PaddleSpeech/paddlespeech/s2t/io/batchfy.py

# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# Modified from espnet(https://github.com/espnet/espnet)
import itertools

import numpy as np

from paddlespeech.s2t.utils.log import Log

__all__ = ["make_batchset"]

logger = Log(__name__).getlog()


def batchfy_by_seq(
        sorted_data,
        batch_size,
        max_length_in,
        max_length_out,
        min_batch_size=1,
        shortest_first=False,
        ikey="input",
        iaxis=0,
        okey="output",
        oaxis=0, ):
    """Make batch set from json dictionary

    :param List[(str, Dict[str, Any])] sorted_data: dictionary loaded from data.json
    :param int batch_size: batch size
    :param int max_length_in: maximum length of input to decide adaptive batch size
    :param int max_length_out: maximum length of output to decide adaptive batch size
    :param int min_batch_size: mininum batch size (for multi-gpu)
    :param bool shortest_first: Sort from batch with shortest samples
        to longest if true, otherwise reverse
    :param str ikey: key to access input
        (for ASR ikey="input", for TTS, MT ikey="output".)
    :param int iaxis: dimension to access input
        (for ASR, TTS iaxis=0, for MT iaxis="1".)
    :param str okey: key to access output
        (for ASR, MT okey="output". for TTS okey="input".)
    :param int oaxis: dimension to access output
        (for ASR, TTS, MT oaxis=0, reserved for future research, -1 means all axis.)
    :return: List[List[Tuple[str, dict]]] list of batches
    """
    if batch_size <= 0:
        raise ValueError(f"Invalid batch_size={batch_size}")

    # check #utts is more than min_batch_size
    if len(sorted_data) < min_batch_size:
        raise ValueError(
            f"#utts({len(sorted_data)}) is less than min_batch_size({min_batch_size})."
        )

    # make list of minibatches
    minibatches = []
    start = 0
    while True:
        _, info = sorted_data[start]
        ilen = int(info[ikey][iaxis]["shape"][0])
        olen = (int(info[okey][oaxis]["shape"][0]) if oaxis >= 0 else
                max(map(lambda x: int(x["shape"][0]), info[okey])))
        factor = max(int(ilen / max_length_in), int(olen / max_length_out))
        # change batchsize depending on the input and output length
        # if ilen = 1000 and max_length_in = 800
        # then b = batchsize / 2
        # and max(min_batches, .) avoids batchsize = 0
        bs = max(min_batch_size, int(batch_size / (1 + factor)))
        end = min(len(sorted_data), start + bs)
        minibatch = sorted_data[start:end]
        if shortest_first:
            minibatch.reverse()

        # check each batch is more than minimum batchsize
        if len(minibatch) < min_batch_size:
            mod = min_batch_size - len(minibatch) % min_batch_size
            additional_minibatch = [
                sorted_data[i] for i in np.random.randint(0, start, mod)
            ]
            if shortest_first:
                additional_minibatch.reverse()
            minibatch.extend(additional_minibatch)
        minibatches.append(minibatch)

        if end == len(sorted_data):
            break
        start = end

    # batch: List[List[Tuple[str, dict]]]
    return minibatches


def batchfy_by_bin(
        sorted_data,
        batch_bins,
        num_batches=0,
        min_batch_size=1,
        shortest_first=False,
        ikey="input",
        okey="output", ):
    """Make variably sized batch set, which maximizes

    the number of bins up to `batch_bins`.

    :param List[(str, Dict[str, Any])] sorted_data: dictionary loaded from data.json
    :param int batch_bins: Maximum frames of a batch
    :param int num_batches: # number of batches to use (for debug)
    :param int min_batch_size: minimum batch size (for multi-gpu)
    :param int test: Return only every `test` batches
    :param bool shortest_first: Sort from batch with shortest samples
        to longest if true, otherwise reverse

    :param str ikey: key to access input (for ASR ikey="input", for TTS ikey="output".)
    :param str okey: key to access output (for ASR okey="output". for TTS okey="input".)

