test_datapipe.py

# Owner(s): ["module: dataloader"]

import copy
import itertools
import os
import os.path
import pickle
import random
import sys
import tempfile
import warnings
from functools import partial
from typing import (
    Any,
    Awaitable,
    Dict,
    Generic,
    Iterator,
    List,
    NamedTuple,
    Optional,
    Set,
    Tuple,
    Type,
    TypeVar,
    Union,
)
from unittest import skipIf

import numpy as np

import torch
import torch.utils.data.backward_compatibility
import torch.utils.data.datapipes as dp
import torch.utils.data.graph
import torch.utils.data.graph_settings
from torch.testing._internal.common_utils import TestCase, run_tests, suppress_warnings
from torch.utils.data import (
    DataLoader,
    DataChunk,
    IterDataPipe,
    MapDataPipe,
    RandomSampler,
    argument_validation,
    runtime_validation,
    runtime_validation_disabled,
)
from torch.utils.data.graph import traverse
from torch.utils.data.datapipes.utils.common import StreamWrapper
from torch.utils.data.datapipes.utils.decoder import (
    basichandlers as decoder_basichandlers,
)
from torch.utils.data.datapipes.dataframe import CaptureDataFrame
from torch.utils.data.datapipes.dataframe import dataframe_wrapper as df_wrapper


try:
    import dill
    # XXX: By default, dill writes the Pickler dispatch table to inject its
    # own logic there. This globally affects the behavior of the standard library
    # pickler for any user who transitively depends on this module!
    # Undo this extension to avoid altering the behavior of the pickler globally.
    dill.extend(use_dill=False)
    HAS_DILL = True
except ImportError:
    HAS_DILL = False
skipIfNoDill = skipIf(not HAS_DILL, "no dill")

try:
    import pandas  # type: ignore[import] # noqa: F401 F403
    HAS_PANDAS = True
except ImportError:
    HAS_PANDAS = False
skipIfNoDataFrames = skipIf(not HAS_PANDAS, "no dataframes (pandas)")

skipTyping = skipIf(True, "TODO: Fix typing bug")
T_co = TypeVar("T_co", covariant=True)


def create_temp_dir_and_files():
    # The temp dir and files within it will be released and deleted in tearDown().
    # Adding `noqa: P201` to avoid mypy's warning on not releasing the dir handle within this function.
    temp_dir = tempfile.TemporaryDirectory()  # noqa: P201
    temp_dir_path = temp_dir.name
    with tempfile.NamedTemporaryFile(dir=temp_dir_path, delete=False, suffix='.txt') as f:
        temp_file1_name = f.name
    with tempfile.NamedTemporaryFile(dir=temp_dir_path, delete=False, suffix='.byte') as f:
        temp_file2_name = f.name
    with tempfile.NamedTemporaryFile(dir=temp_dir_path, delete=False, suffix='.empty') as f:
        temp_file3_name = f.name

    with open(temp_file1_name, 'w') as f1:
        f1.write('0123456789abcdef')
    with open(temp_file2_name, 'wb') as f2:
        f2.write(b"0123456789abcdef")

    temp_sub_dir = tempfile.TemporaryDirectory(dir=temp_dir_path)  # noqa: P201
    temp_sub_dir_path = temp_sub_dir.name
    with tempfile.NamedTemporaryFile(dir=temp_sub_dir_path, delete=False, suffix='.txt') as f:
        temp_sub_file1_name = f.name
    with tempfile.NamedTemporaryFile(dir=temp_sub_dir_path, delete=False, suffix='.byte') as f:
        temp_sub_file2_name = f.name

    with open(temp_sub_file1_name, 'w') as f1:
        f1.write('0123456789abcdef')
    with open(temp_sub_file2_name, 'wb') as f2:
        f2.write(b"0123456789abcdef")

    return [(temp_dir, temp_file1_name, temp_file2_name, temp_file3_name),
            (temp_sub_dir, temp_sub_file1_name, temp_sub_file2_name)]


def reset_after_n_next_calls(datapipe: Union[IterDataPipe[T_co], MapDataPipe[T_co]],
                             n: int) -> Tuple[List[T_co], List[T_co]]:
    """
    Given a DataPipe and integer n, iterate the DataPipe for n elements and store the elements into a list
    Then, reset the DataPipe and return a tuple of two lists
        1. A list of elements yielded before the reset
        2. A list of all elements of the DataPipe after the reset
    """
    it = iter(datapipe)
    res_before_reset = []
    for _ in range(n):
        res_before_reset.append(next(it))
    return res_before_reset, list(datapipe)


def odd_or_even(x: int) -> int:
    return x % 2


class TestDataChunk(TestCase):
    def setUp(self):
        self.elements = list(range(10))
        random.shuffle(self.elements)
        self.chunk: DataChunk[int] = DataChunk(self.elements)

    def test_getitem(self):
        for i in range(10):
            self.assertEqual(self.elements[i], self.chunk[i])

    def test_iter(self):
        for ele, dc in zip(self.elements, iter(self.chunk)):
            self.assertEqual(ele, dc)

    def test_len(self):
        self.assertEqual(len(self.elements), len(self.chunk))

    def test_as_string(self):
        self.assertEqual(str(self.chunk), str(self.elements))

        batch = [self.elements] * 3
        chunks: List[DataChunk[int]] = [DataChunk(self.elements)] * 3
        self.assertEqual(str(batch), str(chunks))

    def test_sort(self):
        chunk: DataChunk[int] = DataChunk(self.elements)
        chunk.sort()
        self.assertTrue(isinstance(chunk, DataChunk))
        for i, d in enumerate(chunk):
            self.assertEqual(i, d)

    def test_reverse(self):
        chunk: DataChunk[int] = DataChunk(self.elements)
        chunk.reverse()
        self.assertTrue(isinstance(chunk, DataChunk))
        for i in range(10):
            self.assertEqual(chunk[i], self.elements[9 - i])

    def test_random_shuffle(self):
        elements = list(range(10))
        chunk: DataChunk[int] = DataChunk(elements)

        rng = random.Random(0)
        rng.shuffle(chunk)

        rng = random.Random(0)
        rng.shuffle(elements)

        self.assertEqual(chunk, elements)


class TestStreamWrapper(TestCase):
    class _FakeFD:
        def __init__(self, filepath):
            self.filepath = filepath
            self.opened = False
            self.closed = False

        def open(self):
            self.opened = True

        def read(self):
            if self.opened:
                return "".join(self)
            else:
                raise IOError("Cannot read from un-opened file descriptor")

        def __iter__(self):
            for i in range(5):
                yield str(i)

        def close(self):
            if self.opened:
                self.opened = False
                self.closed = True

        def __repr__(self):
            return "FakeFD"

    def test_dir(self):
        fd = TestStreamWrapper._FakeFD("")
        wrap_fd = StreamWrapper(fd)

        s = set(dir(wrap_fd))
        for api in ['open', 'read', 'close']:
            self.assertTrue(api in s)

    def test_api(self):
        fd = TestStreamWrapper._FakeFD("")
        wrap_fd = StreamWrapper(fd)

        self.assertFalse(fd.opened)
        self.assertFalse(fd.closed)
        with self.assertRaisesRegex(IOError, "Cannot read from"):
            wrap_fd.read()

        wrap_fd.open()
        self.assertTrue(fd.opened)
        self.assertEqual("01234", wrap_fd.read())

        del wrap_fd
        self.assertFalse(fd.opened)
        self.assertTrue(fd.closed)

    def test_pickle(self):
        f = tempfile.TemporaryFile()
        with self.assertRaises(TypeError) as ctx1:
            pickle.dumps(f)

        wrap_f = StreamWrapper(f)
        with self.assertRaises(TypeError) as ctx2:
            pickle.dumps(wrap_f)

        # Same exception when pickle
        self.assertEqual(str(ctx1.exception), str(ctx2.exception))

        fd = TestStreamWrapper._FakeFD("")
        wrap_fd = StreamWrapper(fd)
        _ = pickle.loads(pickle.dumps(wrap_fd))

    def test_repr(self):
        fd = TestStreamWrapper._FakeFD("")
        wrap_fd = StreamWrapper(fd)
        self.assertEqual(str(wrap_fd), "StreamWrapper<FakeFD>")

        f = tempfile.TemporaryFile()
        wrap_f = StreamWrapper(f)
        self.assertEqual(str(wrap_f), "StreamWrapper<" + str(f) + ">")


class TestIterableDataPipeBasic(TestCase):
    def setUp(self):
        ret = create_temp_dir_and_files()
        self.temp_dir = ret[0][0]
        self.temp_files = ret[0][1:]
        self.temp_sub_dir = ret[1][0]
        self.temp_sub_files = ret[1][1:]

    def tearDown(self):
        try:
            self.temp_sub_dir.cleanup()
            self.temp_dir.cleanup()
        except Exception as e:
            warnings.warn("TestIterableDatasetBasic was not able to cleanup temp dir due to {}".format(str(e)))

    def test_listdirfiles_iterable_datapipe(self):
        temp_dir = self.temp_dir.name
        datapipe = dp.iter.FileLister(temp_dir, '')

        count = 0
        for pathname in datapipe:
            count = count + 1
            self.assertTrue(pathname in self.temp_files)
        self.assertEqual(count, len(self.temp_files))

        count = 0
        datapipe = dp.iter.FileLister(temp_dir, '', recursive=True)
        for pathname in datapipe:
            count = count + 1
            self.assertTrue((pathname in self.temp_files) or (pathname in self.temp_sub_files))
        self.assertEqual(count, len(self.temp_files) + len(self.temp_sub_files))

        temp_files = self.temp_files
        datapipe = dp.iter.FileLister([temp_dir, *temp_files])
        count = 0
        for pathname in datapipe:
            count += 1
            self.assertTrue(pathname in self.temp_files)
        self.assertEqual(count, 2 * len(self.temp_files))

    def test_listdirfilesdeterministic_iterable_datapipe(self):
        temp_dir = self.temp_dir.name

        datapipe = dp.iter.FileLister(temp_dir, '')
        # The output order should be always the same.
        self.assertEqual(list(datapipe), list(datapipe))

        datapipe = dp.iter.FileLister(temp_dir, '', recursive=True)
        # The output order should be always the same.
        self.assertEqual(list(datapipe), list(datapipe))

    def test_readfilesfromdisk_iterable_datapipe(self):
        # test import datapipe class directly
        from torch.utils.data.datapipes.iter import (
            FileLister,
            FileOpener,
        )

        temp_dir = self.temp_dir.name
        datapipe1 = FileLister(temp_dir, '')
        datapipe2 = FileOpener(datapipe1, mode='b')

        count = 0
        for rec in datapipe2:
            count = count + 1
            self.assertTrue(rec[0] in self.temp_files)
            with open(rec[0], 'rb') as f:
                self.assertEqual(rec[1].read(), f.read())
                rec[1].close()
        self.assertEqual(count, len(self.temp_files))

