Example #1
0
def testDelayLoadAndPostCloning(ext):
    # create test data on disk
    filepath = "/tmp/clpost." + ext
    sz = 1000
    b_ = n.IntBuffer(sz)
    b_[60] = 600
    assert (b_.clientSize() == sz)
    n.save(b_, filepath)

    # test1: Make sure that cloning a buffer doesn't force any data resident. Also make
    # sure that if either buffer forces data resident via a read, both buffers get the
    # same resident data.
    b = n.load(filepath)
    assert (b.clientSize() == 0)
    b2 = b.clone()
    assert (b.clientSize() == 0)
    assert (b2.clientSize() == 0)

    assert (b[60] == 600)  # will cause buffer to load into mem
    assert (b.clientSize() == sz)
    assert (b2.clientSize() == sz)
    assert (b.hasSharedStore(b2))

    # test2: Make sure that if a buffer's data is non-resident, and then it is cloned,
    # then the clone is accessed for writing, that the original buffer's data is NOT
    # made resident.
    c = n.load(filepath)
    assert (c.uniqueStore())
    assert (c.clientSize() == 0)

    c2 = c.clone()
    assert (c2.clientSize() == 0)
    c2[6] = 66  # will cause data to load for c2, but still not for c...!
    assert (c.clientSize() == 0)
    assert (c2.clientSize() == sz)
Example #2
0
def testDelayLoadAndPostCloning(ext):
    # create test data on disk
    filepath = "/tmp/clpost." + ext
    sz = 1000
    b_ = n.IntBuffer(sz)
    b_[60] = 600
    assert(b_.clientSize() == sz)
    n.save(b_, filepath)

    # test1: Make sure that cloning a buffer doesn't force any data resident. Also make
    # sure that if either buffer forces data resident via a read, both buffers get the
    # same resident data.
    b = n.load(filepath)
    assert(b.clientSize() == 0)
    b2 = b.clone()
    assert(b.clientSize() == 0)
    assert(b2.clientSize() == 0)

    assert(b[60] == 600) # will cause buffer to load into mem
    assert(b.clientSize() == sz)
    assert(b2.clientSize() == sz)
    assert(b.hasSharedStore(b2))

    # test2: Make sure that if a buffer's data is non-resident, and then it is cloned,
    # then the clone is accessed for writing, that the original buffer's data is NOT
    # made resident.
    c = n.load(filepath)
    assert(c.uniqueStore())
    assert(c.clientSize() == 0)

    c2 = c.clone()
    assert(c2.clientSize() == 0)
    c2[6] = 66 # will cause data to load for c2, but still not for c...!
    assert(c.clientSize() == 0)
    assert(c2.clientSize() == sz)
def build_node_tree(nap_file_name, map_file_name=None):
    """

    This function will return node.attr list from the map file

    :param nap_file_name: Filepath for reading napalm data

    :type nap_file_name: string

    :param map_file_name: Filepath for reading napalm channel data

    :type map_file_name: string

    :return: list for node.attribute

    :rtype: list

    """
    if not map_file_name:
        map_file_name = build_map_file_name(nap_file_name)
    get_node_list = nap_core.load(map_file_name)
    map_tbl_keys = get_node_list.keys()
    node_attribute_tree = []
    for each_key in map_tbl_keys:
        if each_key == "header":
            continue
        obj_tbl_keys = get_node_list[each_key].keys()
        for each_attr in obj_tbl_keys:
            if each_attr == "eye_val":
                continue
            else:
                nd_tree = "%s.%s" % (each_key, each_attr)
                node_attribute_tree.append(nd_tree)
    return node_attribute_tree
    def getChannel(self, nap_file_name, channel_number):
        """

        This function will return channel data based on the channel number

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :param channel_number: Channel number for getting data from the channel file.

        :type channel_number: int

        :return: Napalm Object

        :rtype: NapalmBuffer

        Example

            >>> import kip.kip_napalm_class as knc

            >>> kncw = knc.Napalm()

            >>> nap_tab = kncw.getChannel(nap_file_name,50)

        """
        if os.path.exists(nap_file_name):
            chan_table = nap_core.load(nap_file_name)
            get_channel_value = chan_table[channel_number].contents
            return get_channel_value
    def getAllChannles(self, nap_file_name):
        """

        This function will return all channel data from a channel file.

