return 0

3375

return 0

3375

3376

if not(self.readBlock()):

3377

if not(self.readBlock()):

3377

return 0

3378

return 0

3378

3379

return 1

3380

return 1

3380

3381

3382

def getData(self):

3383

def getData(self):

3383

3384

if self.flagNoMoreFiles:

3385

if self.flagNoMoreFiles:

3385

self.dataOut.flagNoData = True

3386

self.dataOut.flagNoData = True

3386

print 'Process finished'

3387

print 'Process finished'

3387

return 0

3388

return 0

3388

3389

self.flagTimeBlock = 0

3390

self.flagTimeBlock = 0

3390

self.flagIsNewBlock = 0

3391

self.flagIsNewBlock = 0

3391

3392

if not(self.readNextBlock()):

3393

if not(self.readNextBlock()):

3393

return 0

3394

return 0

3394

3395

if self.data == None:

3396

if self.data == None:

3396

self.dataOut.flagNoData = True

3397

self.dataOut.flagNoData = True

3397

return 0

3398

return 0

3398

3399

self.dataOut.data = self.data

3400

self.dataOut.data = self.data

3400

self.dataOut.data_header = self.data_header_dict

3401

self.dataOut.data_header = self.data_header_dict

3401

self.dataOut.utctime = self.utc

3402

self.dataOut.utctime = self.utc

3402

3403

self.dataOut.header = self.header_dict

3404

self.dataOut.header = self.header_dict

3404

self.dataOut.expName = self.expName

3405

self.dataOut.expName = self.expName

3405

self.dataOut.nChannels = self.nChannels

3406

self.dataOut.nChannels = self.nChannels

3406

self.dataOut.timeZone = self.timeZone

3407

self.dataOut.timeZone = self.timeZone

3407

self.dataOut.dataBlocksPerFile = self.dataBlocksPerFile

3408

self.dataOut.dataBlocksPerFile = self.dataBlocksPerFile

3408

self.dataOut.comments = self.comments

3409

self.dataOut.comments = self.comments

3409

self.dataOut.timeInterval = self.timeInterval

3410

self.dataOut.timeInterval = self.timeInterval

3410

self.dataOut.channelList = self.channelList

3411

self.dataOut.channelList = self.channelList

3411

self.dataOut.heightList = self.heightList

3412

self.dataOut.heightList = self.heightList

3412

self.dataOut.flagNoData = False

3413

self.dataOut.flagNoData = False

3413

3414

return self.dataOut.data

3415

return self.dataOut.data

3415

3416

def run(self, **kwargs):

3417

def run(self, **kwargs):

3417

3418

if not(self.isConfig):

3419

if not(self.isConfig):

3419

self.setup(**kwargs)

3420

self.setup(**kwargs)

3420

self.isConfig = True

3421

self.isConfig = True

3421

3422

self.getData()

3423

self.getData()

3423

3424

3425

class RadacHeader():

3426

class RadacHeader():

3426

def __init__(self, fp):

3427

def __init__(self, fp):

3427

header = 'Raw11/Data/RadacHeader'

3428

header = 'Raw11/Data/RadacHeader'

3428

self.beamCodeByPulse = fp.get(header+'/BeamCode')

3429

self.beamCodeByPulse = fp.get(header+'/BeamCode')

3429

self.beamCode = fp.get('Raw11/Data/Beamcodes')

3430

self.beamCode = fp.get('Raw11/Data/Beamcodes')

3430

self.code = fp.get(header+'/Code')

3431

self.code = fp.get(header+'/Code')

3431

self.frameCount = fp.get(header+'/FrameCount')

3432

self.frameCount = fp.get(header+'/FrameCount')

3432

self.modeGroup = fp.get(header+'/ModeGroup')

3433

self.modeGroup = fp.get(header+'/ModeGroup')

3433

self.nsamplesPulse = fp.get(header+'/NSamplesPulse')

3434

self.nsamplesPulse = fp.get(header+'/NSamplesPulse')

3434

self.pulseCount = fp.get(header+'/PulseCount')

3435

self.pulseCount = fp.get(header+'/PulseCount')

3435

self.radacTime = fp.get(header+'/RadacTime')

3436

self.radacTime = fp.get(header+'/RadacTime')

3436

self.timeCount = fp.get(header+'/TimeCount')

3437

self.timeCount = fp.get(header+'/TimeCount')

3437

self.timeStatus = fp.get(header+'/TimeStatus')

3438

self.timeStatus = fp.get(header+'/TimeStatus')

3438

3439

self.nrecords = self.pulseCount.shape[0] #numero de bloques

3440

self.nrecords = self.pulseCount.shape[0] #numero de bloques

3440

self.npulses = self.pulseCount.shape[1] #numero de perfiles

3441

self.npulses = self.pulseCount.shape[1] #numero de perfiles

3441

self.nsamples = self.nsamplesPulse[0,0] #numero de alturas

3442

self.nsamples = self.nsamplesPulse[0,0] #numero de alturas

3442

self.nbeams = self.beamCode.shape[1] #numero de beams

3443

self.nbeams = self.beamCode.shape[1] #numero de beams

3443

3444

3445

def getIndexRangeToPulse(self, idrecord=0):