    def test_routeddecoder_iterable_datapipe(self):
        temp_dir = self.temp_dir.name
        temp_pngfile_pathname = os.path.join(temp_dir, "test_png.png")
        png_data = np.array([[[1., 0., 0.], [1., 0., 0.]], [[1., 0., 0.], [1., 0., 0.]]], dtype=np.single)
        np.save(temp_pngfile_pathname, png_data)
        datapipe1 = dp.iter.FileLister(temp_dir, ['*.png', '*.txt'])
        datapipe2 = dp.iter.FileOpener(datapipe1, mode='b')

        def _png_decoder(extension, data):
            if extension != 'png':
                return None
            return np.load(data)

        def _helper(prior_dp, dp, channel_first=False):
            # Byte stream is not closed
            for inp in prior_dp:
                self.assertFalse(inp[1].closed)
            for inp, rec in zip(prior_dp, dp):
                ext = os.path.splitext(rec[0])[1]
                if ext == '.png':
                    expected = np.array([[[1., 0., 0.], [1., 0., 0.]], [[1., 0., 0.], [1., 0., 0.]]], dtype=np.single)
                    if channel_first:
                        expected = expected.transpose(2, 0, 1)
                    self.assertEqual(rec[1], expected)
                else:
                    with open(rec[0], 'rb') as f:
                        self.assertEqual(rec[1], f.read().decode('utf-8'))
                # Corresponding byte stream is closed by Decoder
                self.assertTrue(inp[1].closed)

        cached = list(datapipe2)
        datapipe3 = dp.iter.RoutedDecoder(cached, _png_decoder)
        datapipe3.add_handler(decoder_basichandlers)
        _helper(cached, datapipe3)

        cached = list(datapipe2)
        datapipe4 = dp.iter.RoutedDecoder(cached, decoder_basichandlers)
        datapipe4.add_handler(_png_decoder)
        _helper(cached, datapipe4, channel_first=True)

    def test_groupby_iterable_datapipe(self):
        file_list = ["a.png", "b.png", "c.json", "a.json", "c.png", "b.json", "d.png",
                     "d.json", "e.png", "f.json", "g.png", "f.png", "g.json", "e.json",
                     "h.txt", "h.json"]

        import io

        datapipe1 = dp.iter.IterableWrapper([(filename, io.BytesIO(b'12345abcde')) for filename in file_list])

        def group_fn(data):
            filepath, _ = data
            return os.path.basename(filepath).split(".")[0]

        datapipe2 = dp.iter.Grouper(datapipe1, group_key_fn=group_fn, group_size=2)

        def order_fn(data):
            data.sort(key=lambda f: f[0], reverse=True)
            return data

        datapipe3 = dp.iter.Mapper(datapipe2, fn=order_fn)  # type: ignore[var-annotated]

        expected_result = [
            ("a.png", "a.json"), ("c.png", "c.json"), ("b.png", "b.json"), ("d.png", "d.json"),
            ("f.png", "f.json"), ("g.png", "g.json"), ("e.png", "e.json"), ("h.txt", "h.json")]

        count = 0
        for rec, expected in zip(datapipe3, expected_result):
            count = count + 1
            self.assertEqual(os.path.basename(rec[0][0]), expected[0])
            self.assertEqual(os.path.basename(rec[1][0]), expected[1])
            for i in [0, 1]:
                self.assertEqual(rec[i][1].read(), b'12345abcde')
                rec[i][1].close()
        self.assertEqual(count, 8)

    def test_demux_mux_datapipe(self):
        numbers = NumbersDataset(10)
        n1, n2 = numbers.demux(2, lambda x: x % 2)
        self.assertEqual([0, 2, 4, 6, 8], list(n1))
        self.assertEqual([1, 3, 5, 7, 9], list(n2))

        # Functional Test: demux and mux works sequentially as expected
        numbers = NumbersDataset(10)
        n1, n2, n3 = numbers.demux(3, lambda x: x % 3)
        n = n1.mux(n2, n3)
        self.assertEqual(list(range(10)), list(n))

        # Functional Test: Uneven DataPipes
        source_numbers = list(range(0, 10)) + [10, 12]
        numbers_dp = dp.iter.IterableWrapper(source_numbers)
        n1, n2 = numbers_dp.demux(2, lambda x: x % 2)
        self.assertEqual([0, 2, 4, 6, 8, 10, 12], list(n1))
        self.assertEqual([1, 3, 5, 7, 9], list(n2))
        n = n1.mux(n2)
        self.assertEqual(source_numbers, list(n))

    @suppress_warnings  # Suppress warning for lambda fn
    def test_map_with_col_file_handle_datapipe(self):
        temp_dir = self.temp_dir.name
        datapipe1 = dp.iter.FileLister(temp_dir, '')
        datapipe2 = dp.iter.FileOpener(datapipe1)

        def _helper(datapipe):
            dp1 = datapipe.map(lambda x: x.read(), input_col=1)
            dp2 = datapipe.map(lambda x: (x[0], x[1].read()))
            self.assertEqual(list(dp1), list(dp2))

        # tuple
        _helper(datapipe2)
        # list
        datapipe3 = datapipe2.map(lambda x: list(x))
        _helper(datapipe3)


@skipIfNoDataFrames
class TestCaptureDataFrame(TestCase):
    def get_new_df(self):
        return df_wrapper.create_dataframe([[1, 2]], columns=['a', 'b'])

    def compare_capture_and_eager(self, operations):
        cdf = CaptureDataFrame()
        cdf = operations(cdf)
        df = self.get_new_df()
        cdf = cdf.apply_ops(df)

        df = self.get_new_df()
        df = operations(df)

        self.assertTrue(df.equals(cdf))

    def test_basic_capture(self):
        def operations(df):
            df['c'] = df.b + df['a'] * 7
            # somehow swallows pandas UserWarning when `df.c = df.b + df['a'] * 7`
            return df
        self.compare_capture_and_eager(operations)


class TestDataFramesPipes(TestCase):
    """
        Most of test will fail if pandas instaled, but no dill available.
        Need to rework them to avoid multiple skips.
    """

    def _get_datapipe(self, range=10, dataframe_size=7):
        return NumbersDataset(range) \
            .map(lambda i: (i, i % 3))

    def _get_dataframes_pipe(self, range=10, dataframe_size=7):
        return NumbersDataset(range) \
            .map(lambda i: (i, i % 3)) \
            ._to_dataframes_pipe(
                columns=['i', 'j'],
                dataframe_size=dataframe_size)

    @skipIfNoDataFrames
    @skipIfNoDill  # TODO(VitalyFedyunin): Decouple tests from dill by avoiding lambdas in map
    def test_capture(self):
        dp_numbers = self._get_datapipe().map(lambda x: (x[0], x[1], x[1] + 3 * x[0]))
        df_numbers = self._get_dataframes_pipe()
        df_numbers['k'] = df_numbers['j'] + df_numbers.i * 3
        self.assertEqual(list(dp_numbers), list(df_numbers))

    @skipIfNoDataFrames
    @skipIfNoDill
    def test_shuffle(self):
        #  With non-zero (but extremely low) probability (when shuffle do nothing),
        #  this test fails, so feel free to restart
        df_numbers = self._get_dataframes_pipe(range=1000).shuffle()
        dp_numbers = self._get_datapipe(range=1000)
        df_result = [tuple(item) for item in df_numbers]
        self.assertNotEqual(list(dp_numbers), df_result)
        self.assertEqual(list(dp_numbers), sorted(df_result))

    @skipIfNoDataFrames
    @skipIfNoDill
    def test_batch(self):
        df_numbers = self._get_dataframes_pipe(range=100).batch(8)
        df_numbers_list = list(df_numbers)
        last_batch = df_numbers_list[-1]
        self.assertEqual(4, len(last_batch))
        unpacked_batch = [tuple(row) for row in last_batch]
        self.assertEqual([(96, 0), (97, 1), (98, 2), (99, 0)], unpacked_batch)

    @skipIfNoDataFrames
    @skipIfNoDill
    def test_unbatch(self):
        df_numbers = self._get_dataframes_pipe(range=100).batch(8).batch(3)
        dp_numbers = self._get_datapipe(range=100)
        self.assertEqual(list(dp_numbers), list(df_numbers.unbatch(2)))

    @skipIfNoDataFrames
    @skipIfNoDill
    def test_filter(self):
        df_numbers = self._get_dataframes_pipe(range=10).filter(lambda x: x.i > 5)
        self.assertEqual([(6, 0), (7, 1), (8, 2), (9, 0)], list(df_numbers))


class IDP_NoLen(IterDataPipe):
    def __init__(self, input_dp):
        super().__init__()
        self.input_dp = input_dp

    # Prevent in-place modification
    def __iter__(self):
        input_dp = self.input_dp if isinstance(self.input_dp, IterDataPipe) else copy.deepcopy(self.input_dp)
        for i in input_dp:
            yield i


def _fake_fn(data):
    return data


def _fake_add(constant, data):
    return constant + data


def _fake_filter_fn(data):
    return data >= 5


def _fake_filter_fn_constant(constant, data):
    return data >= constant


def _worker_init_fn(worker_id):
    random.seed(123)


class TestFunctionalIterDataPipe(TestCase):

    def _serialization_test_helper(self, datapipe):
        serialized_dp = pickle.dumps(datapipe)
        deserialized_dp = pickle.loads(serialized_dp)
        try:
            self.assertEqual(list(datapipe), list(deserialized_dp))
        except AssertionError as e:
            print(f"{datapipe} is failing.")
            raise e

    def _serialization_test_for_single_dp(self, dp):
        # 1. Testing for serialization before any iteration starts
        self._serialization_test_helper(dp)
        # 2. Testing for serialization after DataPipe is partially read
        it = iter(dp)
        _ = next(it)
        self._serialization_test_helper(dp)
        # 3. Testing for serialization after DataPipe is fully read
        _ = list(it)
        self._serialization_test_helper(dp)

    def _serialization_test_for_dp_with_children(self, dp1, dp2):
        # 1. Testing for serialization before any iteration starts
        self._serialization_test_helper(dp1)
        self._serialization_test_helper(dp2)
        # 2. Testing for serialization after DataPipe is partially read
        it1, it2 = iter(dp1), iter(dp2)
        _, _ = next(it1), next(it2)
        self._serialization_test_helper(dp1)
        self._serialization_test_helper(dp2)
        # 2.5. Testing for serialization after one child DataPipe is fully read
        #      (Only for DataPipes with children DataPipes)
        _ = list(it1)  # fully read one child
        self._serialization_test_helper(dp1)
        self._serialization_test_helper(dp2)
        # 3. Testing for serialization after DataPipe is fully read
        _ = list(it2)  # fully read the other child
        self._serialization_test_helper(dp1)
        self._serialization_test_helper(dp2)