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :return: Napalm Object

        :rtype: NapalmBuffer

        Example

            >>> import kip.kip_napalm_class as knc

            >>> kncw = knc.Napalm()

            >>> nap_tab = kncw.getAllChannles(nap_file_name)

            >>> nap_tab["key_value"].contents

        """

        if os.path.exists(nap_file_name):
            chan_table = nap_core.load(nap_file_name)
            return (chan_table)
Example #6
0
def build_node_tree(nap_file_name, map_file_name=None):
    """

    This function will return node.attr list from the map file

    :param nap_file_name: Filepath for reading napalm data

    :type nap_file_name: string

    :param map_file_name: Filepath for reading napalm channel data

    :type map_file_name: string

    :return: list for node.attribute

    :rtype: list

    """
    if not map_file_name:
        map_file_name = build_map_file_name(nap_file_name)
    get_node_list = nap_core.load(map_file_name)
    map_tbl_keys = get_node_list.keys()
    node_attribute_tree = []
    for each_key in map_tbl_keys:
        if each_key == "header":
            continue
        obj_tbl_keys = get_node_list[each_key].keys()
        for each_attr in obj_tbl_keys:
            if each_attr == "eye_val":
                continue
            else:
                nd_tree = "%s.%s" % (each_key, each_attr)
                node_attribute_tree.append(nd_tree)
    return node_attribute_tree
    def getAllChannles(self, nap_file_name):
        """

        This function will return all channel data from a channel file.

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :return: Napalm Object

        :rtype: NapalmBuffer

        Example

            >>> import kip.kip_napalm_class as knc

            >>> kncw = knc.Napalm()

            >>> nap_tab = kncw.getAllChannles(nap_file_name)

            >>> nap_tab["key_value"].contents

        """

        if os.path.exists(nap_file_name):
            chan_table = nap_core.load(nap_file_name)
            return(chan_table)
    def getChannel(self, nap_file_name, channel_number):
        """

        This function will return channel data based on the channel number

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :param channel_number: Channel number for getting data from the channel file.

        :type channel_number: int

        :return: Napalm Object

        :rtype: NapalmBuffer

        Example

            >>> import kip.kip_napalm_class as knc

            >>> kncw = knc.Napalm()

            >>> nap_tab = kncw.getChannel(nap_file_name,50)

        """
        if os.path.exists(nap_file_name):
            chan_table = nap_core.load(nap_file_name)
            get_channel_value = chan_table[channel_number].contents
            return get_channel_value
Example #9
0
def testTableSerialize(ext):
    # create test data on disk
    filepath = "/tmp/tbl1." + ext
    t = createUberTable()
    n.save(t, filepath)

    for delayload in [True, False]:
        t2 = n.load(filepath, delayload)
        assert (n.areEqual(t, t2))
Example #10
0
def testTableSerialize(ext):
    # create test data on disk
    filepath = "/tmp/tbl1." + ext
    t = createUberTable()
    n.save(t, filepath)

    for delayload in [True,False]:
        t2 = n.load(filepath, delayload)
        assert(n.areEqual(t,t2))
Example #11
0
def testFile():

    # test1
    fail = False
    try:
        b = n.load("some_nonexistant_file.foo")
    except n.NapalmFileError:
        fail = True
    assert (fail)

    # test2
    f = open("/tmp/notnapalm.txt", "w")
    f.write("this is not a napalm file.")
    f.close()
    fail = False
    try:
        b = n.load("/tmp/notnapalm.txt")
    except n.NapalmSerializeError:
        fail = True
    assert (fail)
Example #12
0
def testFile():

    # test1
    fail = False
    try:
        b = n.load("some_nonexistant_file.foo")
    except n.NapalmFileError:
        fail = True
    assert(fail)

    # test2
    f = open("/tmp/notnapalm.txt", "w")
    f.write("this is not a napalm file.")
    f.close()
    fail = False
    try:
        b = n.load("/tmp/notnapalm.txt")
    except n.NapalmSerializeError:
        fail = True
    assert(fail)
Example #13
0
def testV3fBufSerialize(ext):
    # create test data on disk
    filepath = "/tmp/v3fbuf." + ext
    b = n.V3fBuffer(100)
    b[50] = p.V3f(3.3, 4.4, 5.5)
    n.save(b, filepath)

    b2 = n.load(filepath)
    assert(type(b) == type(b2))
    assert(len(b) == len(b2))
    vdiff = b[50] - b2[50]
    assert(vdiff.length() < 0.001)
Example #14
0
def testV3fBufSerialize(ext):
    # create test data on disk
    filepath = "/tmp/v3fbuf." + ext
    b = n.V3fBuffer(100)
    b[50] = p.V3f(3.3, 4.4, 5.5)
    n.save(b, filepath)

    b2 = n.load(filepath)
    assert (type(b) == type(b2))
    assert (len(b) == len(b2))
    vdiff = b[50] - b2[50]
    assert (vdiff.length() < 0.001)
Example #15
0
def header(map_file_name):
    """

