Merge pull request #53 from jimrybarski/42-feature-unittests

42 feature unittests
9 years ago · 9eb8a4b762
--- a/+ 1
+++ b/+ 1
@ -1,4 +1,4 @@
 FROM ubuntu
 FROM ubuntu:15.04
 MAINTAINER Jim Rybarski <jim@rybarski.com>

 RUN mkdir -p /var/nds2
@ -15,6 +15,3 @@ COPY . /opt/nd2reader
 WORKDIR /opt/nd2reader
 RUN python setup.py install
 RUN python3 setup.py install
 WORKDIR /var/nd2s

 CMD /usr/bin/python3.4
--- a/+ 4
+++ b/+ 4
@ -8,3 +8,7 @@ py2shell:

 py3shell:
 	docker run --rm -v ~/Documents/nd2s:/var/nd2s -it jimrybarski/nd2reader python3.4

 test:	build
 	docker run --rm -it jimrybarski/nd2reader python3.4 /opt/nd2reader/tests.py

--- a/nd2reader/init.py
+++ b/nd2reader/init.py
@ -16,7 +16,7 @@ class Nd2(Nd2Parser):

    def __repr__(self):
        return "\n".join(["<ND2 %s>" % self._filename,
                          "Created: %s" % self._absolute_start.strftime("%Y-%m-%d %H:%M:%S"),
                          "Created: %s" % self.absolute_start.strftime("%Y-%m-%d %H:%M:%S"),
                          "Image size: %sx%s (HxW)" % (self.height, self.width),
                          "Image cycles: %s" % len(self.time_indexes),
                          "Channels: %s" % ", ".join(["'%s'" % str(channel) for channel in self.channels]),
@ -32,7 +32,7 @@ class Nd2(Nd2Parser):
        :rtype: int

        """
        return self._image_count * self._channel_count
        return self._total_images_per_channel * self._channel_count

    def __getitem__(self, item):
        """
@ -123,16 +123,6 @@ class Nd2(Nd2Parser):
        """
        return self.metadata[six.b('ImageAttributes')][six.b('SLxImageAttributes')][six.b('uiWidth')]

    def _calculate_field_of_view(self, frame_number):
        images_per_cycle = len(self.z_levels) * len(self.channels)
        return int((frame_number - (frame_number % images_per_cycle)) / images_per_cycle) % len(self.fields_of_view)

    def _calculate_channel(self, frame_number):
        return self._channels[frame_number % len(self.channels)]

    def _calculate_z_level(self, frame_number):
        return self.z_levels[int(((frame_number - (frame_number % len(self.channels))) / len(self.channels)) % len(self.z_levels))]

    def get_image(self, time_index, field_of_view, channel_name, z_level):
        """
        Returns an Image if data exists for the given parameters, otherwise returns None. In general, you should avoid
--- a/nd2reader/parser.py
+++ b/nd2reader/parser.py
@ -19,6 +19,7 @@ class Nd2Parser(object):
    CHUNK_MAP_END = six.b("ND2 CHUNK MAP SIGNATURE 0000001!")

    def __init__(self, filename):
        self._absolute_start = None
        self._filename = filename
        self._fh = None
        self._channels = None
@ -34,6 +35,109 @@ class Nd2Parser(object):
        self._parse_metadata()
        self._z_levels = None

    @property
    def absolute_start(self):
        """
        The date and time when acquisition began.

        :rtype: datetime.datetime()

        """
        if self._absolute_start is None:
            for line in self.metadata[six.b('ImageTextInfo')][six.b('SLxImageTextInfo')].values():
                line = line.decode("utf8")
                absolute_start_12 = None
                absolute_start_24 = None
                # ND2s seem to randomly switch between 12- and 24-hour representations.
                try:
                    absolute_start_24 = datetime.strptime(line, "%m/%d/%Y  %H:%M:%S")
                except (TypeError, ValueError):
                    pass
                try:
                    absolute_start_12 = datetime.strptime(line, "%m/%d/%Y  %I:%M:%S %p")
                except (TypeError, ValueError):
                    pass
                if not absolute_start_12 and not absolute_start_24:
                    continue
                return absolute_start_12 if absolute_start_12 else absolute_start_24
            raise ValueError("This ND2 has no recorded start time. This is probably a bug.")
        return self._absolute_start

    @property
    def channels(self):
        """
        These are labels created by the NIS Elements user. Typically they may a short description of the filter cube
        used (e.g. "bright field", "GFP", etc.)