    def test_serializable(self):
        picklable_datapipes: List = [
            (dp.iter.Batcher, None, (3, True,), {}),
            (dp.iter.Collator, None, (_fake_fn,), {}),
            (dp.iter.Concater, None, (dp.iter.IterableWrapper(range(5)),), {}),
            (dp.iter.Demultiplexer, None, (2, _fake_filter_fn), {}),
            (dp.iter.FileLister, ".", (), {}),
            (dp.iter.FileOpener, None, (), {}),
            (dp.iter.Filter, None, (_fake_filter_fn,), {}),
            (dp.iter.Filter, None, (partial(_fake_filter_fn_constant, 5),), {}),
            (dp.iter.Forker, None, (2,), {}),
            (dp.iter.Grouper, None, (_fake_filter_fn,), {"group_size": 2}),
            (dp.iter.IterableWrapper, range(10), (), {}),
            (dp.iter.Mapper, None, (_fake_fn, ), {}),
            (dp.iter.Mapper, None, (partial(_fake_add, 1), ), {}),
            (dp.iter.Multiplexer, None, (dp.iter.IterableWrapper(range(10)),), {}),
            (dp.iter.Sampler, None, (), {}),
            (dp.iter.Shuffler, dp.iter.IterableWrapper([0] * 10), (), {}),
            (dp.iter.StreamReader, None, (), {}),
            (dp.iter.UnBatcher, None, (0,), {}),
            (dp.iter.Zipper, None, (dp.iter.IterableWrapper(range(10)),), {}),
        ]
        # Skipping comparison for these DataPipes
        dp_skip_comparison = {dp.iter.FileOpener, dp.iter.StreamReader}
        # These DataPipes produce multiple DataPipes as outputs and those should be compared
        dp_compare_children = {dp.iter.Demultiplexer, dp.iter.Forker}

        for dpipe, custom_input, dp_args, dp_kwargs in picklable_datapipes:
            if custom_input is None:
                custom_input = dp.iter.IterableWrapper(range(10))
            if dpipe in dp_skip_comparison:  # Merely make sure they are picklable and loadable (no value comparison)
                datapipe = dpipe(custom_input, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                serialized_dp = pickle.dumps(datapipe)
                _ = pickle.loads(serialized_dp)
            elif dpipe in dp_compare_children:  # DataPipes that have children
                dp1, dp2 = dpipe(custom_input, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                self._serialization_test_for_dp_with_children(dp1, dp2)
            else:  # Single DataPipe that requires comparison
                datapipe = dpipe(custom_input, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                self._serialization_test_for_single_dp(datapipe)

    def test_serializable_with_dill(self):
        """Only for DataPipes that take in a function as argument"""
        input_dp = dp.iter.IterableWrapper(range(10))
        unpicklable_datapipes: List[Tuple[Type[IterDataPipe], Tuple, Dict[str, Any]]] = [
            (dp.iter.Collator, (lambda x: x,), {}),
            (dp.iter.Demultiplexer, (2, lambda x: x % 2,), {}),
            (dp.iter.Filter, (lambda x: x >= 5,), {}),
            (dp.iter.Grouper, (lambda x: x >= 5,), {}),
            (dp.iter.Mapper, (lambda x: x, ), {}),
        ]
        dp_compare_children = {dp.iter.Demultiplexer}
        if HAS_DILL:
            for dpipe, dp_args, dp_kwargs in unpicklable_datapipes:
                if dpipe in dp_compare_children:
                    dp1, dp2 = dpipe(input_dp, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                    self._serialization_test_for_dp_with_children(dp1, dp2)
                else:
                    datapipe = dpipe(input_dp, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                    self._serialization_test_for_single_dp(datapipe)
        else:
            for dpipe, dp_args, dp_kwargs in unpicklable_datapipes:
                with warnings.catch_warnings(record=True) as wa:
                    datapipe = dpipe(input_dp, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                    self.assertEqual(len(wa), 1)
                    self.assertRegex(str(wa[0].message), r"^Lambda function is not supported for pickle")
                    with self.assertRaises(AttributeError):
                        p = pickle.dumps(datapipe)

    def test_iterable_wrapper_datapipe(self):

        input_ls = list(range(10))
        input_dp = dp.iter.IterableWrapper(input_ls)

        # Functional Test: values are unchanged and in the same order
        self.assertEqual(input_ls, list(input_dp))

        # Functional Test: deep copy by default when an iterator is initialized (first element is read)
        it = iter(input_dp)
        self.assertEqual(0, next(it))  # The deep copy only happens when the first element is read
        input_ls.append(50)
        self.assertEqual(list(range(1, 10)), list(it))

        # Functional Test: shallow copy
        input_ls2 = [1, 2, 3]
        input_dp_shallow = dp.iter.IterableWrapper(input_ls2, deepcopy=False)
        input_ls2.append(10)
        self.assertEqual([1, 2, 3, 10], list(input_dp_shallow))

        # Reset Test: reset the DataPipe
        input_ls = list(range(10))
        input_dp = dp.iter.IterableWrapper(input_ls)
        n_elements_before_reset = 5
        res_before_reset, res_after_reset = reset_after_n_next_calls(input_dp, n_elements_before_reset)
        self.assertEqual(input_ls[:n_elements_before_reset], res_before_reset)
        self.assertEqual(input_ls, res_after_reset)

        # __len__ Test: inherits length from sequence
        self.assertEqual(len(input_ls), len(input_dp))

    def test_concat_iterdatapipe(self):
        input_dp1 = dp.iter.IterableWrapper(range(10))
        input_dp2 = dp.iter.IterableWrapper(range(5))

        # Functional Test: Raises exception for empty input
        with self.assertRaisesRegex(ValueError, r"Expected at least one DataPipe"):
            dp.iter.Concater()

        # Functional Test: Raises exception for non-IterDataPipe input
        with self.assertRaisesRegex(TypeError, r"Expected all inputs to be `IterDataPipe`"):
            dp.iter.Concater(input_dp1, ())  # type: ignore[arg-type]

        # Functional Test: Concatenate DataPipes as expected
        concat_dp = input_dp1.concat(input_dp2)
        self.assertEqual(len(concat_dp), 15)
        self.assertEqual(list(concat_dp), list(range(10)) + list(range(5)))

        # Reset Test: reset the DataPipe
        n_elements_before_reset = 5
        res_before_reset, res_after_reset = reset_after_n_next_calls(concat_dp, n_elements_before_reset)
        self.assertEqual(list(range(5)), res_before_reset)
        self.assertEqual(list(range(10)) + list(range(5)), res_after_reset)

        # __len__ Test: inherits length from source DataPipe
        input_dp_nl = IDP_NoLen(range(5))
        concat_dp = input_dp1.concat(input_dp_nl)
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(concat_dp)

        self.assertEqual(list(concat_dp), list(range(10)) + list(range(5)))

    def test_fork_iterdatapipe(self):
        input_dp = dp.iter.IterableWrapper(range(10))

        with self.assertRaises(ValueError):
            input_dp.fork(num_instances=0)

        dp0 = input_dp.fork(num_instances=1)
        self.assertEqual(dp0, input_dp)

        # Functional Test: making sure all child DataPipe shares the same reference
        dp1, dp2, dp3 = input_dp.fork(num_instances=3)
        self.assertTrue(all(n1 is n2 and n1 is n3 for n1, n2, n3 in zip(dp1, dp2, dp3)))

        # Functional Test: one child DataPipe yields all value at a time
        output1, output2, output3 = list(dp1), list(dp2), list(dp3)
        self.assertEqual(list(range(10)), output1)
        self.assertEqual(list(range(10)), output2)
        self.assertEqual(list(range(10)), output3)

        # Functional Test: two child DataPipes yield value together
        dp1, dp2 = input_dp.fork(num_instances=2)
        output = []
        for n1, n2 in zip(dp1, dp2):
            output.append((n1, n2))
        self.assertEqual([(i, i) for i in range(10)], output)

        # Functional Test: one child DataPipe yields all value first, but buffer_size = 5 being too small
        dp1, dp2 = input_dp.fork(num_instances=2, buffer_size=5)
        it1 = iter(dp1)
        for _ in range(5):
            next(it1)
        with self.assertRaises(BufferError):
            next(it1)
        with self.assertRaises(BufferError):
            list(dp2)

        # Functional Test: one child DataPipe yields all value first with unlimited buffer
        with warnings.catch_warnings(record=True) as wa:
            dp1, dp2 = input_dp.fork(num_instances=2, buffer_size=-1)
            self.assertEqual(len(wa), 1)
            self.assertRegex(str(wa[0].message), r"Unlimited buffer size is set")
        l1, l2 = list(dp1), list(dp2)
        for d1, d2 in zip(l1, l2):
            self.assertEqual(d1, d2)

        # Functional Test: two child DataPipes yield value together with buffer size 1
        dp1, dp2 = input_dp.fork(num_instances=2, buffer_size=1)
        output = []
        for n1, n2 in zip(dp1, dp2):
            output.append((n1, n2))
        self.assertEqual([(i, i) for i in range(10)], output)

        # Functional Test: make sure logic related to slowest_ptr is working properly
        dp1, dp2, dp3 = input_dp.fork(num_instances=3)
        output1, output2, output3 = [], [], []
        for i, (n1, n2) in enumerate(zip(dp1, dp2)):
            output1.append(n1)
            output2.append(n2)
            if i == 4:  # yield all of dp3 when halfway through dp1, dp2
                output3 = list(dp3)
                break
        self.assertEqual(list(range(5)), output1)
        self.assertEqual(list(range(5)), output2)
        self.assertEqual(list(range(10)), output3)

        # Reset Test: DataPipe doesn't reset if this pipe hasn't been read
        dp1, dp2 = input_dp.fork(num_instances=2)
        i1, i2 = iter(dp1), iter(dp2)
        output2 = []
        for i, n2 in enumerate(i2):
            output2.append(n2)
            if i == 4:
                i1 = iter(dp1)  # Doesn't reset because i1 hasn't been read
        self.assertEqual(list(range(10)), output2)

        # Reset Test: DataPipe reset when some of it have been read
        dp1, dp2 = input_dp.fork(num_instances=2)
        i1, i2 = iter(dp1), iter(dp2)
        output1, output2 = [], []
        for i, (n1, n2) in enumerate(zip(i1, i2)):
            output1.append(n1)
            output2.append(n2)
            if i == 4:
                with warnings.catch_warnings(record=True) as wa:
                    i1 = iter(dp1)  # Reset both all child DataPipe
                    self.assertEqual(len(wa), 1)
                    self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
        self.assertEqual(list(range(5)) + list(range(10)), output1)
        self.assertEqual(list(range(5)) + list(range(10)), output2)