3446

def getIndexRangeToPulse(self, idrecord=0):

3446

indexToZero = numpy.where(self.pulseCount.value[idrecord,:]==0)

3447

indexToZero = numpy.where(self.pulseCount.value[idrecord,:]==0)

3447

startPulseCountId = indexToZero[0][0]

3448

startPulseCountId = indexToZero[0][0]

3448

endPulseCountId = startPulseCountId - 1

3449

endPulseCountId = startPulseCountId - 1

3449

range1 = numpy.arange(startPulseCountId,self.npulses,1)

3450

range1 = numpy.arange(startPulseCountId,self.npulses,1)

3450

range2 = numpy.arange(0,startPulseCountId,1)

3451

range2 = numpy.arange(0,startPulseCountId,1)

3451

return range1, range2

3452

return range1, range2

3452

3453

3454

class AMISRReader(ProcessingUnit):

3455

class AMISRReader(ProcessingUnit):

3455

3456

path = None

3457

path = None

3457

startDate = None

3458

startDate = None

3458

endDate = None

3459

endDate = None

3459

startTime = None

3460

startTime = None

3460

endTime = None

3461

endTime = None

3461

walk = None

3462

walk = None

3462

isConfig = False

3463

isConfig = False

3463

3464

def __init__(self):

3465

def __init__(self):

3465

self.set = None

3466

self.set = None

3466

self.subset = None

3467

self.subset = None

3467

self.extension_file = '.h5'

3468

self.extension_file = '.h5'

3468

self.dtc_str = 'dtc'

3469

self.dtc_str = 'dtc'

3469

self.dtc_id = 0

3470

self.dtc_id = 0

3470

self.status = True

3471

self.status = True

3471

self.isConfig = False

3472

self.isConfig = False

3472

self.dirnameList = []

3473

self.dirnameList = []

3473

self.filenameList = []

3474

self.filenameList = []

3474

self.fileIndex = None

3475

self.fileIndex = None

3475

self.flagNoMoreFiles = False

3476

self.flagNoMoreFiles = False

3476

self.flagIsNewFile = 0

3477

self.flagIsNewFile = 0

3477

self.filename = ''

3478

self.filename = ''

3478

self.amisrFilePointer = None

3479

self.amisrFilePointer = None

3479

self.radacHeaderObj = None

3480

self.radacHeaderObj = None

3480

self.dataOut = self.__createObjByDefault()

3481

self.dataOut = self.__createObjByDefault()

3481

self.datablock = None

3482

self.datablock = None

3482

self.rest_datablock = None

3483

self.rest_datablock = None

3483

self.range = None

3484

self.range = None

3484

self.idrecord_count = 0

3485

self.idrecord_count = 0

3485

self.profileIndex = 0

3486

self.profileIndex = 0

3486

self.idpulse_range1 = None

3487

self.idpulse_range1 = None

3487

self.idpulse_range2 = None

3488

self.idpulse_range2 = None

3488

self.beamCodeByFrame = None

3489

self.beamCodeByFrame = None

3489

self.radacTimeByFrame = None

3490

self.radacTimeByFrame = None

3490

#atributos originales tal y como esta en el archivo de datos

3491

#atributos originales tal y como esta en el archivo de datos

3491

self.beamCodesFromFile = None

3492

self.beamCodesFromFile = None

3492

self.radacTimeFromFile = None

3493

self.radacTimeFromFile = None

3493

self.rangeFromFile = None

3494

self.rangeFromFile = None

3494

self.dataByFrame = None

3495

self.dataByFrame = None

3495

self.dataset = None

3496

self.dataset = None

3496

3497

self.beamCodeDict = {}

3498

self.beamCodeDict = {}

3498

self.beamRangeDict = {}

3499

self.beamRangeDict = {}

3499

3500

3501

#experiment cgf file

3502

self.npulsesint_fromfile = None

3503

self.recordsperfile_fromfile = None

3504

self.nbeamcodes_fromfile = None

3505

self.ngates_fromfile = None

3506

self.ippSeconds_fromfile = None

3507

self.frequency_h5file = None

3508

3500

3509

3501

def __createObjByDefault(self):

3510

def __createObjByDefault(self):

3502

3511

3503

dataObj = AMISR()

3512

dataObj = AMISR()

3504

3513

3505

return dataObj

3514

return dataObj

3506

3515

3507

def __setParameters(self,path,startDate,endDate,startTime,endTime,walk):

3516

def __setParameters(self,path,startDate,endDate,startTime,endTime,walk):

3508

self.path = path

3517

self.path = path

3509

self.startDate = startDate

3518

self.startDate = startDate

3510

self.endDate = endDate

3519

self.endDate = endDate

3511

self.startTime = startTime

3520

self.startTime = startTime

3512

self.endTime = endTime

3521

self.endTime = endTime

3513

self.walk = walk

3522

self.walk = walk

3514

3523

3515

def __checkPath(self):