        :rtype: str

        """
        if not self._channels:
            self._channels = []
            metadata = self.metadata[six.b('ImageMetadataSeq')][six.b('SLxPictureMetadata')][six.b('sPicturePlanes')]
            try:
                validity = self.metadata[six.b('ImageMetadata')][six.b('SLxExperiment')][six.b('ppNextLevelEx')][six.b('')][0][six.b('ppNextLevelEx')][six.b('')][0][six.b('pItemValid')]
            except KeyError:
                # If none of the channels have been deleted, there is no validity list, so we just make one
                validity = [True for _ in metadata]
            # Channel information is contained in dictionaries with the keys a0, a1...an where the number
            # indicates the order in which the channel is stored. So by sorting the dicts alphabetically
            # we get the correct order.
            for (label, chan), valid in zip(sorted(metadata[six.b('sPlaneNew')].items()), validity):
                if not valid:
                    continue
                self._channels.append(chan[six.b('sDescription')].decode("utf8"))
        return self._channels

    @property
    def fields_of_view(self):
        """
        The metadata contains information about fields of view, but it contains it even if some fields
        of view were cropped. We can't find anything that states which fields of view are actually
        in the image data, so we have to calculate it. There probably is something somewhere, since
        NIS Elements can figure it out, but we haven't found it yet.

        :rtype: int

        """
        if self._fields_of_view is None:
            self._fields_of_view = self._parse_dimension_text(r""".*?XY\((\d+)\).*?""")
        return self._fields_of_view

    @property
    def time_indexes(self):
        """
        The number of cycles.

        :rtype:     int

        """
        if self._time_indexes is None:
            self._time_indexes = self._parse_dimension_text(r""".*?T'\((\d+)\).*?""")
        return self._time_indexes

    @property
    def z_levels(self):
        """
        The different levels in the Z-plane. Just a sequence from 0 to n.

        :rtype: int

        """
        if self._z_levels is None:
            self._z_levels = self._parse_dimension_text(r""".*?Z\((\d+)\).*?""")
        return self._z_levels

    def _calculate_field_of_view(self, frame_number):
        images_per_cycle = len(self.z_levels) * len(self.channels)
        return int((frame_number - (frame_number % images_per_cycle)) / images_per_cycle) % len(self.fields_of_view)

    def _calculate_channel(self, frame_number):
        return self.channels[frame_number % len(self.channels)]

    def _calculate_z_level(self, frame_number):
        return self.z_levels[int(((frame_number - (frame_number % len(self.channels))) / len(self.channels)) % len(self.z_levels))]

    @property
    def _file_handle(self):
        if self._fh is None:
@ -97,32 +201,6 @@ class Nd2Parser(object):
                raise ValueError("Could not parse metadata dimensions!")
        return self._dimension_text

    @property
    def channels(self):
        """
        These are labels created by the NIS Elements user. Typically they may a short description of the filter cube
        used (e.g. "bright field", "GFP", etc.)

        :rtype: str

        """
        if not self._channels:
            self._channels = []
            metadata = self.metadata[six.b('ImageMetadataSeq')][six.b('SLxPictureMetadata')][six.b('sPicturePlanes')]
            try:
                validity = self.metadata[six.b('ImageMetadata')][six.b('SLxExperiment')][six.b('ppNextLevelEx')][six.b('')][0][six.b('ppNextLevelEx')][six.b('')][0][six.b('pItemValid')]
            except KeyError:
                # If none of the channels have been deleted, there is no validity list, so we just make one
                validity = [True for _ in metadata]
            # Channel information is contained in dictionaries with the keys a0, a1...an where the number
            # indicates the order in which the channel is stored. So by sorting the dicts alphabetically
            # we get the correct order.
            for (label, chan), valid in zip(sorted(metadata[six.b('sPlaneNew')].items()), validity):
                if not valid:
                    continue
                self._channels.append(chan[six.b('sDescription')].decode("utf8"))
        return self._channels

    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.
@ -150,32 +228,6 @@ class Nd2Parser(object):
            channel_offset[channel] = n
        return channel_offset

    @property
    def _absolute_start(self):
        """
        The date and time when acquisition began.