    :return: List[Tuple[str, Dict[str, List[Dict[str, Any]]]] list of batches
    """
    if batch_bins <= 0:
        raise ValueError(f"invalid batch_bins={batch_bins}")
    length = len(sorted_data)
    idim = int(sorted_data[0][1][ikey][0]["shape"][1])
    odim = int(sorted_data[0][1][okey][0]["shape"][1])
    logger.info("# utts: " + str(len(sorted_data)))
    minibatches = []
    start = 0
    n = 0
    while True:
        # Dynamic batch size depending on size of samples
        b = 0
        next_size = 0
        max_olen = 0
        while next_size < batch_bins and (start + b) < length:
            ilen = int(sorted_data[start + b][1][ikey][0]["shape"][0]) * idim
            olen = int(sorted_data[start + b][1][okey][0]["shape"][0]) * odim
            if olen > max_olen:
                max_olen = olen
            next_size = (max_olen + ilen) * (b + 1)
            if next_size <= batch_bins:
                b += 1
            elif next_size == 0:
                raise ValueError(
                    f"Can't fit one sample in batch_bins ({batch_bins}): "
                    f"Please increase the value")
        end = min(length, start + max(min_batch_size, b))
        batch = sorted_data[start:end]
        if shortest_first:
            batch.reverse()
        minibatches.append(batch)
        # Check for min_batch_size and fixes the batches if needed
        i = -1
        while len(minibatches[i]) < min_batch_size:
            missing = min_batch_size - len(minibatches[i])
            if -i == len(minibatches):
                minibatches[i + 1].extend(minibatches[i])
                minibatches = minibatches[1:]
                break
            else:
                minibatches[i].extend(minibatches[i - 1][:missing])
                minibatches[i - 1] = minibatches[i - 1][missing:]
                i -= 1
        if end == length:
            break
        start = end
        n += 1
    if num_batches > 0:
        minibatches = minibatches[:num_batches]
    lengths = [len(x) for x in minibatches]
    logger.info(
        str(len(minibatches)) + " batches containing from " + str(min(lengths))
        + " to " + str(max(lengths)) + " samples " + "(avg " + str(
            int(np.mean(lengths))) + " samples).")
    return minibatches


def batchfy_by_frame(
        sorted_data,
        max_frames_in,
        max_frames_out,
        max_frames_inout,
        num_batches=0,
        min_batch_size=1,
        shortest_first=False,
        ikey="input",
        okey="output", ):
    """Make variable batch set, which maximizes the number of frames to max_batch_frame.

    :param List[(str, Dict[str, Any])] sorteddata: dictionary loaded from data.json
    :param int max_frames_in: Maximum input frames of a batch
    :param int max_frames_out: Maximum output frames of a batch
    :param int max_frames_inout: Maximum input+output frames of a batch
    :param int num_batches: # number of batches to use (for debug)
    :param int min_batch_size: minimum batch size (for multi-gpu)
    :param int test: Return only every `test` batches
    :param bool shortest_first: Sort from batch with shortest samples
        to longest if true, otherwise reverse

    :param str ikey: key to access input (for ASR ikey="input", for TTS ikey="output".)
    :param str okey: key to access output (for ASR okey="output". for TTS okey="input".)