        # Reset Test: DataPipe reset, even when some other child DataPipes are not read
        dp1, dp2, dp3 = input_dp.fork(num_instances=3)
        output1, output2 = list(dp1), list(dp2)
        self.assertEqual(list(range(10)), output1)
        self.assertEqual(list(range(10)), output2)
        with warnings.catch_warnings(record=True) as wa:
            self.assertEqual(list(range(10)), list(dp1))  # Resets even though dp3 has not been read
            self.assertEqual(len(wa), 1)
            self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
        output3 = []
        for i, n3 in enumerate(dp3):
            output3.append(n3)
            if i == 4:
                with warnings.catch_warnings(record=True) as wa:
                    output1 = list(dp1)  # Resets even though dp3 is only partially read
                    self.assertEqual(len(wa), 1)
                    self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
                self.assertEqual(list(range(5)), output3)
                self.assertEqual(list(range(10)), output1)
                break
        self.assertEqual(list(range(10)), list(dp3))  # dp3 has to read from the start again

        # __len__ Test: Each DataPipe inherits the source datapipe's length
        dp1, dp2, dp3 = input_dp.fork(num_instances=3)
        self.assertEqual(len(input_dp), len(dp1))
        self.assertEqual(len(input_dp), len(dp2))
        self.assertEqual(len(input_dp), len(dp3))

        # Pickle Test:
        dp1, dp2, dp3 = input_dp.fork(num_instances=3)
        traverse(dp1)  # This should not raise any error
        for _ in zip(dp1, dp2, dp3):
            pass
        traverse(dp2)  # This should not raise any error either

    def test_mux_iterdatapipe(self):

        # Functional Test: Elements are yielded one at a time from each DataPipe, until they are all exhausted
        input_dp1 = dp.iter.IterableWrapper(range(4))
        input_dp2 = dp.iter.IterableWrapper(range(4, 8))
        input_dp3 = dp.iter.IterableWrapper(range(8, 12))
        output_dp = input_dp1.mux(input_dp2, input_dp3)
        expected_output = [0, 4, 8, 1, 5, 9, 2, 6, 10, 3, 7, 11]
        self.assertEqual(len(expected_output), len(output_dp))
        self.assertEqual(expected_output, list(output_dp))

        # Functional Test: Uneven input Data Pipes
        input_dp1 = dp.iter.IterableWrapper([1, 2, 3, 4])
        input_dp2 = dp.iter.IterableWrapper([10])
        input_dp3 = dp.iter.IterableWrapper([100, 200, 300])
        output_dp = input_dp1.mux(input_dp2, input_dp3)
        expected_output = [1, 10, 100, 2, 200, 3, 300, 4]
        self.assertEqual(len(expected_output), len(output_dp))
        self.assertEqual(expected_output, list(output_dp))

        # Functional Test: Empty Data Pipe
        input_dp1 = dp.iter.IterableWrapper([0, 1, 2, 3])
        input_dp2 = dp.iter.IterableWrapper([])
        output_dp = input_dp1.mux(input_dp2)
        self.assertEqual(len(input_dp1), len(output_dp))
        self.assertEqual(list(input_dp1), list(output_dp))

        # __len__ Test: raises TypeError when __len__ is called and an input doesn't have __len__
        input_dp1 = dp.iter.IterableWrapper(range(10))
        input_dp_no_len = IDP_NoLen(range(10))
        output_dp = input_dp1.mux(input_dp_no_len)
        with self.assertRaises(TypeError):
            len(output_dp)

    def test_demux_iterdatapipe(self):
        input_dp = dp.iter.IterableWrapper(range(10))

        with self.assertRaises(ValueError):
            input_dp.demux(num_instances=0, classifier_fn=lambda x: 0)

        # Functional Test: split into 2 DataPipes and output them one at a time
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        output1, output2 = list(dp1), list(dp2)
        self.assertEqual(list(range(0, 10, 2)), output1)
        self.assertEqual(list(range(1, 10, 2)), output2)

        # Functional Test: split into 2 DataPipes and output them together
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        output = []
        for n1, n2 in zip(dp1, dp2):
            output.append((n1, n2))
        self.assertEqual([(i, i + 1) for i in range(0, 10, 2)], output)

        # Functional Test: values of the same classification are lumped together, and buffer_size = 3 being too small
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: 0 if x >= 5 else 1, buffer_size=4)
        it1 = iter(dp1)
        with self.assertRaises(BufferError):
            next(it1)  # Buffer raises because first 5 elements all belong to the a different child
        with self.assertRaises(BufferError):
            list(dp2)

        # Functional Test: values of the same classification are lumped together, and buffer_size = 5 is just enough
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: 0 if x >= 5 else 1, buffer_size=5)
        output1, output2 = list(dp1), list(dp2)
        self.assertEqual(list(range(5, 10)), output1)
        self.assertEqual(list(range(0, 5)), output2)

        # Functional Test: values of the same classification are lumped together, and unlimited buffer
        with warnings.catch_warnings(record=True) as wa:
            dp1, dp2 = input_dp.demux(
                num_instances=2,
                classifier_fn=lambda x: 0 if x >= 5 else 1,
                buffer_size=-1
            )
            exp_l = 1 if HAS_DILL else 2
            self.assertEqual(len(wa), exp_l)
            self.assertRegex(str(wa[-1].message), r"Unlimited buffer size is set")
        output1, output2 = list(dp1), list(dp2)
        self.assertEqual(list(range(5, 10)), output1)
        self.assertEqual(list(range(0, 5)), output2)

        # Functional Test: classifier returns a value outside of [0, num_instance - 1]
        dp0 = input_dp.demux(num_instances=1, classifier_fn=lambda x: x % 2)
        it = iter(dp0[0])
        with self.assertRaises(ValueError):
            next(it)
            next(it)

        # Reset Test: DataPipe doesn't reset when it has not been read
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        i1 = iter(dp1)
        output2 = []
        i = 0
        for i, n2 in enumerate(dp2):
            output2.append(n2)
            if i == 4:
                i1 = iter(dp1)
        self.assertEqual(list(range(1, 10, 2)), output2)

        # Reset Test: DataPipe reset when some of it has been read
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        output1, output2 = [], []
        for n1, n2 in zip(dp1, dp2):
            output1.append(n1)
            output2.append(n2)
            if n1 == 4:
                break
        with warnings.catch_warnings(record=True) as wa:
            i1 = iter(dp1)  # Reset all child DataPipes
            self.assertEqual(len(wa), 1)
            self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
        for n1, n2 in zip(dp1, dp2):
            output1.append(n1)
            output2.append(n2)
        self.assertEqual([0, 2, 4] + list(range(0, 10, 2)), output1)
        self.assertEqual([1, 3, 5] + list(range(1, 10, 2)), output2)

        # Reset Test: DataPipe reset, even when not all child DataPipes are exhausted
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        output1 = list(dp1)
        self.assertEqual(list(range(0, 10, 2)), output1)
        with warnings.catch_warnings(record=True) as wa:
            self.assertEqual(list(range(0, 10, 2)), list(dp1))  # Reset even when dp2 is not read
            self.assertEqual(len(wa), 1)
            self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
        output2 = []
        for i, n2 in enumerate(dp2):
            output2.append(n2)
            if i == 1:
                self.assertEqual(list(range(1, 5, 2)), output2)
                with warnings.catch_warnings(record=True) as wa:
                    self.assertEqual(list(range(0, 10, 2)), list(dp1))  # Can reset even when dp2 is partially read
                    self.assertEqual(len(wa), 1)
                    self.assertRegex(str(wa[0].message), r"Some child DataPipes are not exhausted")
                break
        output2 = list(dp2)  # output2 has to read from beginning again
        self.assertEqual(list(range(1, 10, 2)), output2)

        # Functional Test: drop_none = True
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2 if x % 5 != 0 else None,
                                  drop_none=True)
        self.assertEqual([2, 4, 6, 8], list(dp1))
        self.assertEqual([1, 3, 7, 9], list(dp2))

        # Functional Test: drop_none = False
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2 if x % 5 != 0 else None,
                                  drop_none=False)
        it1 = iter(dp1)
        with self.assertRaises(ValueError):
            next(it1)

        # __len__ Test: __len__ not implemented
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=lambda x: x % 2)
        with self.assertRaises(TypeError):
            len(dp1)  # It is not implemented as we do not know length for each child in advance
        with self.assertRaises(TypeError):
            len(dp2)

        # Pickle Test:
        dp1, dp2 = input_dp.demux(num_instances=2, classifier_fn=odd_or_even)
        traverse(dp1)  # This should not raise any error
        for _ in zip(dp1, dp2):
            pass
        traverse(dp2)  # This should not raise any error either

    def test_map_iterdatapipe(self):
        input_dp = dp.iter.IterableWrapper(range(10))

        def fn(item, dtype=torch.float, *, sum=False):
            data = torch.tensor(item, dtype=dtype)
            return data if not sum else data.sum()

        # Functional Test: apply to each element correctly
        map_dp = input_dp.map(fn)
        self.assertEqual(len(input_dp), len(map_dp))
        for x, y in zip(map_dp, input_dp):
            self.assertEqual(x, torch.tensor(y, dtype=torch.float))

        # Functional Test: works with partial function
        map_dp = input_dp.map(partial(fn, dtype=torch.int, sum=True))
        for x, y in zip(map_dp, input_dp):
            self.assertEqual(x, torch.tensor(y, dtype=torch.int).sum())

        # __len__ Test: inherits length from source DataPipe
        self.assertEqual(len(input_dp), len(map_dp))

        input_dp_nl = IDP_NoLen(range(10))
        map_dp_nl = input_dp_nl.map(lambda x: x)
        for x, y in zip(map_dp_nl, input_dp_nl):
            self.assertEqual(x, torch.tensor(y, dtype=torch.float))

        # __len__ Test: inherits length from source DataPipe - raises error when invalid
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(map_dp_nl)

        # Reset Test: DataPipe resets properly
        n_elements_before_reset = 5
        res_before_reset, res_after_reset = reset_after_n_next_calls(map_dp, n_elements_before_reset)
        self.assertEqual(list(range(n_elements_before_reset)), res_before_reset)
        self.assertEqual(list(range(10)), res_after_reset)

    @suppress_warnings  # Suppress warning for lambda fn
    def test_map_tuple_list_with_col_iterdatapipe(self):
        def fn_11(d):
            return -d

        def fn_1n(d):
            return -d, d

        def fn_n1(d0, d1):
            return d0 + d1

        def fn_nn(d0, d1):
            return -d0, -d1, d0 + d1

        def _helper(ref_fn, fn, input_col=None, output_col=None):
            for constr in (list, tuple):
                datapipe = dp.iter.IterableWrapper([constr((0, 1, 2)), constr((3, 4, 5)), constr((6, 7, 8))])
                res_dp = datapipe.map(fn, input_col, output_col)
                ref_dp = datapipe.map(ref_fn)
                self.assertEqual(list(res_dp), list(ref_dp))
                # Reset
                self.assertEqual(list(res_dp), list(ref_dp))

