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jroIO_voltage.py
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'''
Created on Jul 2, 2014
@author: roj-idl71
'''
import numpy
from .jroIO_base import LOCALTIME, JRODataReader, JRODataWriter
from schainpy.model.proc.jroproc_base import ProcessingUnit, Operation
from schainpy.model.data.jroheaderIO import PROCFLAG, BasicHeader, SystemHeader, RadarControllerHeader, ProcessingHeader
from schainpy.model.data.jrodata import Voltage
import zmq
import tempfile
from io import StringIO
# from _sha import blocksize
class VoltageReader(JRODataReader, ProcessingUnit):
"""
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, **kwargs):
"""
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
"""
ProcessingUnit.__init__(self, **kwargs)
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.flagDiscontinuousBlock = 0
self.flagIsNewBlock = 0
self.nTotalBlocks = 0
self.blocksize = 0
self.dataOut = self.createObjByDefault()
self.nTxs = 1
self.txIndex = 0
def createObjByDefault(self):
dataObj = Voltage()
return dataObj
def __hasNotDataInBuffer(self):
if self.profileIndex >= self.processingHeaderObj.profilesPerBlock * self.nTxs:
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
"""
# if self.server is not None:
# self.zBlock = self.receiver.recv()
# self.zHeader = self.zBlock[:24]
# self.zDataBlock = self.zBlock[24:]
# junk = numpy.fromstring(self.zDataBlock, numpy.dtype([('real','<i4'),('imag','<i4')]))
# self.processingHeaderObj.profilesPerBlock = 240
# self.processingHeaderObj.nHeights = 248
# self.systemHeaderObj.nChannels
# else:
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
# Dimensions : nChannels, nProfiles, nSamples
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.getBasicHeader()
self.dataOut.processingHeaderObj = self.processingHeaderObj.copy()
self.dataOut.systemHeaderObj = self.systemHeaderObj.copy()
self.dataOut.radarControllerHeaderObj = self.radarControllerHeaderObj.copy()
if self.nTxs > 1:
self.dataOut.radarControllerHeaderObj.ippSeconds = self.radarControllerHeaderObj.ippSeconds / self.nTxs
# Time interval and code are propierties of dataOut. Its value depends of radarControllerHeaderObj.
# self.dataOut.timeInterval = self.radarControllerHeaderObj.ippSeconds * self.processingHeaderObj.nCohInt
#
# if self.radarControllerHeaderObj.code is not None:
#
# self.dataOut.nCode = self.radarControllerHeaderObj.nCode
#
# self.dataOut.nBaud = self.radarControllerHeaderObj.nBaud
#
# self.dataOut.code = self.radarControllerHeaderObj.code
self.dataOut.dtype = self.dtype
self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock
self.dataOut.heightList = numpy.arange(
self.processingHeaderObj.nHeights) * self.processingHeaderObj.deltaHeight + self.processingHeaderObj.firstHeight
self.dataOut.channelList = list(range(self.systemHeaderObj.nChannels))
self.dataOut.nCohInt = self.processingHeaderObj.nCohInt
# asumo q la data no esta decodificada
self.dataOut.flagDecodeData = self.processingHeaderObj.flag_decode
# asumo q la data no esta sin flip
self.dataOut.flagDeflipData = self.processingHeaderObj.flag_deflip
self.dataOut.flagShiftFFT = self.processingHeaderObj.shif_fft
def reshapeData(self):
if self.nTxs < 0:
return
if self.nTxs == 1:
return
if self.nTxs < 1 and self.processingHeaderObj.profilesPerBlock % (1. / self.nTxs) != 0:
raise ValueError("1./nTxs (=%f), should be a multiple of nProfiles (=%d)" % (