3524

def __checkPath(self):

3516

if os.path.exists(self.path):

3525

if os.path.exists(self.path):

3517

self.status = 1

3526

self.status = 1

3518

else:

3527

else:

3519

self.status = 0

3528

self.status = 0

3520

print 'Path:%s does not exists'%self.path

3529

print 'Path:%s does not exists'%self.path

3521

3530

3522

return

3531

return

3523

3532

3524

def __selDates(self, amisr_dirname_format):

3533

def __selDates(self, amisr_dirname_format):

3525

year = int(amisr_dirname_format[0:4])

3534

year = int(amisr_dirname_format[0:4])

3526

month = int(amisr_dirname_format[4:6])

3535

month = int(amisr_dirname_format[4:6])

3527

dom = int(amisr_dirname_format[6:8])

3536

dom = int(amisr_dirname_format[6:8])

3528

thisDate = datetime.date(year,month,dom)

3537

thisDate = datetime.date(year,month,dom)

3529

3538

3530

if (thisDate>=self.startDate and thisDate <= self.endDate):

3539

if (thisDate>=self.startDate and thisDate <= self.endDate):

3531

return amisr_dirname_format

3540

return amisr_dirname_format

3532

3541

3533

def __findDataForDates(self):

3542

def __findDataForDates(self):

3534

3543

3535

~~import~~ re

3544

3536

3545

3537

if not(self.status):

3546

if not(self.status):

3538

return None

3547

return None

3539

3548

3540

pat = '\d+.\d+'

3549

pat = '\d+.\d+'

3541

dirnameList = [re.search(pat,x).string for x in os.listdir(self.path)]

3550

dirnameList = [re.search(pat,x).string for x in os.listdir(self.path)]

3542

dirnameList = [self.__selDates(x) for x in dirnameList]

3551

dirnameList = [self.__selDates(x) for x in dirnameList]

3543

dirnameList = filter(lambda x:x!=None,dirnameList)

3552

dirnameList = filter(lambda x:x!=None,dirnameList)

3544

if len(dirnameList)>0:

3553

if len(dirnameList)>0:

3545

self.status = 1

3554

self.status = 1

3546

self.dirnameList = dirnameList

3555

self.dirnameList = dirnameList

3547

self.dirnameList.sort()

3556

self.dirnameList.sort()

3548

else:

3557

else:

3549

self.status = 0

3558

self.status = 0

3550

return None

3559

return None

3551

3560

3552

def __getTimeFromData(self):

3561

def __getTimeFromData(self):

3553

pass

3562

pass

3554

3563

3555

def __filterByGlob1(self, dirName):

3564

def __filterByGlob1(self, dirName):

3556

filter_files = glob.glob1(dirName, '*.*%s'%self.extension_file)

3565

filter_files = glob.glob1(dirName, '*.*%s'%self.extension_file)

3557

filterDict = {}

3566

filterDict = {}

3558

filterDict.setdefault(dirName)

3567

filterDict.setdefault(dirName)

3559

filterDict[dirName] = filter_files

3568

filterDict[dirName] = filter_files

3560

return filterDict

3569

return filterDict

3561

3570

3562

def __getFilenameList(self, fileListInKeys, dirList):

3571

def __getFilenameList(self, fileListInKeys, dirList):

3563

for value in fileListInKeys:

3572

for value in fileListInKeys:

3564

dirName = value.keys()[0]

3573

dirName = value.keys()[0]

3565

for file in value[dirName]:

3574

for file in value[dirName]:

3566

filename = os.path.join(dirName, file)

3575

filename = os.path.join(dirName, file)

3567

self.filenameList.append(filename)

3576

self.filenameList.append(filename)

3568

3577

3569

3578

3570

def __selectDataForTimes(self):

3579

def __selectDataForTimes(self):

3571

#aun no esta implementado el filtro for tiempo

3580

#aun no esta implementado el filtro for tiempo

3572

if not(self.status):

3581

if not(self.status):

3573

return None

3582

return None

3574

3583

3575

dirList = [os.path.join(self.path,x) for x in self.dirnameList]

3584

dirList = [os.path.join(self.path,x) for x in self.dirnameList]

3576

3585

3577

fileListInKeys = [self.__filterByGlob1(x) for x in dirList]

3586

fileListInKeys = [self.__filterByGlob1(x) for x in dirList]

3578

3587

3579

self.__getFilenameList(fileListInKeys, dirList)

3588

self.__getFilenameList(fileListInKeys, dirList)

3580

3589

3581

if len(self.filenameList)>0:

3590

if len(self.filenameList)>0:

3582

self.status = 1

3591

self.status = 1

3583

self.filenameList.sort()

3592

self.filenameList.sort()

3584

else:

3593

else:

3585

self.status = 0

3594

self.status = 0

3586

return None

3595

return None

3587

3596

3588

3597

3589

def __searchFilesOffline(self,

3598

def __searchFilesOffline(self,

3590

path,

3599

path,

3591

startDate,

3600

startDate,

3592

endDate,

3601

endDate,

3593

startTime=datetime.time(0,0,0),

3602

startTime=datetime.time(0,0,0),

3594

endTime=datetime.time(23,59,59),

3603

endTime=datetime.time(23,59,59),

3595

walk=True):