        :rtype: datetime.datetime()

        """
        for line in self.metadata[six.b('ImageTextInfo')][six.b('SLxImageTextInfo')].values():
            line = line.decode("utf8")
            absolute_start_12 = None
            absolute_start_24 = None
            # ND2s seem to randomly switch between 12- and 24-hour representations.
            try:
                absolute_start_24 = datetime.strptime(line, "%m/%d/%Y  %H:%M:%S")
            except (TypeError, ValueError):
                pass
            try:
                absolute_start_12 = datetime.strptime(line, "%m/%d/%Y  %I:%M:%S %p")
            except (TypeError, ValueError):
                pass
            if not absolute_start_12 and not absolute_start_24:
                continue
            return absolute_start_12 if absolute_start_12 else absolute_start_24
        raise ValueError("This ND2 has no recorded start time. This is probably a bug.")

    def _parse_dimension_text(self, pattern):
        try:
            count = int(re.match(pattern, self._dimensions).group(1))
@ -188,48 +240,9 @@ class Nd2Parser(object):
            return list(range(count))

    @property
    def fields_of_view(self):
        """
        The metadata contains information about fields of view, but it contains it even if some fields
        of view were cropped. We can't find anything that states which fields of view are actually
        in the image data, so we have to calculate it. There probably is something somewhere, since
        NIS Elements can figure it out, but we haven't found it yet.

        :rtype: int

        """
        if self._fields_of_view is None:
            self._fields_of_view = self._parse_dimension_text(r""".*?XY\((\d+)\).*?""")
        return self._fields_of_view

    @property
    def time_indexes(self):
        """
        The number of cycles.

        :rtype:     int

        """
        if self._time_indexes is None:
            self._time_indexes = self._parse_dimension_text(r""".*?T'\((\d+)\).*?""")
        return self._time_indexes

    @property
    def z_levels(self):
        """
        The different levels in the Z-plane. Just a sequence from 0 to n.

        :rtype: int

        """
        if self._z_levels is None:
            self._z_levels = self._parse_dimension_text(r""".*?Z\((\d+)\).*?""")
        return self._z_levels

    @property
    def _image_count(self):
    def _total_images_per_channel(self):
        """
        The total number of images in the ND2. Warning: this may be inaccurate as it includes "gap" images.
        The total number of images per channel. Warning: this may be inaccurate as it includes "gap" images.

        :rtype: int

--- a/tests.py
+++ b/tests.py
@ -0,0 +1,5 @@
 import unittest
 loader = unittest.TestLoader()
 tests = loader.discover('tests', pattern='*.py', top_level_dir='.')
 testRunner = unittest.TextTestRunner()
 testRunner.run(tests)
--- a/tests/init.py
+++ b/tests/init.py
@ -0,0 +1,183 @@
 from nd2reader.parser import Nd2Parser
 import unittest


 class MockNd2Parser(object):
    def __init__(self, channels, fields_of_view, z_levels):
        self.channels = channels
        self.fields_of_view = fields_of_view
        self.z_levels = z_levels


 class TestNd2Parser(unittest.TestCase):
    def test_calculate_field_of_view_simple(self):
        """ With a single field of view, the field of view should always be the same number (0). """
        nd2 = MockNd2Parser([''], [0], [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_field_of_view(nd2, frame_number)
            self.assertEqual(result, 0)

    def test_calculate_field_of_view_two_channels(self):
        nd2 = MockNd2Parser(['', 'GFP'], [0], [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_field_of_view(nd2, frame_number)
            self.assertEqual(result, 0)

    def test_calculate_field_of_view_three_channels(self):
        nd2 = MockNd2Parser(['', 'GFP', 'dsRed'], [0], [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_field_of_view(nd2, frame_number)
            self.assertEqual(result, 0)

    def test_calculate_field_of_view_two_fovs(self):
        nd2 = MockNd2Parser([''], [0, 1], [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_field_of_view(nd2, frame_number)
            self.assertEqual(result, frame_number % 2)