    :return: List[Tuple[str, Dict[str, List[Dict[str, Any]]]] list of batches
    """
    if max_frames_in <= 0 and max_frames_out <= 0 and max_frames_inout <= 0:
        raise ValueError(
            "At least, one of `--batch-frames-in`, `--batch-frames-out` or "
            "`--batch-frames-inout` should be > 0")
    length = len(sorted_data)
    minibatches = []
    start = 0
    end = 0
    while end != length:
        # Dynamic batch size depending on size of samples
        b = 0
        max_olen = 0
        max_ilen = 0
        while (start + b) < length:
            ilen = int(sorted_data[start + b][1][ikey][0]["shape"][0])
            if ilen > max_frames_in and max_frames_in != 0:
                raise ValueError(
                    f"Can't fit one sample in --batch-frames-in ({max_frames_in}): "
                    f"Please increase the value")
            olen = int(sorted_data[start + b][1][okey][0]["shape"][0])
            if olen > max_frames_out and max_frames_out != 0:
                raise ValueError(
                    f"Can't fit one sample in --batch-frames-out ({max_frames_out}): "
                    f"Please increase the value")
            if ilen + olen > max_frames_inout and max_frames_inout != 0:
                raise ValueError(
                    f"Can't fit one sample in --batch-frames-out ({max_frames_inout}): "
                    f"Please increase the value")
            max_olen = max(max_olen, olen)
            max_ilen = max(max_ilen, ilen)
            in_ok = max_ilen * (b + 1) <= max_frames_in or max_frames_in == 0
            out_ok = max_olen * (b + 1) <= max_frames_out or max_frames_out == 0
            inout_ok = (max_ilen + max_olen) * (
                b + 1) <= max_frames_inout or max_frames_inout == 0
            if in_ok and out_ok and inout_ok:
                # add more seq in the minibatch
                b += 1
            else:
                # no more seq in the minibatch
                break
        end = min(length, start + b)
        batch = sorted_data[start:end]
        if shortest_first:
            batch.reverse()
        minibatches.append(batch)
        # Check for min_batch_size and fixes the batches if needed
        i = -1
        while len(minibatches[i]) < min_batch_size:
            missing = min_batch_size - len(minibatches[i])
            if -i == len(minibatches):
                minibatches[i + 1].extend(minibatches[i])
                minibatches = minibatches[1:]
                break
            else:
                minibatches[i].extend(minibatches[i - 1][:missing])
                minibatches[i - 1] = minibatches[i - 1][missing:]
                i -= 1
        start = end
    if num_batches > 0:
        minibatches = minibatches[:num_batches]
    lengths = [len(x) for x in minibatches]
    logger.info(
        str(len(minibatches)) + " batches containing from " + str(min(lengths))
        + " to " + str(max(lengths)) + " samples" + "(avg " + str(
            int(np.mean(lengths))) + " samples).")

    return minibatches


def batchfy_shuffle(data, batch_size, min_batch_size, num_batches,
                    shortest_first):
    import random

    logger.info("use shuffled batch.")
    sorted_data = random.sample(data.items(), len(data.items()))
    logger.info("# utts: " + str(len(sorted_data)))
    # make list of minibatches
    minibatches = []
    start = 0
    while True:
        end = min(len(sorted_data), start + batch_size)
        # check each batch is more than minimum batchsize
        minibatch = sorted_data[start:end]
        if shortest_first:
            minibatch.reverse()
        if len(minibatch) < min_batch_size:
            mod = min_batch_size - len(minibatch) % min_batch_size
            additional_minibatch = [
                sorted_data[i] for i in np.random.randint(0, start, mod)
            ]
            if shortest_first:
                additional_minibatch.reverse()
            minibatch.extend(additional_minibatch)
        minibatches.append(minibatch)
        if end == len(sorted_data):
            break
        start = end

    # for debugging
    if num_batches > 0:
        minibatches = minibatches[:num_batches]
        logger.info("# minibatches: " + str(len(minibatches)))
    return minibatches


BATCH_COUNT_CHOICES = ["auto", "seq", "bin", "frame"]
BATCH_SORT_KEY_CHOICES = ["input", "output", "shuffle"]


def make_batchset(
        data,
        batch_size=0,
        max_length_in=float("inf"),
        max_length_out=float("inf"),
        num_batches=0,
        min_batch_size=1,
        shortest_first=False,
        batch_sort_key="input",
        count="auto",
        batch_bins=0,
        batch_frames_in=0,
        batch_frames_out=0,
        batch_frames_inout=0,
        iaxis=0,
        oaxis=0, ):
    """Make batch set from json dictionary

    if utts have "category" value,

        >>> data = [{'category': 'A', 'input': ..., 'utt':'utt1'},
        ...         {'category': 'B', 'input': ..., 'utt':'utt2'},
        ...         {'category': 'B', 'input': ..., 'utt':'utt3'},
        ...         {'category': 'A', 'input': ..., 'utt':'utt4'}]
        >>> make_batchset(data, batchsize=2, ...)
        [[('utt1', ...), ('utt4', ...)], [('utt2', ...), ('utt3': ...)]]