3604

walk=True):

3596

3605

3597

self.__setParameters(path, startDate, endDate, startTime, endTime, walk)

3606

self.__setParameters(path, startDate, endDate, startTime, endTime, walk)

3598

3607

3599

self.__checkPath()

3608

self.__checkPath()

3600

3609

3601

self.__findDataForDates()

3610

self.__findDataForDates()

3602

3611

3603

self.__selectDataForTimes()

3612

self.__selectDataForTimes()

3604

3613

3605

for i in range(len(self.filenameList)):

3614

for i in range(len(self.filenameList)):

3606

print "%s" %(self.filenameList[i])

3615

print "%s" %(self.filenameList[i])

3607

3616

3608

return

3617

return

3609

3618

3610

def __setNextFileOffline(self):

3619

def __setNextFileOffline(self):

3611

idFile = self.fileIndex

3620

idFile = self.fileIndex

3612

3621

3613

while (True):

3622

while (True):

3614

idFile += 1

3623

idFile += 1

3615

if not(idFile < len(self.filenameList)):

3624

if not(idFile < len(self.filenameList)):

3616

self.flagNoMoreFiles = 1

3625

self.flagNoMoreFiles = 1

3617

print "No more Files"

3626

print "No more Files"

3618

return 0

3627

return 0

3619

3628

3620

filename = self.filenameList[idFile]

3629

filename = self.filenameList[idFile]

3621

3630

3622

amisrFilePointer = h5py.File(filename,'r')

3631

amisrFilePointer = h5py.File(filename,'r')

3623

3632

3624

break

3633

break

3625

3634

3626

self.flagIsNewFile = 1

3635

self.flagIsNewFile = 1

3627

self.fileIndex = idFile

3636

self.fileIndex = idFile

3628

self.filename = filename

3637

self.filename = filename

3629

3638

3630

self.amisrFilePointer = amisrFilePointer

3639

self.amisrFilePointer = amisrFilePointer

3631

3640

3632

print "Setting the file: %s"%self.filename

3641

print "Setting the file: %s"%self.filename

3633

3642

3634

return 1

3643

return 1

3635

3644

3636

def __readHeader(self):

3645

def __readHeader(self):

3637

self.radacHeaderObj = RadacHeader(self.amisrFilePointer)

3646

self.radacHeaderObj = RadacHeader(self.amisrFilePointer)

3647

3648

#update values from experiment cfg file

3649

self.radacHeaderObj.nrecords = self.recordsperfile_fromfile

3650

self.radacHeaderObj.nbeams = self.nbeamcodes_fromfile

3651

self.radacHeaderObj.npulses = self.npulsesint_fromfile

3652

self.radacHeaderObj.nsamples = self.ngates_fromfile

3653

3654

#get tuning frequency

3655

frequency_h5file_dataset = self.amisrFilePointer.get('Rx'+'/TuningFrequency')

3656

self.frequency_h5file = frequency_h5file_dataset[0,0]

3657

3638

self.flagIsNewFile = 1

3658

self.flagIsNewFile = 1

3639

3659

3640

def __getBeamCode(self):

3660

def __getBeamCode(self):

3641

self.beamCodeDict = {}

3661

self.beamCodeDict = {}

3642

self.beamRangeDict = {}

3662

self.beamRangeDict = {}

3643

3663

3644

for i in range(len(self.radacHeaderObj.beamCode[0,:])):

3664

for i in range(len(self.radacHeaderObj.beamCode[0,:])):

3645

self.beamCodeDict.setdefault(i)

3665

self.beamCodeDict.setdefault(i)

3646

self.beamRangeDict.setdefault(i)

3666

self.beamRangeDict.setdefault(i)

3647

self.beamCodeDict[i] = self.radacHeaderObj.beamCode[0,i]

3667

self.beamCodeDict[i] = self.radacHeaderObj.beamCode[0,i]

3648

3668

3649

3669

3650

just4record0 = self.radacHeaderObj.beamCodeByPulse[0,:]

3670

just4record0 = self.radacHeaderObj.beamCodeByPulse[0,:]

3651

3671

3652

for i in range(len(self.beamCodeDict.values())):

3672

for i in range(len(self.beamCodeDict.values())):

3653

xx = numpy.where(just4record0==self.beamCodeDict.values()[i])

3673

xx = numpy.where(just4record0==self.beamCodeDict.values()[i])

3654

self.beamRangeDict[i] = xx[0]

3674

self.beamRangeDict[i] = xx[0]

3675

3676

def __getExpParameters(self):

3677

if not(self.status):

3678

return None

3679

3680

experimentCfgPath = os.path.join(self.path, self.dirnameList[0], 'Setup')

3681

3682

expFinder = glob.glob1(experimentCfgPath,'*.exp')

3683

if len(expFinder)== 0:

3684

self.status = 0

3685

return None

3686

3687

experimentFilename = os.path.join(experimentCfgPath,expFinder[0])

3688

3689

f = open(experimentFilename)

3690

lines = f.readlines()

3691

f.close()

3692

3693

parmsList = ['npulsesint*','recordsperfile*','nbeamcodes*','ngates*']

3694

filterList = [fnmatch.filter(lines, x) for x in parmsList]

3695

3696

3697

values = [re.sub(r'\D',"",x[0]) for x in filterList]

3655

3698

3699

self.npulsesint_fromfile = int(values[0])

3700

self.recordsperfile_fromfile = int(values[1])

3701

self.nbeamcodes_fromfile = int(values[2])

3702

self.ngates_fromfile = int(values[3])

3703

3704

tufileFinder = fnmatch.filter(lines, 'tufile=*')

3705

tufile = tufileFinder[0].split('=')[1].split('\n')[0]

3706

tufilename = os.path.join(experimentCfgPath,tufile)

3707

3708

f = open(tufilename)

3709

lines = f.readlines()

3710

f.close()

3711

self.ippSeconds_fromfile = float(lines[1].split()[2])/1E6

3712

3713

3714

self.status = 1

3656

3715

3657

def __setNextFile(self):

3716

def __setNextFile(self):

3658

3717

3659

newFile = self.__setNextFileOffline()

3718

newFile = self.__setNextFileOffline()

3660

3719

3661

if not(newFile):

3720

if not(newFile):

3662

return 0

3721

return 0

3663

3722

3664

self.__readHeader()

3723

self.__readHeader()

3665

self.__getBeamCode()

3724

self.__getBeamCode()

3666

self.readDataBlock()

3725

self.readDataBlock()

3667

3726

3668

3727

3669

def setup(self,path=None,

3728

def setup(self,path=None,

3670

startDate=None,

3729

startDate=None,

3671

endDate=None,

3730

endDate=None,

3672

startTime=datetime.time(0,0,0),

3731

startTime=datetime.time(0,0,0),

3673

endTime=datetime.time(23,59,59),

3732

endTime=datetime.time(23,59,59),

3674

walk=True):

3733

walk=True):

3675

3734

3676

#Busqueda de archivos offline

3735

#Busqueda de archivos offline

3677

self.__searchFilesOffline(path, startDate, endDate, startTime, endTime, walk)

3736

self.__searchFilesOffline(path, startDate, endDate, startTime, endTime, walk)

3678

3737

3679

if not(self.filenameList):

3738

if not(self.filenameList):

3680

print "There is no files into the folder: %s"%(path)

3739

print "There is no files into the folder: %s"%(path)

3681

3740

3682

sys.exit(-1)

3741

sys.exit(-1)

3683

3742

3743

self.__getExpParameters()

3744

3684

self.fileIndex = -1

3745

self.fileIndex = -1

3685

3746

3686

self.__setNextFile()

3747

self.__setNextFile()

3687

3748

3688

def readRanges(self):

3749

def readRanges(self):

3689

dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Range')

3750

dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Range')

3690

#self.rangeFromFile = dataset.value

3751

#self.rangeFromFile = dataset.value

3691

self.rangeFromFile = numpy.reshape(dataset.value,(-1))

3752

self.rangeFromFile = numpy.reshape(dataset.value,(-1))

3692

return range

3753

return range

3693

3754

3694

3755

3695

def readRadacTime(self,idrecord, range1, range2):

3756

def readRadacTime(self,idrecord, range1, range2):

3696

self.radacTimeFromFile = self.radacHeaderObj.radacTime.value

3757

self.radacTimeFromFile = self.radacHeaderObj.radacTime.value

3697

3758

3698

radacTimeByFrame = numpy.zeros((self.radacHeaderObj.npulses))

3759

radacTimeByFrame = numpy.zeros((self.radacHeaderObj.npulses))

3699

#radacTimeByFrame = dataset[idrecord - 1,range1]

3760

#radacTimeByFrame = dataset[idrecord - 1,range1]

3700

#radacTimeByFrame = dataset[idrecord,range2]

3761

#radacTimeByFrame = dataset[idrecord,range2]

3701

3762

3702

return radacTimeByFrame

3763

return radacTimeByFrame

3703

3764

3704

def readBeamCode(self, idrecord, range1, range2):

3765

def readBeamCode(self, idrecord, range1, range2):

3705

dataset = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode')

3766

dataset = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode')

3706

beamcodeByFrame = numpy.zeros((self.radacHeaderObj.npulses))

3767

beamcodeByFrame = numpy.zeros((self.radacHeaderObj.npulses))

3707

self.beamCodesFromFile = dataset.value

3768

self.beamCodesFromFile = dataset.value

3708

3769

3709

#beamcodeByFrame[range1] = dataset[idrecord - 1, range1]

3770

#beamcodeByFrame[range1] = dataset[idrecord - 1, range1]

3710

#beamcodeByFrame[range2] = dataset[idrecord, range2]