    def test_calculate_field_of_view_two_fovs_two_zlevels(self):
        nd2 = MockNd2Parser([''], [0, 1], [0, 1])
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 0), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 1), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 2), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 3), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 4), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 5), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 6), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 7), 1)

    def test_calculate_field_of_view_two_everything(self):
        nd2 = MockNd2Parser(['', 'GFP'], [0, 1], [0, 1])
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 0), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 1), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 2), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 3), 0)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 4), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 5), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 6), 1)
        self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, 7), 1)

    def test_calculate_field_of_view_7c2f2z(self):
        nd2 = MockNd2Parser(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], [0, 1], [0, 1])
        for i in range(14):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 0)
        for i in range(14, 28):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 1)
        for i in range(28, 42):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 0)
        for i in range(42, 56):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 1)
        for i in range(56, 70):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 0)
        for i in range(70, 84):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 1)

    def test_calculate_field_of_view_2c3f5z(self):
        """ All prime numbers to elucidate any errors that won't show up when numbers are multiples of each other """
        nd2 = MockNd2Parser(['', 'GFP'], [0, 1, 2], [0, 1, 2, 3, 4])
        for i in range(10):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 0)
        for i in range(10, 20):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 1)
        for i in range(20, 30):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 2)
        for i in range(30, 40):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 0)
        for i in range(40, 50):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 1)
        for i in range(50, 60):
            self.assertEqual(Nd2Parser._calculate_field_of_view(nd2, i), 2)

    def test_calculate_channel_simple(self):
        nd2 = MockNd2Parser(['GFP'], [0], [0])
        for i in range(1000):
            self.assertEqual(Nd2Parser._calculate_channel(nd2, i), 'GFP')

    def test_calculate_channel(self):
        nd2 = MockNd2Parser(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], [0], [0])
        for i in range(1000):
            for n, channel in enumerate(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], start=i*7):
                self.assertEqual(Nd2Parser._calculate_channel(nd2, n), channel)

    def test_calculate_channel_7c2fov1z(self):
        nd2 = MockNd2Parser(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], [0, 1], [0])
        for i in range(1000):
            for n, channel in enumerate(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], start=i*7):
                self.assertEqual(Nd2Parser._calculate_channel(nd2, n), channel)

    def test_calculate_channel_ludicrous_values(self):
        nd2 = MockNd2Parser(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], list(range(31)), list(range(17)))
        for i in range(10000):
            for n, channel in enumerate(['', 'GFP', 'dsRed', 'dTomato', 'lulzBlue', 'jimbotronPurple', 'orange'], start=i*7):
                self.assertEqual(Nd2Parser._calculate_channel(nd2, n), channel)

    def test_calculate_z_level(self):
        nd2 = MockNd2Parser([''], [0], [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_z_level(nd2, frame_number)
            self.assertEqual(result, 0)

    def test_calculate_z_level_1c1f2z(self):
        nd2 = MockNd2Parser([''], [0], [0, 1])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_z_level(nd2, frame_number)
            self.assertEqual(result, frame_number % 2)

    def test_calculate_z_level_31c17f1z(self):
        nd2 = MockNd2Parser(list(range(31)), list(range(17)), [0])
        for frame_number in range(1000):
            result = Nd2Parser._calculate_z_level(nd2, frame_number)
            self.assertEqual(result, 0)

    def test_calculate_z_level_2c1f2z(self):
        nd2 = MockNd2Parser(['', 'GFP'], [0], [0, 1])
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 0), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 1), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 2), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 3), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 4), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 5), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 6), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 7), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 8), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 9), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 10), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 11), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 12), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 13), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 14), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 15), 1)

    def test_calculate_z_level_2c3f5z(self):
        nd2 = MockNd2Parser(['', 'GFP'], [0, 1, 2], [0, 1, 2, 3, 4])
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 0), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 1), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 2), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 3), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 4), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 5), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 6), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 7), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 8), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 9), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 10), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 11), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 12), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 13), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 14), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 15), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 16), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 17), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 18), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 19), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 20), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 21), 0)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 22), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 23), 1)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 24), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 25), 2)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 26), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 27), 3)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 28), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 29), 4)
        self.assertEqual(Nd2Parser._calculate_z_level(nd2, 30), 0)