Ejemplo n.º 1
0
    def decode(self, data):
        v = super(Channel201501Decoder, self).decode(data)
        self.set_property(v, 'alpha', data.get('Alpha'))
        self.set_property(v, 'blue', data.get('Blue'))
        self.set_property(v, 'green', data.get('Green'))
        self.set_property(v, 'red', data.get('Red'))
        self.set_property(v, 'lookupTable', data.get('omero:lookupTable'))

        logical_channel = LogicalChannelI(data.get('omero:LogicalChannelId'))
        logical_channel.emissionWave = \
            self.to_unit(data.get('EmissionWavelength'))
        logical_channel.excitationWave = \
            self.to_unit(data.get('ExcitationWavelength'))
        self.set_property(logical_channel, 'fluor', data.get('Fluor'))
        self.set_property(logical_channel, 'name', data.get('Name'))
        self.set_property(logical_channel, 'ndFilter', data.get('NDFilter'))
        logical_channel.pinHoleSize = self.to_unit(data.get('PinholeSize'))
        self.set_property(
            logical_channel, 'pockelCellSetting', data.get('PockelCellSetting')
        )
        self.set_property(
            logical_channel, 'samplesPerPixel', data.get('SamplesPerPixel')
        )
        contrast_method = data.get('ContrastMethod')
        if contrast_method is not None:
            contrast_method_decoder = self.ctx.get_decoder(
                contrast_method['@type']
            )
            logical_channel.contrastMethod = contrast_method_decoder.decode(
                contrast_method
            )
        illumination = data.get('Illumination')
        if illumination is not None:
            illumination_decoder = self.ctx.get_decoder(
                illumination['@type']
            )
            logical_channel.illumination = illumination_decoder.decode(
                illumination
            )
        acquisition_mode = data.get('AcquisitionMode')
        if acquisition_mode is not None:
            acquisition_mode_decoder = self.ctx.get_decoder(
                acquisition_mode['@type']
            )
            logical_channel.mode = acquisition_mode_decoder.decode(
                acquisition_mode
            )
        photometric_interpretation = \
            data.get('omero:photometricInterpretation')
        if photometric_interpretation is not None:
            photometric_interpretation_decoder = self.ctx.get_decoder(
                photometric_interpretation['@type']
            )
            logical_channel.photometricInterpretation = \
                photometric_interpretation_decoder.decode(
                    photometric_interpretation
                )
        v.logicalChannel = logical_channel

        return v
Ejemplo n.º 2
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    def decode(self, data):
        v = super(Channel201501Decoder, self).decode(data)
        self.set_property(v, 'alpha', data.get('Alpha'))
        self.set_property(v, 'blue', data.get('Blue'))
        self.set_property(v, 'green', data.get('Green'))
        self.set_property(v, 'red', data.get('Red'))
        self.set_property(v, 'lookupTable', data.get('omero:lookupTable'))

        logical_channel = LogicalChannelI(data.get('omero:LogicalChannelId'))
        logical_channel.emissionWave = \
            self.to_unit(data.get('EmissionWavelength'))
        logical_channel.excitationWave = \
            self.to_unit(data.get('ExcitationWavelength'))
        self.set_property(logical_channel, 'fluor', data.get('Fluor'))
        self.set_property(logical_channel, 'name', data.get('Name'))
        self.set_property(logical_channel, 'ndFilter', data.get('NDFilter'))
        logical_channel.pinHoleSize = self.to_unit(data.get('PinholeSize'))
        self.set_property(
            logical_channel, 'pockelCellSetting', data.get('PockelCellSetting')
        )
        self.set_property(
            logical_channel, 'samplesPerPixel', data.get('SamplesPerPixel')
        )
        contrast_method = data.get('ContrastMethod')
        if contrast_method is not None:
            contrast_method_decoder = self.ctx.get_decoder(
                contrast_method['@type']
            )
            logical_channel.contrastMethod = contrast_method_decoder.decode(
                contrast_method
            )
        illumination = data.get('Illumination')
        if illumination is not None:
            illumination_decoder = self.ctx.get_decoder(
                illumination['@type']
            )
            logical_channel.illumination = illumination_decoder.decode(
                illumination
            )
        acquisition_mode = data.get('AcquisitionMode')
        if acquisition_mode is not None:
            acquisition_mode_decoder = self.ctx.get_decoder(
                acquisition_mode['@type']
            )
            logical_channel.mode = acquisition_mode_decoder.decode(
                acquisition_mode
            )
        photometric_interpretation = \
            data.get('omero:photometricInterpretation')
        if photometric_interpretation is not None:
            photometric_interpretation_decoder = self.ctx.get_decoder(
                photometric_interpretation['@type']
            )
            logical_channel.photometricInterpretation = \
                photometric_interpretation_decoder.decode(
                    photometric_interpretation
                )
        v.logicalChannel = logical_channel