3771

#beamcodeByFrame[range2] = dataset[idrecord, range2]

3711

beamcodeByFrame[range1] = dataset[idrecord, range1]

3772

beamcodeByFrame[range1] = dataset[idrecord, range1]

3712

beamcodeByFrame[range2] = dataset[idrecord, range2]

3773

beamcodeByFrame[range2] = dataset[idrecord, range2]

3713

3774

3714

return beamcodeByFrame

3775

return beamcodeByFrame

3715

3776

3716

3777

3717

def __setDataByFrame(self):

3778

def __setDataByFrame(self):

3718

ndata = 2 # porque es complejo

3779

ndata = 2 # porque es complejo

3719

dataByFrame = numpy.zeros((self.radacHeaderObj.npulses, self.radacHeaderObj.nsamples, ndata))

3780

dataByFrame = numpy.zeros((self.radacHeaderObj.npulses, self.radacHeaderObj.nsamples, ndata))

3720

return dataByFrame

3781

return dataByFrame

3721

3782

3722

def __readDataSet(self):

3783

def __readDataSet(self):

3723

dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Data')

3784

dataset = self.amisrFilePointer.get('Raw11/Data/Samples/Data')

3724

return dataset

3785

return dataset

3725

3786

3726

def __setDataBlock(self,):

3787

def __setDataBlock(self,):

3727

real = self.dataByFrame[:,:,0] #asumo que 0 es real

3788

real = self.dataByFrame[:,:,0] #asumo que 0 es real

3728

imag = self.dataByFrame[:,:,1] #asumo que 1 es imaginario

3789

imag = self.dataByFrame[:,:,1] #asumo que 1 es imaginario

3729

datablock = real + imag*1j #armo el complejo

3790

datablock = real + imag*1j #armo el complejo

3730

return datablock

3791

return datablock

3731

3792

3732

def readSamples_version1(self,idrecord):

3793

def readSamples_version1(self,idrecord):

3733

#estas tres primeras lineas solo se deben ejecutar una vez

3794

#estas tres primeras lineas solo se deben ejecutar una vez

3734

if self.flagIsNewFile:

3795

if self.flagIsNewFile:

3735

self.idpulse_range1, self.idpulse_range2 = self.radacHeaderObj.getIndexRangeToPulse(0)

3796

self.idpulse_range1, self.idpulse_range2 = self.radacHeaderObj.getIndexRangeToPulse(0)

3736

self.dataByFrame = self.__setDataByFrame()

3797

self.dataByFrame = self.__setDataByFrame()

3737

self.beamCodeByFrame = self.readBeamCode(idrecord, self.idpulse_range1, self.idpulse_range2)

3798

self.beamCodeByFrame = self.readBeamCode(idrecord, self.idpulse_range1, self.idpulse_range2)

3738

self.radacTimeByFrame = self.readRadacTime(idrecord, self.idpulse_range1, self.idpulse_range2)

3799

self.radacTimeByFrame = self.readRadacTime(idrecord, self.idpulse_range1, self.idpulse_range2)

3739

#reading dataset

3800

#reading dataset

3740

self.dataset = self.__readDataSet()

3801

self.dataset = self.__readDataSet()

3741

3802

3742

if idrecord == 0:

3803

if idrecord == 0:

3743

3804

3744

if len(numpy.where(self.dataByFrame!=0.0)[0]) or len(numpy.where(self.dataByFrame!=0.0)[1]) or len(numpy.where(self.dataByFrame!=0.0)[2]):

3805

if len(numpy.where(self.dataByFrame!=0.0)[0]) or len(numpy.where(self.dataByFrame!=0.0)[1]) or len(numpy.where(self.dataByFrame!=0.0)[2]):

3745

#falta agregar una condicion para datos discontinuos

3806

#falta agregar una condicion para datos discontinuos

3746

#por defecto une los datos del record anterior

3807

#por defecto une los datos del record anterior

3747

self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]

3808

self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]

3748

#timepulse

3809

#timepulse

3749

self.radacTimeByFrame[self.idpulse_range2] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range2]

3810

self.radacTimeByFrame[self.idpulse_range2] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range2]

3750

else:

3811

else:

3751

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]

3812

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]

3752

3813

3753

self.radacTimeByFrame[self.idpulse_range1] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range1]

3814

self.radacTimeByFrame[self.idpulse_range1] = self.radacHeaderObj.radacTime[idrecord, self.idpulse_range1]

3754

3815

3755

datablock = self.__setDataBlock()

3816

datablock = self.__setDataBlock()

3756

3817

3757

return datablock

3818

return datablock

3758

3819

3759

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord - 1,self.idpulse_range1, :, :]

3820

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord - 1,self.idpulse_range1, :, :]

3760

self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]

3821

self.dataByFrame[self.idpulse_range2, :, :] = self.dataset[idrecord, self.idpulse_range2, :, :]

3761

datablock = self.__setDataBlock()

3822

datablock = self.__setDataBlock()

3762

self.flagIsNewFile = 0

3823

self.flagIsNewFile = 0

3763

3824

3764

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]