    This function will return a dict of header details from map file

    :param map_file_name: Filepath of napalm channel data

    :type map_file_name: string

    :return: header details

    :rtype: dict

    """
    map_table = nap_core.load(map_file_name)
    map_header = map_table["header"]
    return map_header
def header(map_file_name):
    """

    This function will return a dict of header details from map file

    :param map_file_name: Filepath of napalm channel data

    :type map_file_name: string

    :return: header details

    :rtype: dict

    """
    map_table = nap_core.load(map_file_name)
    map_header = map_table["header"]
    return map_header
Example #17
0
def testSerializeBruteForce():
    fileprefix = "/tmp/tblbrute."
    t = createUberTable()

    # save
    files = []
    for ext in fileTypes:
        for compression in [0, 1, 2]:
            filepath = fileprefix + str(compression) + '.' + ext
            n.save(t, filepath, compression)
            files.append(filepath)

    # load
    for delayload in [True, False]:
        for f in files:
            t2 = n.load(f, delayload)
            assert (n.areEqual(t, t2))
    def read(self, filename):
        """

        This function will return napalm table data from napalm file.

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :return: Napalm Table Structure

        :rtype: ObjectTable

        """
        if filename:
            nap_table = nap_core.load(filename)
            return nap_table
    def read(self, filename):
        """

        This function will return napalm table data from napalm file.

        :param nap_file_name: Filepath to read napalm file.

        :type nap_file_name: string

        :return: Napalm Table Structure

        :rtype: ObjectTable

        """
        if filename:
            nap_table = nap_core.load(filename)
            return nap_table
Example #20
0
def testSerializeBruteForce():
    fileprefix = "/tmp/tblbrute."
    t = createUberTable()

    # save
    files = []
    for ext in fileTypes:
        for compression in [0,1,2]:
            filepath = fileprefix + str(compression) + '.' + ext
            n.save(t, filepath, compression)
            files.append(filepath)

    # load
    for delayload in [True,False]:
        for f in files:
            t2 = n.load(f, delayload)
            assert(n.areEqual(t,t2))
Example #21
0
def testDelayLoadAndPreCloning(ext):
    # create test data on disk
    filepath = "/tmp/clpre." + ext
    sz = 13
    t_ = n.ObjectTable()
    b_ = n.IntBuffer(sz)
    b2_ = b_.clone()
    t_[1] = b_
    t_[2] = b2_
    n.save(t_, filepath)

    # test1: Make sure that when buffers are loaded, their cloned relationships are kept intact
    t = n.load(filepath)
    assert(t.keys() == t_.keys())
    assert(t[1].hasSharedStore(t[2]))
    t[2][0] # force resident via zeroeth element read
    assert(t[1].clientSize() == sz)
    assert(t[1].hasSharedStore(t[2]))
Example #22
0
def testDelayLoadAndPreCloning(ext):
    # create test data on disk
    filepath = "/tmp/clpre." + ext
    sz = 13
    t_ = n.ObjectTable()
    b_ = n.IntBuffer(sz)
    b2_ = b_.clone()
    t_[1] = b_
    t_[2] = b2_
    n.save(t_, filepath)

    # test1: Make sure that when buffers are loaded, their cloned relationships are kept intact
    t = n.load(filepath)
    assert (t.keys() == t_.keys())
    assert (t[1].hasSharedStore(t[2]))
    t[2][0]  # force resident via zeroeth element read
    assert (t[1].clientSize() == sz)
    assert (t[1].hasSharedStore(t[2]))
Example #23
0
def testDelayLoad(ext):
    # create test data on disk
    filepath = "/tmp/dl1." + ext
    sz = 100
    t_ = n.ObjectTable()
    for i in range(10):
        t_[i] = n.IntBuffer(sz)
    n.save(t_, filepath)

    # test1: make sure a buffer's data isn't made resident until it's accessed
    t = n.load(filepath)
    expected_count = sz
    for i in t.iteritems():
        i[1][0]  # force resident via zeroeth element read
        count = 0
        for j in t.iteritems():
            count += j[1].clientSize()
        assert (count == expected_count)
        expected_count += sz
Example #24
0
def testDelayLoad(ext):
    # create test data on disk
    filepath = "/tmp/dl1." + ext
    sz = 100
    t_ = n.ObjectTable()
    for i in range(10):
        t_[i] = n.IntBuffer(sz)
    n.save(t_, filepath)