        # Replacing with one input column and default output column
        _helper(lambda data: (data[0], -data[1], data[2]), fn_11, 1)
        _helper(lambda data: (data[0], (-data[1], data[1]), data[2]), fn_1n, 1)
        # The index of input column is out of range
        with self.assertRaises(IndexError):
            _helper(None, fn_1n, 3)
        # Unmatched input columns with fn arguments
        with self.assertRaises(TypeError):
            _helper(None, fn_n1, 1)
        # Replacing with multiple input columns and default output column (the left-most input column)
        _helper(lambda data: (data[1], data[2] + data[0]), fn_n1, [2, 0])
        _helper(lambda data: (data[0], (-data[2], -data[1], data[2] + data[1])), fn_nn, [2, 1])

        # output_col can only be specified when input_col is not None
        with self.assertRaises(ValueError):
            _helper(None, fn_n1, None, 1)
        # output_col can only be single-element list or tuple
        with self.assertRaises(ValueError):
            _helper(None, fn_n1, None, [0, 1])
        # Single-element list as output_col
        _helper(lambda data: (-data[1], data[1], data[2]), fn_11, 1, [0])
        # Replacing with one input column and single specified output column
        _helper(lambda data: (-data[1], data[1], data[2]), fn_11, 1, 0)
        _helper(lambda data: (data[0], data[1], (-data[1], data[1])), fn_1n, 1, 2)
        # The index of output column is out of range
        with self.assertRaises(IndexError):
            _helper(None, fn_1n, 1, 3)
        _helper(lambda data: (data[0], data[0] + data[2], data[2]), fn_n1, [0, 2], 1)
        _helper(lambda data: ((-data[1], -data[2], data[1] + data[2]), data[1], data[2]), fn_nn, [1, 2], 0)

        # Appending the output at the end
        _helper(lambda data: (*data, -data[1]), fn_11, 1, -1)
        _helper(lambda data: (*data, (-data[1], data[1])), fn_1n, 1, -1)
        _helper(lambda data: (*data, data[0] + data[2]), fn_n1, [0, 2], -1)
        _helper(lambda data: (*data, (-data[1], -data[2], data[1] + data[2])), fn_nn, [1, 2], -1)

    @suppress_warnings  # Suppress warning for lambda fn
    def test_map_dict_with_col_iterdatapipe(self):
        def fn_11(d):
            return -d

        def fn_1n(d):
            return -d, d

        def fn_n1(d0, d1):
            return d0 + d1

        def fn_nn(d0, d1):
            return -d0, -d1, d0 + d1

        # Prevent modification in-place to support resetting
        def _dict_update(data, newdata, remove_idx=None):
            _data = dict(data)
            _data.update(newdata)
            if remove_idx:
                for idx in remove_idx:
                    del _data[idx]
            return _data

        def _helper(ref_fn, fn, input_col=None, output_col=None):
            datapipe = dp.iter.IterableWrapper(
                [{"x": 0, "y": 1, "z": 2},
                 {"x": 3, "y": 4, "z": 5},
                 {"x": 6, "y": 7, "z": 8}]
            )
            res_dp = datapipe.map(fn, input_col, output_col)
            ref_dp = datapipe.map(ref_fn)
            self.assertEqual(list(res_dp), list(ref_dp))
            # Reset
            self.assertEqual(list(res_dp), list(ref_dp))

        # Replacing with one input column and default output column
        _helper(lambda data: _dict_update(data, {"y": -data["y"]}), fn_11, "y")
        _helper(lambda data: _dict_update(data, {"y": (-data["y"], data["y"])}), fn_1n, "y")
        # The key of input column is not in dict
        with self.assertRaises(KeyError):
            _helper(None, fn_1n, "a")
        # Unmatched input columns with fn arguments
        with self.assertRaises(TypeError):
            _helper(None, fn_n1, "y")
        # Replacing with multiple input columns and default output column (the left-most input column)
        _helper(lambda data: _dict_update(data, {"z": data["x"] + data["z"]}, ["x"]), fn_n1, ["z", "x"])
        _helper(lambda data: _dict_update(
            data, {"z": (-data["z"], -data["y"], data["y"] + data["z"])}, ["y"]), fn_nn, ["z", "y"])

        # output_col can only be specified when input_col is not None
        with self.assertRaises(ValueError):
            _helper(None, fn_n1, None, "x")
        # output_col can only be single-element list or tuple
        with self.assertRaises(ValueError):
            _helper(None, fn_n1, None, ["x", "y"])
        # Single-element list as output_col
        _helper(lambda data: _dict_update(data, {"x": -data["y"]}), fn_11, "y", ["x"])
        # Replacing with one input column and single specified output column
        _helper(lambda data: _dict_update(data, {"x": -data["y"]}), fn_11, "y", "x")
        _helper(lambda data: _dict_update(data, {"z": (-data["y"], data["y"])}), fn_1n, "y", "z")
        _helper(lambda data: _dict_update(data, {"y": data["x"] + data["z"]}), fn_n1, ["x", "z"], "y")
        _helper(lambda data: _dict_update(
            data, {"x": (-data["y"], -data["z"], data["y"] + data["z"])}), fn_nn, ["y", "z"], "x")

        # Adding new key to dict for the output
        _helper(lambda data: _dict_update(data, {"a": -data["y"]}), fn_11, "y", "a")
        _helper(lambda data: _dict_update(data, {"a": (-data["y"], data["y"])}), fn_1n, "y", "a")
        _helper(lambda data: _dict_update(data, {"a": data["x"] + data["z"]}), fn_n1, ["x", "z"], "a")
        _helper(lambda data: _dict_update(
            data, {"a": (-data["y"], -data["z"], data["y"] + data["z"])}), fn_nn, ["y", "z"], "a")

    def test_collate_iterdatapipe(self):
        arrs = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]
        input_dp = dp.iter.IterableWrapper(arrs)

        def _collate_fn(batch, default_type=torch.float):
            return torch.tensor(sum(batch), dtype=default_type)

        # Functional Test: defaults to the default collate function when a custom one is not specified
        collate_dp = input_dp.collate()
        for x, y in zip(input_dp, collate_dp):
            self.assertEqual(torch.tensor(x), y)

        # Functional Test: custom collate function
        collate_dp = input_dp.collate(collate_fn=_collate_fn)
        for x, y in zip(input_dp, collate_dp):
            self.assertEqual(torch.tensor(sum(x), dtype=torch.float), y)

        # Functional Test: custom, partial collate function
        collate_dp = input_dp.collate(partial(_collate_fn, default_type=torch.int))
        for x, y in zip(input_dp, collate_dp):
            self.assertEqual(torch.tensor(sum(x), dtype=torch.int), y)

        # Reset Test: reset the DataPipe and results are still correct
        n_elements_before_reset = 1
        res_before_reset, res_after_reset = reset_after_n_next_calls(collate_dp, n_elements_before_reset)
        self.assertEqual([torch.tensor(6, dtype=torch.int)], res_before_reset)
        for x, y in zip(input_dp, res_after_reset):
            self.assertEqual(torch.tensor(sum(x), dtype=torch.int), y)

        # __len__ Test: __len__ is inherited
        self.assertEqual(len(input_dp), len(collate_dp))

        # __len__ Test: verify that it has no valid __len__ when the source doesn't have it
        input_dp_nl = IDP_NoLen(arrs)
        collate_dp_nl = input_dp_nl.collate()
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(collate_dp_nl)
        for x, y in zip(input_dp_nl, collate_dp_nl):
            self.assertEqual(torch.tensor(x), y)

    def test_batch_iterdatapipe(self):
        arrs = list(range(10))
        input_dp = dp.iter.IterableWrapper(arrs)

        # Functional Test: raise error when input argument `batch_size = 0`
        with self.assertRaises(AssertionError):
            input_dp.batch(batch_size=0)

        # Functional Test: by default, do not drop the last batch
        bs = 3
        batch_dp = input_dp.batch(batch_size=bs)
        self.assertEqual(len(batch_dp), 4)
        for i, batch in enumerate(batch_dp):
            self.assertEqual(len(batch), 1 if i == 3 else bs)
            self.assertEqual(batch, arrs[i * bs: i * bs + len(batch)])

        # Functional Test: Drop the last batch when specified
        bs = 4
        batch_dp = input_dp.batch(batch_size=bs, drop_last=True)
        for i, batch in enumerate(batch_dp):
            self.assertEqual(batch, arrs[i * bs: i * bs + len(batch)])

        # __len__ test: verifying that the overall length and of each batch is correct
        for i, batch in enumerate(batch_dp):
            self.assertEqual(len(batch), bs)

        # __len__ Test: the length is missing if the source DataPipe doesn't have length
        self.assertEqual(len(batch_dp), 2)
        input_dp_nl = IDP_NoLen(range(10))
        batch_dp_nl = input_dp_nl.batch(batch_size=2)
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(batch_dp_nl)

        # Reset Test: Ensures that the DataPipe can properly reset
        n_elements_before_reset = 1
        res_before_reset, res_after_reset = reset_after_n_next_calls(batch_dp, n_elements_before_reset)
        self.assertEqual([[0, 1, 2, 3]], res_before_reset)
        self.assertEqual([[0, 1, 2, 3], [4, 5, 6, 7]], res_after_reset)

    def test_unbatch_iterdatapipe(self):
        target_length = 6
        prebatch_dp = dp.iter.IterableWrapper(range(target_length))

        # Functional Test: Unbatch DataPipe should be the same as pre-batch DataPipe
        input_dp = prebatch_dp.batch(3)
        unbatch_dp = input_dp.unbatch()
        self.assertEqual(len(list(unbatch_dp)), target_length)  # __len__ is as expected
        for i, res in zip(prebatch_dp, unbatch_dp):
            self.assertEqual(i, res)

        # Functional Test: unbatch works for an input with nested levels
        input_dp = dp.iter.IterableWrapper([[0, 1, 2], [3, 4, 5]])
        unbatch_dp = input_dp.unbatch()
        self.assertEqual(len(list(unbatch_dp)), target_length)
        for i, res in zip(prebatch_dp, unbatch_dp):
            self.assertEqual(i, res)

        input_dp = dp.iter.IterableWrapper([[[0, 1], [2, 3]], [[4, 5], [6, 7]]])

        # Functional Test: unbatch works for an input with nested levels
        unbatch_dp = input_dp.unbatch()
        expected_dp = [[0, 1], [2, 3], [4, 5], [6, 7]]
        self.assertEqual(len(list(unbatch_dp)), 4)
        for i, res in zip(expected_dp, unbatch_dp):
            self.assertEqual(i, res)

        # Functional Test: unbatching multiple levels at the same time
        unbatch_dp = input_dp.unbatch(unbatch_level=2)
        expected_dp2 = [0, 1, 2, 3, 4, 5, 6, 7]
        self.assertEqual(len(list(unbatch_dp)), 8)
        for i, res in zip(expected_dp2, unbatch_dp):
            self.assertEqual(i, res)

        # Functional Test: unbatching all levels at the same time
        unbatch_dp = input_dp.unbatch(unbatch_level=-1)
        self.assertEqual(len(list(unbatch_dp)), 8)
        for i, res in zip(expected_dp2, unbatch_dp):
            self.assertEqual(i, res)