3825

self.dataByFrame[self.idpulse_range1, :, :] = self.dataset[idrecord, self.idpulse_range1, :, :]

3765

3826

3766

3827

3767

return datablock

3828

return datablock

3768

3829

3769

3830

3770

def readSamples(self,idrecord):

3831

def readSamples(self,idrecord):

3771

if self.flagIsNewFile:

3832

if self.flagIsNewFile:

3772

self.dataByFrame = self.__setDataByFrame()

3833

self.dataByFrame = self.__setDataByFrame()

3773

self.beamCodeByFrame = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode').value[idrecord, :]

3834

self.beamCodeByFrame = self.amisrFilePointer.get('Raw11/Data/RadacHeader/BeamCode').value[idrecord, :]

3774

3835

3775

#reading ranges

3836

#reading ranges

3776

self.readRanges()

3837

self.readRanges()

3777

#reading dataset

3838

#reading dataset

3778

self.dataset = self.__readDataSet()

3839

self.dataset = self.__readDataSet()

3779

3840

3780

self.flagIsNewFile = 0

3841

self.flagIsNewFile = 0

3781

self.radacTimeByFrame = self.radacHeaderObj.radacTime.value[idrecord, :]

3842

self.radacTimeByFrame = self.radacHeaderObj.radacTime.value[idrecord, :]

3782

self.dataByFrame = self.dataset[idrecord, :, :, :]

3843

self.dataByFrame = self.dataset[idrecord, :, :, :]

3783

datablock = self.__setDataBlock()

3844

datablock = self.__setDataBlock()

3784

return datablock

3845

return datablock

3785

3846

3786

3847

3787

def readDataBlock(self):

3848

def readDataBlock(self):

3788

3849

3789

#self.datablock = self.readSamples(self.idrecord_count)

3850

#self.datablock = self.readSamples(self.idrecord_count)

3790

self.datablock = self.readSamples(self.idrecord_count)

3851

self.datablock = self.readSamples(self.idrecord_count)

3791

#print 'record:', self.idrecord_count

3852

#print 'record:', self.idrecord_count

3792

3853

3793

self.idrecord_count += 1

3854

self.idrecord_count += 1

3794

self.profileIndex = 0

3855

self.profileIndex = 0

3795

3856

3796

if self.idrecord_count >= self.radacHeaderObj.nrecords:

3857

if self.idrecord_count >= self.radacHeaderObj.nrecords:

3797

self.idrecord_count = 0

3858

self.idrecord_count = 0

3798

self.flagIsNewFile = 1

3859

self.flagIsNewFile = 1

3799

3860

3800

def readNextBlock(self):

3861

def readNextBlock(self):

3801

3862

3802

self.readDataBlock()

3863

self.readDataBlock()

3803

3864

3804

if self.flagIsNewFile:

3865

if self.flagIsNewFile:

3805

self.__setNextFile()

3866

self.__setNextFile()

3806

pass

3867

pass

3807

3868

3808

def __hasNotDataInBuffer(self):

3869

def __hasNotDataInBuffer(self):

3809

#self.radacHeaderObj.npulses debe ser otra variable para considerar el numero de pulsos a tomar en el primer y ultimo record

3870

#self.radacHeaderObj.npulses debe ser otra variable para considerar el numero de pulsos a tomar en el primer y ultimo record

3810

if self.profileIndex >= self.radacHeaderObj.npulses:

3871

if self.profileIndex >= self.radacHeaderObj.npulses:

3811

return 1

3872

return 1

3812

return 0

3873

return 0

3813

3874

3814

def printUTC(self):

3875

def printUTC(self):

3815

print self.dataOut.utctime

3876

print self.dataOut.utctime

3816

print ''

3877

print ''

3817

3878

3818

def setObjProperties(self):

3879

def setObjProperties(self):

3819

self.dataOut.heightList = self.rangeFromFile/1000.0 #km

3880

self.dataOut.heightList = self.rangeFromFile/1000.0 #km

3820

self.dataOut.nProfiles = self.radacHeaderObj.npulses

3881

self.dataOut.nProfiles = self.radacHeaderObj.npulses

3882

self.dataOut.ippSeconds = self.ippSeconds_fromfile

3821

self.dataOut.timeInterval = self.dataOut.ippSeconds * self.dataOut.nCohInt

3883

self.dataOut.timeInterval = self.dataOut.ippSeconds * self.dataOut.nCohInt

3884

self.dataOut.frequency = self.frequency_h5file

3822

self.dataOut.nBaud = None

3885

self.dataOut.nBaud = None

3823

self.dataOut.nCode = None

3886

self.dataOut.nCode = None

3824

self.dataOut.code = None

3887

self.dataOut.code = None

3825

3888

3826

self.dataOut.beamCodeDict = self.beamCodeDict

3889

self.dataOut.beamCodeDict = self.beamCodeDict

3827

self.dataOut.beamRangeDict = self.beamRangeDict

3890

self.dataOut.beamRangeDict = self.beamRangeDict

3828

3891

3829

def getData(self):