    # test1: make sure a buffer's data isn't made resident until it's accessed
    t = n.load(filepath)
    expected_count = sz
    for i in t.iteritems():
        i[1][0] # force resident via zeroeth element read
        count = 0
        for j in t.iteritems():
            count += j[1].clientSize()
        assert(count == expected_count)
        expected_count += sz
Example #25
0
def testIntBufSerialize(ext):
    # create test data on disk
    filepath = "/tmp/intbuf." + ext
    sz = 50
    b = n.IntBuffer(sz)
    b[5] = 5
    n.save(b, filepath)
    b2 = n.load(filepath)

    if ext in delayLoadableFileTypes:
        assert (b2.clientSize() == 0)
    else:
        assert (b2.clientSize() == sz)

    assert (type(b) == type(b2))
    assert (len(b) == len(b2))
    assert (b2[5] == b[5])

    if ext in delayLoadableFileTypes:
        assert (b2.clientSize() == sz)
Example #26
0
def testIntBufSerialize(ext):
    # create test data on disk
    filepath = "/tmp/intbuf." + ext
    sz = 50
    b = n.IntBuffer(sz)
    b[5] = 5
    n.save(b, filepath)
    b2 = n.load(filepath)

    if ext in delayLoadableFileTypes:
        assert(b2.clientSize() == 0)
    else:
        assert(b2.clientSize() == sz)

    assert(type(b) == type(b2))
    assert(len(b) == len(b2))
    assert(b2[5] == b[5])

    if ext in delayLoadableFileTypes:
        assert(b2.clientSize() == sz)
Example #27
0
    def read(self, nap_file_name = None, map_file_name = None, offset_value = 0):

        """

        This function will return the curve object based on the channel and map file and this
        function added for backward compatable module.

        :param nap_file_name: Filepath for reading napalm data

        :type nap_file_name: string

        :param map_file_name: Filepath for reading napalm channel data

        :type map_file_name: string

        :param offset_value: Animation key offset value

        :type offset_value: int

        .. warning::

            This function not suppose to call from any API call . use :func:`getCurves` for creating curves.


        .. seealso::

            * :func:`getCurves`

        .. versionchanged:: 0.0.5

            Fixed the map_file_name fixed.

        .. todo::

            More in-line comment should be added

        :return: Curve Object

        :rtype: list

        """

        curve_objects = []
        if nap_file_name:
            if not map_file_name:
                map_file_name = build_map_file_name(nap_file_name)
            if os.path.exists(map_file_name):
                map_table = nap_core.load(map_file_name)
                map_tbl_keys = map_table.keys()
                chan_table = nap_core.load(nap_file_name)
                for obj_cnt in  range(0, len(map_tbl_keys)):
                    kipCurveClassObject = ClassObject()
                    kipCurveObject = CurveClass()
                    if map_tbl_keys[obj_cnt] == "header":
                        continue
                    get_obj_table = map_table[map_tbl_keys[obj_cnt]]
                    obj_tbl_keys = get_obj_table.keys()
                    eye_value = get_obj_table["eye_val"]
                    for each_curv_cnt in range(0, len(obj_tbl_keys)):
                        attr_name = obj_tbl_keys[each_curv_cnt]
                        if attr_name == "eye_val":
                            continue
                        curve_dict = get_obj_table[obj_tbl_keys[each_curv_cnt]]
                        curve_type		= attr_name[:-1]
                        curve_attr		= attr_name
                        get_all_channels = napalm_func.getAllChannles(nap_file_name)
                        time_keys 		= get_all_channels[curve_dict["time"]].contents
                        key_value		= get_all_channels[curve_dict["key_value"]].contents
                        in_angle		= get_all_channels[curve_dict["in_angle"]].contents
                        out_angle		= get_all_channels[curve_dict["out_angle"]].contents
                        in_weight		= get_all_channels[curve_dict["in_weight"]].contents
                        out_weight		= get_all_channels[curve_dict["out_weight"]].contents
                        in_tan_type		= get_all_channels[curve_dict["in_tan_type"]].contents
                        out_tan_type	= get_all_channels[curve_dict["out_tan_type"]].contents
                        in_slope		= get_all_channels[curve_dict["in_slope"]].contents
                        out_slope		= get_all_channels[curve_dict["out_slope"]].contents
                        key = CurveKeyClass()
                        for time_fr in time_keys:
                            key_index = time_keys.index(time_fr)
                            key.time.append(time_keys[key_index]+offset_value)
                            key.value.append(key_value[key_index])
                            key.in_angle.append(in_angle[key_index])
                            key.out_angle.append(out_angle[key_index])
                            key.in_weight.append(in_weight[key_index])
                            key.out_weight.append(out_weight[key_index])
                            key.in_tan_type.append(in_tan_type[key_index])
                            key.out_tan_type.append(out_tan_type[key_index])
                            key.in_slope.append(in_slope[key_index])
                            key.out_slope.append(out_slope[key_index])