        # Functional Test: raises error when input unbatch_level is less than -1
        input_dp = dp.iter.IterableWrapper([[0, 1, 2], [3, 4, 5]])
        with self.assertRaises(ValueError):
            unbatch_dp = input_dp.unbatch(unbatch_level=-2)
            for i in unbatch_dp:
                print(i)

        # Functional Test: raises error when input unbatch_level is too high
        with self.assertRaises(IndexError):
            unbatch_dp = input_dp.unbatch(unbatch_level=5)
            for i in unbatch_dp:
                print(i)

        # Reset Test: unbatch_dp resets properly
        input_dp = dp.iter.IterableWrapper([[0, 1, 2], [3, 4, 5]])
        unbatch_dp = input_dp.unbatch(unbatch_level=-1)
        n_elements_before_reset = 3
        res_before_reset, res_after_reset = reset_after_n_next_calls(unbatch_dp, n_elements_before_reset)
        self.assertEqual([0, 1, 2], res_before_reset)
        self.assertEqual([0, 1, 2, 3, 4, 5], res_after_reset)

    def test_filter_datapipe(self):
        input_ds = dp.iter.IterableWrapper(range(10))

        def _filter_fn(data, val, clip=False):
            if clip:
                return data >= val
            return True

        # Functional Test: filter works with partial function
        filter_dp = input_ds.filter(partial(_filter_fn, val=5))
        for data, exp in zip(filter_dp, range(10)):
            self.assertEqual(data, exp)

        # Functional Test: filter works with partial function with keyword args
        filter_dp = input_ds.filter(partial(_filter_fn, val=5, clip=True))
        for data, exp in zip(filter_dp, range(5, 10)):
            self.assertEqual(data, exp)

        def _non_bool_fn(data):
            return 1

        # Functional Test: filter function must return bool
        filter_dp = input_ds.filter(filter_fn=_non_bool_fn)
        with self.assertRaises(ValueError):
            temp = list(filter_dp)

        # __len__ Test: DataPipe has no valid len
        with self.assertRaisesRegex(TypeError, r"has no len"):
            len(filter_dp)

        # Reset Test: DataPipe resets correctly
        filter_dp = input_ds.filter(partial(_filter_fn, val=5, clip=True))
        n_elements_before_reset = 3
        res_before_reset, res_after_reset = reset_after_n_next_calls(filter_dp, n_elements_before_reset)
        self.assertEqual(list(range(5, 10))[:n_elements_before_reset], res_before_reset)
        self.assertEqual(list(range(5, 10)), res_after_reset)

    def test_sampler_iterdatapipe(self):
        input_dp = dp.iter.IterableWrapper(range(10))
        # Default SequentialSampler
        sampled_dp = dp.iter.Sampler(input_dp)  # type: ignore[var-annotated]
        self.assertEqual(len(sampled_dp), 10)
        for i, x in enumerate(sampled_dp):
            self.assertEqual(x, i)

        # RandomSampler
        random_sampled_dp = dp.iter.Sampler(input_dp, sampler=RandomSampler, sampler_kwargs={'replacement': True})  # type: ignore[var-annotated] # noqa: B950

        # Requires `__len__` to build SamplerDataPipe
        input_dp_nolen = IDP_NoLen(range(10))
        with self.assertRaises(AssertionError):
            sampled_dp = dp.iter.Sampler(input_dp_nolen)

    def test_shuffle_iterdatapipe(self):
        exp = list(range(20))
        input_ds = dp.iter.IterableWrapper(exp)

        with self.assertRaises(AssertionError):
            shuffle_dp = input_ds.shuffle(buffer_size=0)

        for bs in (5, 20, 25):
            shuffle_dp = input_ds.shuffle(buffer_size=bs)
            self.assertEqual(len(shuffle_dp), len(input_ds))

            random.seed(123)
            res = list(shuffle_dp)
            self.assertEqual(sorted(res), exp)

            # Test Deterministic
            for num_workers in (0, 1):
                random.seed(123)
                dl = DataLoader(shuffle_dp, num_workers=num_workers, worker_init_fn=_worker_init_fn, shuffle=True)
                dl_res = list(dl)
                self.assertEqual(res, dl_res)

        shuffle_dp_nl = IDP_NoLen(range(20)).shuffle(buffer_size=5)
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(shuffle_dp_nl)

        # Test: deactivate shuffling via set_shuffle
        unshuffled_dp = input_ds.shuffle().set_shuffle(False)
        self.assertEqual(list(unshuffled_dp), list(input_ds))

    def test_zip_iterdatapipe(self):

        # Functional Test: raises TypeError when an input is not of type `IterDataPipe`
        with self.assertRaises(TypeError):
            dp.iter.Zipper(dp.iter.IterableWrapper(range(10)), list(range(10)))  # type: ignore[arg-type]

        # Functional Test: raises TypeError when an input does not have valid length
        zipped_dp = dp.iter.Zipper(dp.iter.IterableWrapper(
            range(10)), IDP_NoLen(range(5)))  # type: ignore[var-annotated]
        with self.assertRaisesRegex(TypeError, r"instance doesn't have valid length$"):
            len(zipped_dp)

        # Functional Test: zips the results properly
        exp = list((i, i) for i in range(5))
        self.assertEqual(list(zipped_dp), exp)

        # Functional Test: zips the inputs properly even when lengths are different (zips to the shortest)
        zipped_dp = dp.iter.Zipper(dp.iter.IterableWrapper(range(10)), dp.iter.IterableWrapper(range(5)))

        # __len__ Test: length matches the length of the shortest input
        self.assertEqual(len(zipped_dp), 5)

        # Reset Test:
        n_elements_before_reset = 3
        res_before_reset, res_after_reset = reset_after_n_next_calls(zipped_dp, n_elements_before_reset)
        self.assertEqual(list((i, i) for i in range(5))[:n_elements_before_reset], res_before_reset)
        self.assertEqual(list((i, i) for i in range(5)), res_after_reset)


class TestFunctionalMapDataPipe(TestCase):

    def _serialization_test_helper(self, datapipe):
        serialized_dp = pickle.dumps(datapipe)
        deserialized_dp = pickle.loads(serialized_dp)
        try:
            self.assertEqual(list(datapipe), list(deserialized_dp))
        except AssertionError as e:
            print(f"{datapipe} is failing.")
            raise e

    def _serialization_test_for_single_dp(self, dp):
        # 1. Testing for serialization before any iteration starts
        self._serialization_test_helper(dp)
        # 2. Testing for serialization after DataPipe is partially read
        it = iter(dp)
        _ = next(it)
        self._serialization_test_helper(dp)
        # 3. Testing for serialization after DataPipe is fully read
        _ = list(it)
        self._serialization_test_helper(dp)

    def test_serializable(self):
        picklable_datapipes: List = [
            (dp.map.Batcher, None, (2,), {}),
            (dp.map.Concater, None, (dp.map.SequenceWrapper(range(10)),), {}),
            (dp.map.Mapper, None, (), {}),
            (dp.map.Mapper, None, (_fake_fn, ), {}),
            (dp.map.Mapper, None, (partial(_fake_add, 1), ), {}),
            (dp.map.SequenceWrapper, range(10), (), {}),
            (dp.map.Shuffler, dp.map.SequenceWrapper([0] * 5), (), {}),
            (dp.map.Zipper, None, (dp.map.SequenceWrapper(range(10)),), {}),
        ]
        for dpipe, custom_input, dp_args, dp_kwargs in picklable_datapipes:
            if custom_input is None:
                custom_input = dp.map.SequenceWrapper(range(10))
            datapipe = dpipe(custom_input, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
            self._serialization_test_for_single_dp(datapipe)

    def test_serializable_with_dill(self):
        """Only for DataPipes that take in a function as argument"""
        input_dp = dp.map.SequenceWrapper(range(10))
        unpicklable_datapipes: List[
            Tuple[Type[MapDataPipe], Tuple, Dict[str, Any]]
        ] = [
            (dp.map.Mapper, (lambda x: x,), {}),
        ]
        if HAS_DILL:
            for dpipe, dp_args, dp_kwargs in unpicklable_datapipes:
                _ = pickle.dumps(dpipe(input_dp, *dp_args, **dp_kwargs))  # type: ignore[call-arg]
        else:
            for dpipe, dp_args, dp_kwargs in unpicklable_datapipes:
                with warnings.catch_warnings(record=True) as wa:
                    datapipe = dpipe(input_dp, *dp_args, **dp_kwargs)  # type: ignore[call-arg]
                    self.assertEqual(len(wa), 1)
                    self.assertRegex(
                        str(wa[0].message), r"^Lambda function is not supported for pickle"
                    )
                    with self.assertRaises(AttributeError):
                        p = pickle.dumps(datapipe)

    def test_sequence_wrapper_datapipe(self):
        seq = list(range(10))
        input_dp = dp.map.SequenceWrapper(seq)

        # Functional Test: all elements are equal in the same order
        self.assertEqual(seq, list(input_dp))

        # Functional Test: confirm deepcopy works by default
        seq.append(11)
        self.assertEqual(list(range(10)), list(input_dp))  # input_dp shouldn't have 11

        # Functional Test: non-deepcopy version is working
        seq2 = [1, 2, 3]
        input_dp_non_deep = dp.map.SequenceWrapper(seq2, deepcopy=False)
        seq2.append(4)
        self.assertEqual(list(seq2), list(input_dp_non_deep))  # should have 4

        # Reset Test: reset the DataPipe
        seq = list(range(10))
        n_elements_before_reset = 5
        res_before_reset, res_after_reset = reset_after_n_next_calls(input_dp, n_elements_before_reset)
        self.assertEqual(list(range(5)), res_before_reset)
        self.assertEqual(seq, res_after_reset)

        # __len__ Test: inherits length from sequence
        self.assertEqual(len(seq), len(input_dp))

    def test_concat_mapdatapipe(self):
        input_dp1 = dp.map.SequenceWrapper(range(10))
        input_dp2 = dp.map.SequenceWrapper(range(5))

        with self.assertRaisesRegex(ValueError, r"Expected at least one DataPipe"):
            dp.map.Concater()

        with self.assertRaisesRegex(TypeError, r"Expected all inputs to be `MapDataPipe`"):
            dp.map.Concater(input_dp1, ())  # type: ignore[arg-type]

        concat_dp = input_dp1.concat(input_dp2)
        self.assertEqual(len(concat_dp), 15)
        for index in range(15):
            self.assertEqual(concat_dp[index], (list(range(10)) + list(range(5)))[index])
        self.assertEqual(list(concat_dp), list(range(10)) + list(range(5)))

    def test_zip_mapdatapipe(self):
        input_dp1 = dp.map.SequenceWrapper(range(10))
        input_dp2 = dp.map.SequenceWrapper(range(5))
        input_dp3 = dp.map.SequenceWrapper(range(15))