1. / self.nTxs, self.processingHeaderObj.profilesPerBlock))
if self.nTxs > 1 and self.processingHeaderObj.nHeights % self.nTxs != 0:
raise ValueError("nTxs (=%d), should be a multiple of nHeights (=%d)" % (
self.nTxs, self.processingHeaderObj.nHeights))
self.datablock = self.datablock.reshape(
(self.systemHeaderObj.nChannels, self.processingHeaderObj.profilesPerBlock * self.nTxs, self.processingHeaderObj.nHeights / self.nTxs))
self.dataOut.nProfiles = self.processingHeaderObj.profilesPerBlock * self.nTxs
self.dataOut.heightList = numpy.arange(self.processingHeaderObj.nHeights / self.nTxs) * \
self.processingHeaderObj.deltaHeight + self.processingHeaderObj.firstHeight
self.dataOut.radarControllerHeaderObj.ippSeconds = self.radarControllerHeaderObj.ippSeconds / self.nTxs
return
def readFirstHeaderFromServer(self):
self.getFirstHeader()
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 getFromServer(self):
self.flagDiscontinuousBlock = 0
self.profileIndex = 0
self.flagIsNewBlock = 1
self.dataOut.flagNoData = False
self.nTotalBlocks += 1
self.nReadBlocks += 1
self.blockPointer = 0
block = self.receiver.recv()
self.basicHeaderObj.read(block[self.blockPointer:])
self.blockPointer += self.basicHeaderObj.length
self.systemHeaderObj.read(block[self.blockPointer:])
self.blockPointer += self.systemHeaderObj.length
self.radarControllerHeaderObj.read(block[self.blockPointer:])
self.blockPointer += self.radarControllerHeaderObj.length
self.processingHeaderObj.read(block[self.blockPointer:])
self.blockPointer += self.processingHeaderObj.length
self.readFirstHeaderFromServer()
timestamp = self.basicHeaderObj.get_datatime()
print('[Reading] - Block {} - {}'.format(self.nTotalBlocks, timestamp))
current_pointer_location = self.blockPointer
junk = numpy.fromstring(
block[self.blockPointer:], 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.fromstring(
block[self.blockPointer:], self.dtype, self.blocksize)
junk = junk.reshape((self.processingHeaderObj.profilesPerBlock,
self.processingHeaderObj.nHeights, self.systemHeaderObj.nChannels))
# return 0
# Dimensions : nChannels, nProfiles, nSamples
junk = numpy.transpose(junk, (2, 0, 1))
self.datablock = junk['real'] + junk['imag'] * 1j
self.profileIndex = 0
if self.selBlocksize == None:
self.selBlocksize = self.dataOut.nProfiles
if self.selBlocktime != None:
if self.dataOut.nCohInt is not None:
nCohInt = self.dataOut.nCohInt
else:
nCohInt = 1
self.selBlocksize = int(self.dataOut.nProfiles * round(self.selBlocktime / (
nCohInt * self.dataOut.ippSeconds * self.dataOut.nProfiles)))
self.dataOut.data = self.datablock[:,
self.profileIndex:self.profileIndex + self.selBlocksize, :]
datasize = self.dataOut.data.shape[1]
if datasize < self.selBlocksize:
buffer = numpy.zeros(
(self.dataOut.data.shape[0], self.selBlocksize, self.dataOut.data.shape[2]), dtype='complex')
buffer[:, :datasize, :] = self.dataOut.data
self.dataOut.data = buffer
self.profileIndex = blockIndex
self.dataOut.flagDataAsBlock = True
self.flagIsNewBlock = 1
self.dataOut.realtime = self.online
return self.dataOut.data
def getData(self):
"""
getData obtiene una unidad de datos del buffer de lectura, un perfil, y la copia al objeto self.dataOut
del tipo "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 "self.profileIndex" en 1.
Return:
Si el flag self.getByBlock ha sido seteado el bloque completo es copiado a self.dataOut y el self.profileIndex
es igual al total de perfiles leidos desde el archivo.