                        kipCurveObject.keys.append(key)
                        kipCurveObject.parm.append(curve_type)
                        kipCurveObject.parm_attr.append(curve_attr)

                    kipCurveClassObject.name = map_tbl_keys[obj_cnt]
                    kipCurveClassObject.type = eye_value
                    kipCurveClassObject.animation.append(kipCurveObject)
                    curve_objects.append(kipCurveClassObject.output())
                return curve_objects
            else:
                rodin_logger.error("%s is not exists in filesystem"%map_file_name)
    def read(self, nap_file_name=None, map_file_name=None, offset_value=0):
        """

        This function will return the curve object based on the channel and map file and this
        function added for backward compatable module.

        :param nap_file_name: Filepath for reading napalm data

        :type nap_file_name: string

        :param map_file_name: Filepath for reading napalm channel data

        :type map_file_name: string

        :param offset_value: Animation key offset value

        :type offset_value: int

        .. warning::

            This function not suppose to call from any API call . use :func:`getCurves` for creating curves.


        .. seealso::

            * :func:`getCurves`

        .. versionchanged:: 0.0.5

            Fixed the map_file_name fixed.

        .. todo::

            More in-line comment should be added

        :return: Curve Object

        :rtype: list

        """

        curve_objects = []
        if nap_file_name:
            if not map_file_name:
                map_file_name = build_map_file_name(nap_file_name)
            if os.path.exists(map_file_name):
                map_table = nap_core.load(map_file_name)
                map_tbl_keys = map_table.keys()
                chan_table = nap_core.load(nap_file_name)
                for obj_cnt in range(0, len(map_tbl_keys)):
                    kipCurveClassObject = ClassObject()
                    kipCurveObject = CurveClass()
                    if map_tbl_keys[obj_cnt] == "header":
                        continue
                    get_obj_table = map_table[map_tbl_keys[obj_cnt]]
                    obj_tbl_keys = get_obj_table.keys()
                    eye_value = get_obj_table["eye_val"]
                    for each_curv_cnt in range(0, len(obj_tbl_keys)):
                        attr_name = obj_tbl_keys[each_curv_cnt]
                        if attr_name == "eye_val":
                            continue
                        curve_dict = get_obj_table[obj_tbl_keys[each_curv_cnt]]
                        curve_type = attr_name[:-1]
                        curve_attr = attr_name
                        get_all_channels = napalm_func.getAllChannles(
                            nap_file_name)
                        time_keys = get_all_channels[
                            curve_dict["time"]].contents
                        key_value = get_all_channels[
                            curve_dict["key_value"]].contents
                        in_angle = get_all_channels[
                            curve_dict["in_angle"]].contents
                        out_angle = get_all_channels[
                            curve_dict["out_angle"]].contents
                        in_weight = get_all_channels[
                            curve_dict["in_weight"]].contents
                        out_weight = get_all_channels[
                            curve_dict["out_weight"]].contents
                        in_tan_type = get_all_channels[
                            curve_dict["in_tan_type"]].contents
                        out_tan_type = get_all_channels[
                            curve_dict["out_tan_type"]].contents
                        in_slope = get_all_channels[
                            curve_dict["in_slope"]].contents
                        out_slope = get_all_channels[
                            curve_dict["out_slope"]].contents
                        key = CurveKeyClass()
                        for time_fr in time_keys:
                            key_index = time_keys.index(time_fr)
                            key.time.append(time_keys[key_index] +
                                            offset_value)
                            key.value.append(key_value[key_index])
                            key.in_angle.append(in_angle[key_index])
                            key.out_angle.append(out_angle[key_index])
                            key.in_weight.append(in_weight[key_index])
                            key.out_weight.append(out_weight[key_index])
                            key.in_tan_type.append(in_tan_type[key_index])
                            key.out_tan_type.append(out_tan_type[key_index])
                            key.in_slope.append(in_slope[key_index])
                            key.out_slope.append(out_slope[key_index])

                        kipCurveObject.keys.append(key)
                        kipCurveObject.parm.append(curve_type)
                        kipCurveObject.parm_attr.append(curve_attr)

                    kipCurveClassObject.name = map_tbl_keys[obj_cnt]
                    kipCurveClassObject.type = eye_value
                    kipCurveClassObject.animation.append(kipCurveObject)
                    curve_objects.append(kipCurveClassObject.output())
                return curve_objects
            else:
                rodin_logger.error("%s is not exists in filesystem" %
                                   map_file_name)