        # Functional Test: requires at least one input DataPipe
        with self.assertRaisesRegex(ValueError, r"Expected at least one DataPipe"):
            dp.map.Zipper()

        # Functional Test: all inputs must be MapDataPipes
        with self.assertRaisesRegex(TypeError, r"Expected all inputs to be `MapDataPipe`"):
            dp.map.Zipper(input_dp1, ())  # type: ignore[arg-type]

        # Functional Test: Zip the elements up as a tuples
        zip_dp = input_dp1.zip(input_dp2, input_dp3)
        self.assertEqual([(i, i, i) for i in range(5)], [zip_dp[i] for i in range(5)])

        # Functional Test: Raise IndexError when index equal or exceed the length of the shortest DataPipe
        with self.assertRaisesRegex(IndexError, r"out of range"):
            input_dp1.zip(input_dp2, input_dp3)[5]

        # __len__ Test: returns the length of the shortest DataPipe
        zip_dp = input_dp1.zip(input_dp2, input_dp3)
        self.assertEqual(5, len(zip_dp))

    def test_shuffler_mapdatapipe(self):
        input_dp1 = dp.map.SequenceWrapper(range(10))
        input_dp2 = dp.map.SequenceWrapper({'a': 1, 'b': 2, 'c': 3, 'd': 4, 'e': 5})

        # Functional Test: Assumes 0-index when indices is not given
        shuffler_dp = input_dp1.shuffle()
        self.assertEqual(set(range(10)), set(shuffler_dp))

        # Functional Test: Custom indices are working
        shuffler_dp = dp.map.Shuffler(input_dp2, indices=['a', 'b', 'c', 'd', 'e'])
        self.assertEqual(set(range(1, 6)), set(shuffler_dp))

        # # Reset Test:
        shuffler_dp = input_dp1.shuffle()
        n_elements_before_reset = 5
        res_before_reset, res_after_reset = reset_after_n_next_calls(shuffler_dp, n_elements_before_reset)
        self.assertEqual(5, len(res_before_reset))
        for x in res_before_reset:
            self.assertTrue(x in set(range(10)))
        self.assertEqual(set(range(10)), set(res_after_reset))

        # __len__ Test: returns the length of the input DataPipe
        shuffler_dp = input_dp1.shuffle()
        self.assertEqual(10, len(shuffler_dp))

    def test_map_mapdatapipe(self):
        arr = range(10)
        input_dp = dp.map.SequenceWrapper(arr)

        def fn(item, dtype=torch.float, *, sum=False):
            data = torch.tensor(item, dtype=dtype)
            return data if not sum else data.sum()

        map_dp = input_dp.map(fn)
        self.assertEqual(len(input_dp), len(map_dp))
        for index in arr:
            self.assertEqual(
                map_dp[index], torch.tensor(input_dp[index], dtype=torch.float)
            )

        map_dp = input_dp.map(partial(fn, dtype=torch.int, sum=True))
        self.assertEqual(len(input_dp), len(map_dp))
        for index in arr:
            self.assertEqual(
                map_dp[index], torch.tensor(input_dp[index], dtype=torch.int).sum()
            )

    def test_batch_mapdatapipe(self):
        arr = list(range(13))
        input_dp = dp.map.SequenceWrapper(arr)

        # Functional Test: batches top level by default
        batch_dp = dp.map.Batcher(input_dp, batch_size=2)
        self.assertEqual([[0, 1], [2, 3], [4, 5], [6, 7], [8, 9], [10, 11], [12]], list(batch_dp))

        # Functional Test: drop_last on command
        batch_dp = dp.map.Batcher(input_dp, batch_size=2, drop_last=True)
        self.assertEqual([[0, 1], [2, 3], [4, 5], [6, 7], [8, 9], [10, 11]], list(batch_dp))

        # Functional Test: nested batching
        batch_dp_2 = batch_dp.batch(batch_size=3)
        self.assertEqual([[[0, 1], [2, 3], [4, 5]], [[6, 7], [8, 9], [10, 11]]], list(batch_dp_2))

        # Reset Test:
        n_elements_before_reset = 3
        res_before_reset, res_after_reset = reset_after_n_next_calls(batch_dp, n_elements_before_reset)
        self.assertEqual([[0, 1], [2, 3], [4, 5]], res_before_reset)
        self.assertEqual([[0, 1], [2, 3], [4, 5], [6, 7], [8, 9], [10, 11]], res_after_reset)

        # __len__ Test:
        self.assertEqual(6, len(batch_dp))
        self.assertEqual(2, len(batch_dp_2))


# Metaclass conflict for Python 3.6
# Multiple inheritance with NamedTuple is not supported for Python 3.9
_generic_namedtuple_allowed = sys.version_info >= (3, 7) and sys.version_info < (3, 9)
if _generic_namedtuple_allowed:
    class InvalidData(Generic[T_co], NamedTuple):
        name: str
        data: T_co


class TestTyping(TestCase):
    def test_isinstance(self):
        class A(IterDataPipe):
            pass

        class B(IterDataPipe):
            pass

        a = A()
        self.assertTrue(isinstance(a, A))
        self.assertFalse(isinstance(a, B))

    def test_protocol(self):
        try:
            from typing import Protocol  # type: ignore[attr-defined]
        except ImportError:
            from typing import _Protocol  # type: ignore[attr-defined]
            Protocol = _Protocol

        class P(Protocol):
            pass

        class A(IterDataPipe[P]):
            pass

    @skipTyping
    def test_subtype(self):
        from torch.utils.data.datapipes._typing import issubtype

        basic_type = (int, str, bool, float, complex,
                      list, tuple, dict, set, T_co)
        for t in basic_type:
            self.assertTrue(issubtype(t, t))
            self.assertTrue(issubtype(t, Any))
            if t == T_co:
                self.assertTrue(issubtype(Any, t))
            else:
                self.assertFalse(issubtype(Any, t))
        for t1, t2 in itertools.product(basic_type, basic_type):
            if t1 == t2 or t2 == T_co:
                self.assertTrue(issubtype(t1, t2))
            else:
                self.assertFalse(issubtype(t1, t2))

        T = TypeVar('T', int, str)
        S = TypeVar('S', bool, Union[str, int], Tuple[int, T])  # type: ignore[valid-type]
        types = ((int, Optional[int]),
                 (List, Union[int, list]),
                 (Tuple[int, str], S),
                 (Tuple[int, str], tuple),
                 (T, S),
                 (S, T_co),
                 (T, Union[S, Set]))
        for sub, par in types:
            self.assertTrue(issubtype(sub, par))
            self.assertFalse(issubtype(par, sub))

        subscriptable_types = {
            List: 1,
            Tuple: 2,  # use 2 parameters
            Set: 1,
            Dict: 2,
        }
        for subscript_type, n in subscriptable_types.items():
            for ts in itertools.combinations(types, n):
                subs, pars = zip(*ts)
                sub = subscript_type[subs]  # type: ignore[index]
                par = subscript_type[pars]  # type: ignore[index]
                self.assertTrue(issubtype(sub, par))
                self.assertFalse(issubtype(par, sub))
                # Non-recursive check
                self.assertTrue(issubtype(par, sub, recursive=False))

    @skipTyping
    def test_issubinstance(self):
        from torch.utils.data.datapipes._typing import issubinstance

        basic_data = (1, '1', True, 1., complex(1., 0.))
        basic_type = (int, str, bool, float, complex)
        S = TypeVar('S', bool, Union[str, int])
        for d in basic_data:
            self.assertTrue(issubinstance(d, Any))
            self.assertTrue(issubinstance(d, T_co))
            if type(d) in (bool, int, str):
                self.assertTrue(issubinstance(d, S))
            else:
                self.assertFalse(issubinstance(d, S))
            for t in basic_type:
                if type(d) == t:
                    self.assertTrue(issubinstance(d, t))
                else:
                    self.assertFalse(issubinstance(d, t))
        # list/set
        dt = (([1, '1', 2], List), (set({1, '1', 2}), Set))
        for d, t in dt:
            self.assertTrue(issubinstance(d, t))
            self.assertTrue(issubinstance(d, t[T_co]))  # type: ignore[index]
            self.assertFalse(issubinstance(d, t[int]))  # type: ignore[index]

        # dict
        d = dict({'1': 1, '2': 2.})
        self.assertTrue(issubinstance(d, Dict))
        self.assertTrue(issubinstance(d, Dict[str, T_co]))
        self.assertFalse(issubinstance(d, Dict[str, int]))

        # tuple
        d = (1, '1', 2)
        self.assertTrue(issubinstance(d, Tuple))
        self.assertTrue(issubinstance(d, Tuple[int, str, T_co]))
        self.assertFalse(issubinstance(d, Tuple[int, Any]))
        self.assertFalse(issubinstance(d, Tuple[int, int, int]))

    # Static checking annotation
    @skipTyping
    def test_compile_time(self):
        with self.assertRaisesRegex(TypeError, r"Expected 'Iterator' as the return"):
            class InvalidDP1(IterDataPipe[int]):
                def __iter__(self) -> str:  # type: ignore[misc, override]
                    yield 0

        with self.assertRaisesRegex(TypeError, r"Expected return type of '__iter__'"):
            class InvalidDP2(IterDataPipe[Tuple]):
                def __iter__(self) -> Iterator[int]:  # type: ignore[override]
                    yield 0

        with self.assertRaisesRegex(TypeError, r"Expected return type of '__iter__'"):
            class InvalidDP3(IterDataPipe[Tuple[int, str]]):
                def __iter__(self) -> Iterator[tuple]:  # type: ignore[override]
                    yield (0, )

        if _generic_namedtuple_allowed:
            with self.assertRaisesRegex(TypeError, r"is not supported by Python typing"):
                class InvalidDP4(IterDataPipe["InvalidData[int]"]):  # type: ignore[type-arg, misc]
                    pass

        class DP1(IterDataPipe[Tuple[int, str]]):
            def __init__(self, length):
                self.length = length

            def __iter__(self) -> Iterator[Tuple[int, str]]:
                for d in range(self.length):
                    yield d, str(d)

        self.assertTrue(issubclass(DP1, IterDataPipe))
        dp1 = DP1(10)
        self.assertTrue(DP1.type.issubtype(dp1.type) and dp1.type.issubtype(DP1.type))  # type: ignore[attr-defined]
        dp1_ = DP1(5)
        self.assertEqual(dp1.type, dp1_.type)

        with self.assertRaisesRegex(TypeError, r"is not a generic class"):
            class InvalidDP5(DP1[tuple]):  # type: ignore[type-arg]
                def __iter__(self) -> Iterator[tuple]:  # type: ignore[override]
                    yield (0, )

        class DP2(IterDataPipe[T_co]):
            def __iter__(self) -> Iterator[T_co]:
                for d in range(10):
                    yield d  # type: ignore[misc]