3892

def getData(self):

3830

3893

3831

if self.flagNoMoreFiles:

3894

if self.flagNoMoreFiles:

3832

self.dataOut.flagNoData = True

3895

self.dataOut.flagNoData = True

3833

print 'Process finished'

3896

print 'Process finished'

3834

return 0

3897

return 0

3835

3898

3836

if self.__hasNotDataInBuffer():

3899

if self.__hasNotDataInBuffer():

3837

self.readNextBlock()

3900

self.readNextBlock()

3838

# if not( self.readNextBlock() ):

3901

# if not( self.readNextBlock() ):

3839

# return 0

3902

# return 0

3840

# self.getFirstHeader()

3903

# self.getFirstHeader()

3841

3904

3842

if self.datablock == None: # setear esta condicion cuando no hayan datos por leers

3905

if self.datablock == None: # setear esta condicion cuando no hayan datos por leers

3843

self.dataOut.flagNoData = True

3906

self.dataOut.flagNoData = True

3844

return 0

3907

return 0

3845

3908

3846

self.dataOut.data = numpy.reshape(self.datablock[self.profileIndex,:],(1,-1))

3909

self.dataOut.data = numpy.reshape(self.datablock[self.profileIndex,:],(1,-1))

3847

3910

3848

self.dataOut.utctime = self.radacTimeByFrame[self.profileIndex]

3911

self.dataOut.utctime = self.radacTimeByFrame[self.profileIndex]

3849

3912

3850

self.dataOut.flagNoData = False

3913

self.dataOut.flagNoData = False

3851

3914

3852

self.profileIndex += 1

3915

self.profileIndex += 1

3853

3916

3854

return self.dataOut.data

3917

return self.dataOut.data

3855

3918

3856

3919

3857

def run(self, **kwargs):

3920

def run(self, **kwargs):

3858

if not(self.isConfig):

3921

if not(self.isConfig):

3859

self.setup(**kwargs)

3922

self.setup(**kwargs)

3860

self.setObjProperties()

3923

self.setObjProperties()

3861

self.isConfig = True

3924

self.isConfig = True

3862

3925

3863

self.getData()

3926

self.getData()

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@@ -1,287 +1,326
1	import os, sys	1	import os, sys
2		2
3	path = os.path.split(os.getcwd())[0]	3	path = os.path.split(os.getcwd())[0]
4	sys.path.append(path)	4	sys.path.append(path)
5		5
6	from controller import *	6	from controller import *
7		7
8	desc = "AMISR Experiment Test"	8	desc = "AMISR Experiment Test"
9	filename = "amisr.xml"	9	filename = "amisr.xml"
10		10
11	controllerObj = Project()	11	controllerObj = Project()
12		12
13	controllerObj.setup(id = '191', name='test01', description=desc)	13	controllerObj.setup(id = '191', name='test01', description=desc)
14		14
15	path = '/home/administrator/Documents/amisr'	15	path = '/home/administrator/Documents/amisr'
16	path = '/media/administrator/New Volume/amisr'	16	path = '/media/administrator/New Volume/amisr'
17		17
18	figpath = '/home/administrator/Pictures/amisr'	18	figpath = '/home/administrator/Pictures/amisr'
19		19
20	figfile0 = 'amisr_rti_beam0.png'	20	figfile0 = 'amisr_rti_beam0.png'
21	figfile1 = 'amisr_rti_beam1.png'	21	figfile1 = 'amisr_rti_beam1.png'
22	figfile2 = 'amisr_rti_beam2.png'	22	figfile2 = 'amisr_rti_beam2.png'
23	figfile3 = 'amisr_rti_beam3.png'	23	figfile3 = 'amisr_rti_beam3.png'
24	figfile4 = 'amisr_rti_beam4.png'	24	figfile4 = 'amisr_rti_beam4.png'
25	figfile5 = 'amisr_rti_beam5.png'	25	figfile5 = 'amisr_rti_beam5.png'
26	figfile6 = 'amisr_rti_beam6.png'	26	figfile6 = 'amisr_rti_beam6.png'
27		27
28	title0 = 'RTI AMISR Beam 0'	28	title0 = 'RTI AMISR Beam 0'
29	title1 = 'RTI AMISR Beam 1'	29	title1 = 'RTI AMISR Beam 1'
30	title2 = 'RTI AMISR Beam 2'	30	title2 = 'RTI AMISR Beam 2'
31	title3 = 'RTI AMISR Beam 3'	31	title3 = 'RTI AMISR Beam 3'
32	title4 = 'RTI AMISR Beam 4'	32	title4 = 'RTI AMISR Beam 4'
33	title5 = 'RTI AMISR Beam 5'	33	title5 = 'RTI AMISR Beam 5'
34	title6 = 'RTI AMISR Beam 6'	34	title6 = 'RTI AMISR Beam 6'
35		35
		36	profileStrSelBeam0 = '0,101'
		37	profileStrSelBeam1 = '614,741'
		38	profileStrSelBeam2 = '358,485'
		39	profileStrSelBeam3 = '742,869'