        return v
Ejemplo n.º 3
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def emissionWave_channel(image_channel_factory):
    channels = list()
    emission_waves = (LengthI(123.0, 'NANOMETER'), LengthI(456.0, 'NANOMETER'))
    for emission_wave in emission_waves:
        channel = ChannelI()
        lchannel = LogicalChannelI()
        lchannel.emissionWave = emission_wave
        channel.logicalChannel = lchannel
        channels.append(channel)
    return image_channel_factory(channels)
def emissionWave_channel(image_channel_factory):
    channels = list()
    emission_waves = (LengthI(123.0, 'NANOMETER'), LengthI(456.0, 'NANOMETER'))
    for emission_wave in emission_waves:
        channel = ChannelI()
        lchannel = LogicalChannelI()
        lchannel.emissionWave = emission_wave
        channel.logicalChannel = lchannel
        channels.append(channel)
    return image_channel_factory(channels)
Ejemplo n.º 5
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def create_image(image_id, with_pixels=False):
    image_format = FormatI(1L)
    image_format.value = rstring("PNG")

    image = ImageI()
    image.id = rlong(image_id)
    image.acquisitionDate = rtime(1L)
    image.archived = rbool(False)
    image.description = rstring("image_description_%d" % image_id)
    image.name = rstring("image_name_%d" % image_id)
    image.partial = rbool(False)
    image.series = rint(0)
    image.format = image_format
    if not with_pixels:
        return image
    dimension_order = DimensionOrderI(1L)
    dimension_order.value = rstring("XYZCT")
    pixels_type = PixelsTypeI(1L)
    pixels_type.value = "bit"

    pixels = PixelsI(1L)
    pixels.methodology = rstring("methodology")
    pixels.physicalSizeX = LengthI(1.0, UnitsLength.MICROMETER)
    pixels.physicalSizeY = LengthI(2.0, UnitsLength.MICROMETER)
    pixels.physicalSizeZ = LengthI(3.0, UnitsLength.MICROMETER)
    pixels.sha1 = rstring("61ee8b5601a84d5154387578466c8998848ba089")
    pixels.significantBits = rint(16)
    pixels.sizeX = rint(1)
    pixels.sizeY = rint(2)
    pixels.sizeZ = rint(3)
    pixels.sizeC = rint(4)
    pixels.sizeT = rint(5)
    pixels.timeIncrement = TimeI(1.0, UnitsTime.MILLISECOND)
    pixels.waveIncrement = rdouble(2.0)
    pixels.waveStart = rint(1)
    pixels.dimensionOrder = dimension_order
    pixels.pixelsType = pixels_type
    image.addPixels(pixels)

    contrast_method = ContrastMethodI(8L)
    contrast_method.value = rstring("Fluorescence")
    illumination = IlluminationI(1L)
    illumination.value = rstring("Transmitted")
    acquisition_mode = AcquisitionModeI(1L)
    acquisition_mode.value = rstring("WideField")
    photometric_interpretation = PhotometricInterpretationI(1L)
    photometric_interpretation.value = rstring("RGB")

    channel_1 = ChannelI(1L)
    channel_1.alpha = rint(255)
    channel_1.blue = rint(0)
    channel_1.green = rint(255)
    channel_1.red = rint(0)
    channel_1.lookupTable = rstring("rainbow")
    logical_channel_1 = LogicalChannelI(1L)
    logical_channel_1.emissionWave = LengthI(509.0, UnitsLength.NANOMETER)
    logical_channel_1.excitationWave = LengthI(488.0, UnitsLength.NANOMETER)
    logical_channel_1.fluor = rstring("GFP")
    logical_channel_1.name = rstring("GFP/488")
    logical_channel_1.ndFilter = rdouble(1.0)
    logical_channel_1.pinHoleSize = LengthI(1.0, UnitsLength.NANOMETER)
    logical_channel_1.pockelCellSetting = rint(0)
    logical_channel_1.samplesPerPixel = rint(2)
    logical_channel_1.contrastMethod = contrast_method
    logical_channel_1.illumination = illumination
    logical_channel_1.mode = acquisition_mode
    logical_channel_1.photometricInterpretation = photometric_interpretation
    channel_1.logicalChannel = logical_channel_1

    channel_2 = ChannelI(2L)
    channel_2.alpha = rint(255)
    channel_2.blue = rint(255)
    channel_2.green = rint(0)
    channel_2.red = rint(0)
    channel_2.lookupTable = rstring("rainbow")
    logical_channel_2 = LogicalChannelI(2L)
    logical_channel_2.emissionWave = LengthI(470.0, UnitsLength.NANOMETER)
    logical_channel_2.excitationWave = LengthI(405.0, UnitsLength.NANOMETER)
    logical_channel_2.fluor = rstring("DAPI")
    logical_channel_2.name = rstring("DAPI/405")
    logical_channel_2.ndFilter = rdouble(1.0)
    logical_channel_2.pinHoleSize = LengthI(2.0, UnitsLength.NANOMETER)
    logical_channel_2.pockelCellSetting = rint(0)
    logical_channel_2.samplesPerPixel = rint(2)
    logical_channel_2.contrastMethod = contrast_method
    logical_channel_2.illumination = illumination
    logical_channel_2.mode = acquisition_mode
    logical_channel_2.photometricInterpretation = photometric_interpretation
    channel_2.logicalChannel = logical_channel_2