        self.assertTrue(issubclass(DP2, IterDataPipe))
        dp2 = DP2()  # type: ignore[var-annotated]
        self.assertTrue(DP2.type.issubtype(dp2.type) and dp2.type.issubtype(DP2.type))  # type: ignore[attr-defined]
        dp2_ = DP2()  # type: ignore[var-annotated]
        self.assertEqual(dp2.type, dp2_.type)

        class DP3(IterDataPipe[Tuple[T_co, str]]):
            r""" DataPipe without fixed type with __init__ function"""

            def __init__(self, datasource):
                self.datasource = datasource

            def __iter__(self) -> Iterator[Tuple[T_co, str]]:
                for d in self.datasource:
                    yield d, str(d)

        self.assertTrue(issubclass(DP3, IterDataPipe))
        dp3 = DP3(range(10))  # type: ignore[var-annotated]
        self.assertTrue(DP3.type.issubtype(dp3.type) and dp3.type.issubtype(DP3.type))  # type: ignore[attr-defined]
        dp3_ = DP3(5)  # type: ignore[var-annotated]
        self.assertEqual(dp3.type, dp3_.type)

        class DP4(IterDataPipe[tuple]):
            r""" DataPipe without __iter__ annotation"""

            def __iter__(self):
                raise NotImplementedError

        self.assertTrue(issubclass(DP4, IterDataPipe))
        dp4 = DP4()
        self.assertTrue(dp4.type.param == tuple)

        class DP5(IterDataPipe):
            r""" DataPipe without type annotation"""

            def __iter__(self) -> Iterator[str]:
                raise NotImplementedError

        self.assertTrue(issubclass(DP5, IterDataPipe))
        dp5 = DP5()
        from torch.utils.data.datapipes._typing import issubtype
        self.assertTrue(issubtype(dp5.type.param, Any) and issubtype(Any, dp5.type.param))

        class DP6(IterDataPipe[int]):
            r""" DataPipe with plain Iterator"""

            def __iter__(self) -> Iterator:
                raise NotImplementedError

        self.assertTrue(issubclass(DP6, IterDataPipe))
        dp6 = DP6()
        self.assertTrue(dp6.type.param == int)

        class DP7(IterDataPipe[Awaitable[T_co]]):
            r""" DataPipe with abstract base class"""

        self.assertTrue(issubclass(DP7, IterDataPipe))
        self.assertTrue(DP7.type.param == Awaitable[T_co])  # type: ignore[attr-defined]

        class DP8(DP7[str]):
            r""" DataPipe subclass from a DataPipe with abc type"""

        self.assertTrue(issubclass(DP8, IterDataPipe))
        self.assertTrue(DP8.type.param == Awaitable[str])  # type: ignore[attr-defined]

    @skipTyping
    def test_construct_time(self):
        class DP0(IterDataPipe[Tuple]):
            @argument_validation
            def __init__(self, dp: IterDataPipe):
                self.dp = dp

            def __iter__(self) -> Iterator[Tuple]:
                for d in self.dp:
                    yield d, str(d)

        class DP1(IterDataPipe[int]):
            @argument_validation
            def __init__(self, dp: IterDataPipe[Tuple[int, str]]):
                self.dp = dp

            def __iter__(self) -> Iterator[int]:
                for a, b in self.dp:
                    yield a

        # Non-DataPipe input with DataPipe hint
        datasource = [(1, '1'), (2, '2'), (3, '3')]
        with self.assertRaisesRegex(TypeError, r"Expected argument 'dp' as a IterDataPipe"):
            dp0 = DP0(datasource)

        dp0 = DP0(dp.iter.IterableWrapper(range(10)))
        with self.assertRaisesRegex(TypeError, r"Expected type of argument 'dp' as a subtype"):
            dp1 = DP1(dp0)

    @skipTyping
    def test_runtime(self):
        class DP(IterDataPipe[Tuple[int, T_co]]):
            def __init__(self, datasource):
                self.ds = datasource

            @runtime_validation
            def __iter__(self) -> Iterator[Tuple[int, T_co]]:
                for d in self.ds:
                    yield d

        dss = ([(1, '1'), (2, '2')],
               [(1, 1), (2, '2')])
        for ds in dss:
            dp0 = DP(ds)  # type: ignore[var-annotated]
            self.assertEqual(list(dp0), ds)
            # Reset __iter__
            self.assertEqual(list(dp0), ds)

        dss = ([(1, 1), ('2', 2)],  # type: ignore[assignment, list-item]
               [[1, '1'], [2, '2']],  # type: ignore[list-item]
               [1, '1', 2, '2'])
        for ds in dss:
            dp0 = DP(ds)
            with self.assertRaisesRegex(RuntimeError, r"Expected an instance as subtype"):
                list(dp0)

            with runtime_validation_disabled():
                self.assertEqual(list(dp0), ds)
                with runtime_validation_disabled():
                    self.assertEqual(list(dp0), ds)

            with self.assertRaisesRegex(RuntimeError, r"Expected an instance as subtype"):
                list(dp0)

    @skipTyping
    def test_reinforce(self):
        T = TypeVar('T', int, str)

        class DP(IterDataPipe[T]):
            def __init__(self, ds):
                self.ds = ds

            @runtime_validation
            def __iter__(self) -> Iterator[T]:
                for d in self.ds:
                    yield d

        ds = list(range(10))
        # Valid type reinforcement
        dp0 = DP(ds).reinforce_type(int)
        self.assertTrue(dp0.type, int)
        self.assertEqual(list(dp0), ds)

        # Invalid type
        with self.assertRaisesRegex(TypeError, r"'expected_type' must be a type"):
            dp1 = DP(ds).reinforce_type(1)

        # Type is not subtype
        with self.assertRaisesRegex(TypeError, r"Expected 'expected_type' as subtype of"):
            dp2 = DP(ds).reinforce_type(float)

        # Invalid data at runtime
        dp3 = DP(ds).reinforce_type(str)
        with self.assertRaisesRegex(RuntimeError, r"Expected an instance as subtype"):
            list(dp3)

        # Context Manager to disable the runtime validation
        with runtime_validation_disabled():
            self.assertEqual(list(d for d in dp3), ds)


class NumbersDataset(IterDataPipe):
    def __init__(self, size=10):
        self.size = size

    def __iter__(self):
        for i in range(self.size):
            yield i


class TestGraph(TestCase):
    @skipIfNoDill
    def test_simple_traverse(self):
        numbers_dp = NumbersDataset(size=50)
        mapped_dp = numbers_dp.map(lambda x: x * 10)
        graph = torch.utils.data.graph.traverse(mapped_dp)
        expected: Dict[Any, Any] = {mapped_dp: {numbers_dp: {}}}
        self.assertEqual(expected, graph)

    @skipIfNoDill
    def test_traverse_forked(self):
        numbers_dp = NumbersDataset(size=50)
        dp0, dp1, dp2 = numbers_dp.fork(num_instances=3)
        dp0_upd = dp0.map(lambda x: x * 10)
        dp1_upd = dp1.filter(lambda x: x % 3 == 1)
        combined_dp = dp0_upd.mux(dp1_upd, dp2)
        graph = torch.utils.data.graph.traverse(combined_dp)
        expected = {combined_dp: {dp0_upd: {dp0: {dp0.main_datapipe: {dp0.main_datapipe.main_datapipe: {}}}},
                                  dp1_upd: {dp1: {dp1.main_datapipe: {dp1.main_datapipe.main_datapipe: {}}}},
                                  dp2: {dp2.main_datapipe: {dp2.main_datapipe.main_datapipe: {}}}}}
        self.assertEqual(expected, graph)


class TestCircularSerialization(TestCase):

    class CustomIterDataPipe(IterDataPipe):
        def add_one(self, x):
            return x + 1

        def classify(self, x):
            return 0

        def __init__(self):
            self._dp = dp.iter.IterableWrapper([1, 2, 4]).map(self.add_one).demux(2, self.classify)[0]

        def __iter__(self):
            yield from self._dp

    def test_circular_reference(self):
        self.assertEqual(
            list(TestCircularSerialization.CustomIterDataPipe()),
            list(pickle.loads(pickle.dumps(TestCircularSerialization.CustomIterDataPipe())))
        )
        _ = traverse(TestCircularSerialization.CustomIterDataPipe(), only_datapipe=True)
        _ = traverse(TestCircularSerialization.CustomIterDataPipe(), only_datapipe=False)

    # TODO: Ensure this works with `dill` installed
    # @skipIfNoDill
    # def test_circular_serialization_with_dill(self):
    #     assert list(self._CustomIterDataPipe()) == list(dill.loads(dill.dumps(self._CustomIterDataPipe())))


class TestSharding(TestCase):

    def _get_pipeline(self):
        numbers_dp = NumbersDataset(size=10)
        dp0, dp1 = numbers_dp.fork(num_instances=2)
        dp0_upd = dp0.map(lambda x: x * 10)
        dp1_upd = dp1.filter(lambda x: x % 3 == 1)
        combined_dp = dp0_upd.mux(dp1_upd)
        return combined_dp

    @skipIfNoDill
    def test_simple_sharding(self):
        sharded_dp = self._get_pipeline().sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp, 3, 1)
        items = list(sharded_dp)
        self.assertEqual([1, 20, 40, 70], items)

        all_items = list(self._get_pipeline())
        items = []
        for i in range(3):
            sharded_dp = self._get_pipeline().sharding_filter()
            torch.utils.data.graph_settings.apply_sharding(sharded_dp, 3, i)
            items += list(sharded_dp)

        self.assertEqual(sorted(all_items), sorted(items))

    def test_sharding_length(self):
        numbers_dp = dp.iter.IterableWrapper(range(13))
        sharded_dp0 = numbers_dp.sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp0, 3, 0)
        sharded_dp1 = numbers_dp.sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp1, 3, 1)
        sharded_dp2 = numbers_dp.sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp2, 3, 2)
        self.assertEqual(13, len(numbers_dp))
        self.assertEqual(5, len(sharded_dp0))
        self.assertEqual(4, len(sharded_dp1))
        self.assertEqual(4, len(sharded_dp2))

        numbers_dp = dp.iter.IterableWrapper(range(1))
        sharded_dp0 = numbers_dp.sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp0, 2, 0)
        sharded_dp1 = numbers_dp.sharding_filter()
        torch.utils.data.graph_settings.apply_sharding(sharded_dp1, 2, 1)
        self.assertEqual(1, len(sharded_dp0))
        self.assertEqual(0, len(sharded_dp1))

    @skipIfNoDill
    def test_old_dataloader(self):
        dp0 = self._get_pipeline()
        expected = list(dp0)

        dp0 = self._get_pipeline().sharding_filter()
        dl = DataLoader(dp0, batch_size=1, shuffle=False, num_workers=2,
                        worker_init_fn=torch.utils.data.backward_compatibility.worker_init_fn)
        items = []
        for i in dl:
            items.append(i)

        self.assertEqual(sorted(expected), sorted(items))


if __name__ == '__main__':
    run_tests()