zolfa
/
testtest


								# -*- coding: utf-8 -*-


								import array

								import numpy as np

								import struct

								import six

								from nd2reader.model.image import Image

								from nd2reader.common.v3 import read_chunk


								class V3Driver(object):

								    def __init__(self, metadata, label_map, file_handle):

								        self._metadata = metadata

								        self._label_map = label_map

								        self._file_handle = file_handle


								    def _calculate_field_of_view(self, frame_number):

								        images_per_cycle = len(self._metadata.z_levels) * len(self._metadata.channels)

								        return int((frame_number - (frame_number % images_per_cycle)) / images_per_cycle) % len(self._metadata.fields_of_view)


								    def _calculate_channel(self, frame_number):

								        return self._metadata.channels[frame_number % len(self._metadata.channels)]


								    def _calculate_z_level(self, frame_number):

								        return self._metadata.z_levels[int(((frame_number - (frame_number % len(self._metadata.channels))) / len(self._metadata.channels)) % len(self._metadata.z_levels))]


								    def _calculate_image_group_number(self, time_index, fov, z_level):

								        """

								        Images are grouped together if they share the same time index, field of view, and z-level.


								        :type time_index: int

								        :type fov: int

								        :type z_level: int


								        :rtype: int


								        """

								        return time_index * len(self._metadata.fields_of_view) * len(self._metadata.z_levels) + (fov * len(self._metadata.z_levels) + z_level)


								    def _calculate_frame_number(self, image_group_number, fov, z_level):

								        return (image_group_number - (fov * len(self._metadata.z_levels) + z_level)) / (len(self._metadata.fields_of_view) * len(self._metadata.z_levels))


								    def get_image(self, index):

								        channel_offset = index % len(self._metadata.channels)

								        fov = self._calculate_field_of_view(index)

								        channel = self._calculate_channel(index)

								        z_level = self._calculate_z_level(index)

								        image_group_number = int(index / len(self._metadata.channels))

								        frame_number = self._calculate_frame_number(image_group_number, fov, z_level)

								        timestamp, image = self._get_raw_image_data(image_group_number, channel_offset, self._metadata.height, self._metadata.width)

								        image.add_params(timestamp, frame_number, fov, channel, z_level)

								        return image


								    @property

								    def _channel_offset(self):

								        """

								        Image data is interleaved for each image set. That is, if there are four images in a set, the first image

								        will consist of pixels 1, 5, 9, etc, the second will be pixels 2, 6, 10, and so forth.


								        :rtype: dict


								        """

								        channel_offset = {}

								        for n, channel in enumerate(self._metadata.channels):

								            channel_offset[channel] = n

								        return channel_offset


								    def _get_raw_image_data(self, image_group_number, channel_offset, height, width):

								        """

								        Reads the raw bytes and the timestamp of an image.


								        :param image_group_number: groups are made of images with the same time index, field of view and z-level.

								        :type image_group_number: int

								        :param channel_offset: the offset in the array where the bytes for this image are found.

								        :type channel_offset: int


								        :return: (int, array.array()) or None


								        """

								        chunk = self._label_map[six.b("ImageDataSeq|%d!" % image_group_number)]

								        data = read_chunk(self._file_handle, chunk)

								        # All images in the same image group share the same timestamp! So if you have complicated image data,

								        # your timestamps may not be entirely accurate. Practically speaking though, they'll only be off by a few

								        # seconds unless you're doing something super weird.

								        timestamp = struct.unpack("d", data[:8])[0]

								        image_group_data = array.array("H", data)

								        image_data_start = 4 + channel_offset

								        # The images for the various channels are interleaved within the same array. For example, the second image

								        # of a four image group will be composed of bytes 2, 6, 10, etc. If you understand why someone would design

								        # a data structure that way, please send the author of this library a message.

								        image_data = np.reshape(image_group_data[image_data_start::len(self._metadata.channels)], (height, width))

								        # Skip images that are all zeros! This is important, since NIS Elements creates blank "gap" images if you

								        # don't have the same number of images each cycle. We discovered this because we only took GFP images every

								        # other cycle to reduce phototoxicity, but NIS Elements still allocated memory as if we were going to take

								        # them every cycle.

								        if np.any(image_data):

								            return timestamp, Image(image_data)

								        return None