    pixels.addChannel(channel_1)
    pixels.addChannel(channel_2)
    return image
Ejemplo n.º 6
0
def create_image(image_id, with_pixels=False):
    image_format = FormatI(1)
    image_format.value = rstring('PNG')

    image = ImageI()
    image.id = rlong(image_id)
    image.acquisitionDate = rtime(1)
    image.archived = rbool(False)
    image.description = rstring('image_description_%d' % image_id)
    image.name = rstring('image_name_%d' % image_id)
    image.partial = rbool(False)
    image.series = rint(0)
    image.format = image_format
    if not with_pixels:
        return image
    dimension_order = DimensionOrderI(1)
    dimension_order.value = rstring('XYZCT')
    pixels_type = PixelsTypeI(1)
    pixels_type.value = 'bit'

    pixels = PixelsI(1)
    pixels.methodology = rstring('methodology')
    pixels.physicalSizeX = LengthI(1.0, UnitsLength.MICROMETER)
    pixels.physicalSizeY = LengthI(2.0, UnitsLength.MICROMETER)
    pixels.physicalSizeZ = LengthI(3.0, UnitsLength.MICROMETER)
    pixels.sha1 = rstring('61ee8b5601a84d5154387578466c8998848ba089')
    pixels.significantBits = rint(16)
    pixels.sizeX = rint(1)
    pixels.sizeY = rint(2)
    pixels.sizeZ = rint(3)
    pixels.sizeC = rint(4)
    pixels.sizeT = rint(5)
    pixels.timeIncrement = TimeI(1.0, UnitsTime.MILLISECOND)
    pixels.waveIncrement = rdouble(2.0)
    pixels.waveStart = rint(1)
    pixels.dimensionOrder = dimension_order
    pixels.pixelsType = pixels_type
    image.addPixels(pixels)

    contrast_method = ContrastMethodI(8)
    contrast_method.value = rstring('Fluorescence')
    illumination = IlluminationI(1)
    illumination.value = rstring('Transmitted')
    acquisition_mode = AcquisitionModeI(1)
    acquisition_mode.value = rstring('WideField')
    photometric_interpretation = PhotometricInterpretationI(1)
    photometric_interpretation.value = rstring('RGB')

    channel_1 = ChannelI(1)
    channel_1.alpha = rint(255)
    channel_1.blue = rint(255)
    channel_1.green = rint(255)
    channel_1.red = rint(255)
    channel_1.lookupTable = rstring('rainbow')
    logical_channel_1 = LogicalChannelI(1)
    logical_channel_1.emissionWave = LengthI(509.0, UnitsLength.NANOMETER)
    logical_channel_1.excitationWave = LengthI(488.0, UnitsLength.NANOMETER)
    logical_channel_1.fluor = rstring('GFP')
    logical_channel_1.name = rstring('GFP/488')
    logical_channel_1.ndFilter = rdouble(1.0)
    logical_channel_1.pinHoleSize = LengthI(1.0, UnitsLength.NANOMETER)
    logical_channel_1.pockelCellSetting = rint(0)
    logical_channel_1.samplesPerPixel = rint(2)
    logical_channel_1.contrastMethod = contrast_method
    logical_channel_1.illumination = illumination
    logical_channel_1.mode = acquisition_mode
    logical_channel_1.photometricInterpretation = photometric_interpretation
    channel_1.logicalChannel = logical_channel_1

    channel_2 = ChannelI(2)
    channel_2.alpha = rint(255)
    channel_2.blue = rint(255)
    channel_2.green = rint(0)
    channel_2.red = rint(255)
    channel_2.lookupTable = rstring('rainbow')
    logical_channel_2 = LogicalChannelI(2)
    logical_channel_2.emissionWave = LengthI(470.0, UnitsLength.NANOMETER)
    logical_channel_2.excitationWave = LengthI(405.0, UnitsLength.NANOMETER)
    logical_channel_2.fluor = rstring('DAPI')
    logical_channel_2.name = rstring('DAPI/405')
    logical_channel_2.ndFilter = rdouble(1.0)
    logical_channel_2.pinHoleSize = LengthI(2.0, UnitsLength.NANOMETER)
    logical_channel_2.pockelCellSetting = rint(0)
    logical_channel_2.samplesPerPixel = rint(2)
    logical_channel_2.contrastMethod = contrast_method
    logical_channel_2.illumination = illumination
    logical_channel_2.mode = acquisition_mode
    logical_channel_2.photometricInterpretation = photometric_interpretation
    channel_2.logicalChannel = logical_channel_2

    pixels.addChannel(channel_1)
    pixels.addChannel(channel_2)
    return image