Si self.getByBlock == False:
self.dataOut.data = buffer[:, thisProfile, :]
shape = [nChannels, nHeis]
Si self.getByBlock == True:
self.dataOut.data = buffer[:, :, :]
shape = [nChannels, nProfiles, nHeis]
Variables afectadas:
self.dataOut
self.profileIndex
Affected:
self.dataOut
self.profileIndex
self.flagDiscontinuousBlock
self.flagIsNewBlock
"""
if self.flagNoMoreFiles:
self.dataOut.flagNoData = True
print('Process finished')
return 0
self.flagDiscontinuousBlock = 0
self.flagIsNewBlock = 0
if self.__hasNotDataInBuffer():
if not(self.readNextBlock()):
return 0
self.getFirstHeader()
self.reshapeData()
if self.datablock is None:
self.dataOut.flagNoData = True
return 0
if not self.getByBlock:
"""
Return profile by profile
If nTxs > 1 then one profile is divided by nTxs and number of total
blocks is increased by nTxs (nProfiles *= nTxs)
"""
self.dataOut.flagDataAsBlock = False
self.dataOut.data = self.datablock[:, self.profileIndex, :]
self.dataOut.profileIndex = self.profileIndex
self.profileIndex += 1
# elif self.selBlocksize==None or self.selBlocksize==self.dataOut.nProfiles:
# """
# Return all block
# """
# self.dataOut.flagDataAsBlock = True
# self.dataOut.data = self.datablock
# self.dataOut.profileIndex = self.dataOut.nProfiles - 1
#
# self.profileIndex = self.dataOut.nProfiles
else:
"""
Return a block
"""
if self.selBlocksize == None:
self.selBlocksize = self.dataOut.nProfiles
if self.selBlocktime != None:
if self.dataOut.nCohInt is not None:
nCohInt = self.dataOut.nCohInt
else:
nCohInt = 1
self.selBlocksize = int(self.dataOut.nProfiles * round(self.selBlocktime / (
nCohInt * self.dataOut.ippSeconds * self.dataOut.nProfiles)))
self.dataOut.data = self.datablock[:,
self.profileIndex:self.profileIndex + self.selBlocksize, :]
self.profileIndex += self.selBlocksize
datasize = self.dataOut.data.shape[1]
if datasize < self.selBlocksize:
buffer = numpy.zeros(
(self.dataOut.data.shape[0], self.selBlocksize, self.dataOut.data.shape[2]), dtype='complex')
buffer[:, :datasize, :] = self.dataOut.data
while datasize < self.selBlocksize: # Not enough profiles to fill the block
if not(self.readNextBlock()):
return 0
self.getFirstHeader()
self.reshapeData()
if self.datablock is None:
self.dataOut.flagNoData = True
return 0
# stack data
blockIndex = self.selBlocksize - datasize
datablock1 = self.datablock[:, :blockIndex, :]
buffer[:, datasize:datasize +
datablock1.shape[1], :] = datablock1
datasize += datablock1.shape[1]
self.dataOut.data = buffer
self.profileIndex = blockIndex
self.dataOut.flagDataAsBlock = True
self.dataOut.nProfiles = self.dataOut.data.shape[1]
self.dataOut.flagNoData = False
self.getBasicHeader()
self.dataOut.realtime = self.online
return self.dataOut.data
class VoltageWriter(JRODataWriter, Operation):
"""
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, **kwargs):
"""
Inicializador de la clase VoltageWriter para la escritura de datos de espectros.
Affected:
self.dataOut
Return: None
"""
Operation.__init__(self, **kwargs)
self.nTotalBlocks = 0
self.profileIndex = 0
self.isConfig = False
self.fp = None
self.flagIsNewFile = 1
self.blockIndex = 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
# print "[Writing] Block = %04d" %self.blockIndex
def putData(self):
"""
Setea un bloque de datos y luego los escribe en un file
Affected:
self.flagIsNewBlock
self.profileIndex
Return:
0 : Si no hay data o no hay mas files que puedan escribirse
1 : Si se escribio la data de un bloque en un file
"""
if self.dataOut.flagNoData:
return 0
self.flagIsNewBlock = 0
if self.dataOut.flagDiscontinuousBlock:
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 __getBlockSize(self):
'''
Este metodos determina el cantidad de bytes para un bloque de datos de tipo Voltage
'''
dtype_width = self.getDtypeWidth()
blocksize = int(self.dataOut.nHeights * self.dataOut.nChannels *
self.profilesPerBlock * dtype_width * 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.processingHeaderObj.dtype = 0 # Voltage
self.processingHeaderObj.blockSize = self.__getBlockSize()
self.processingHeaderObj.profilesPerBlock = self.profilesPerBlock
self.processingHeaderObj.dataBlocksPerFile = self.blocksPerFile
# podria ser 1 o self.dataOut.processingHeaderObj.nWindows
self.processingHeaderObj.nWindows = 1
self.processingHeaderObj.nCohInt = self.dataOut.nCohInt
# Cuando la data de origen es de tipo Voltage
self.processingHeaderObj.nIncohInt = 1
# Cuando la data de origen es de tipo Voltage
self.processingHeaderObj.totalSpectra = 0
if self.dataOut.code is not None:
self.processingHeaderObj.code = self.dataOut.code
self.processingHeaderObj.nCode = self.dataOut.nCode
self.processingHeaderObj.nBaud = self.dataOut.nBaud
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
self.processingHeaderObj.processFlags = self.getProcessFlags()
self.setBasicHeader()