    Note that if any utts doesn't have "category",
    perform as same as batchfy_by_{count}

    :param List[Dict[str, Any]] data: dictionary loaded from data.json
    :param int batch_size: maximum number of sequences in a minibatch.
    :param int batch_bins: maximum number of bins (frames x dim) in a minibatch.
    :param int batch_frames_in:  maximum number of input frames in a minibatch.
    :param int batch_frames_out: maximum number of output frames in a minibatch.
    :param int batch_frames_out: maximum number of input+output frames in a minibatch.
    :param str count: strategy to count maximum size of batch.
        For choices, see io.batchfy.BATCH_COUNT_CHOICES

    :param int max_length_in: maximum length of input to decide adaptive batch size
    :param int max_length_out: maximum length of output to decide adaptive batch size
    :param int num_batches: # number of batches to use (for debug)
    :param int min_batch_size: minimum batch size (for multi-gpu)
    :param bool shortest_first: Sort from batch with shortest samples
        to longest if true, otherwise reverse
    :param str batch_sort_key: how to sort data before creating minibatches
        ["input", "output", "shuffle"]
    :param bool swap_io: if True, use "input" as output and "output"
        as input in `data` dict
    :param bool mt: if True, use 0-axis of "output" as output and 1-axis of "output"
        as input in `data` dict
    :param int iaxis: dimension to access input
        (for ASR, TTS iaxis=0, for MT iaxis="1".)
    :param int oaxis: dimension to access output (for ASR, TTS, MT oaxis=0,
        reserved for future research, -1 means all axis.)
    :return: List[List[Tuple[str, dict]]] list of batches
    """
    # check args
    if count not in BATCH_COUNT_CHOICES:
        raise ValueError(
            f"arg 'count' ({count}) should be one of {BATCH_COUNT_CHOICES}")
    if batch_sort_key not in BATCH_SORT_KEY_CHOICES:
        raise ValueError(f"arg 'batch_sort_key' ({batch_sort_key}) should be "
                         f"one of {BATCH_SORT_KEY_CHOICES}")

    ikey = "input"
    okey = "output"
    batch_sort_axis = 0  # index of list 
    if count == "auto":
        if batch_size != 0:
            count = "seq"
        elif batch_bins != 0:
            count = "bin"
        elif batch_frames_in != 0 or batch_frames_out != 0 or batch_frames_inout != 0:
            count = "frame"
        else:
            raise ValueError(
                f"cannot detect `count` manually set one of {BATCH_COUNT_CHOICES}"
            )
        logger.info(f"count is auto detected as {count}")

    if count != "seq" and batch_sort_key == "shuffle":
        raise ValueError(
            "batch_sort_key=shuffle is only available if batch_count=seq")

    category2data = {}  # Dict[str, dict]
    for v in data:
        k = v['utt']
        category2data.setdefault(v.get("category"), {})[k] = v

    batches_list = []  # List[List[List[Tuple[str, dict]]]]
    for d in category2data.values():
        if batch_sort_key == "shuffle":
            batches = batchfy_shuffle(d, batch_size, min_batch_size,
                                      num_batches, shortest_first)
            batches_list.append(batches)
            continue

        # sort it by input lengths (long to short)
        sorted_data = sorted(
            d.items(),
            key=lambda data: int(data[1][batch_sort_key][batch_sort_axis]["shape"][0]),
            reverse=not shortest_first, )
        logger.info("# utts: " + str(len(sorted_data)))

        if count == "seq":
            batches = batchfy_by_seq(
                sorted_data,
                batch_size=batch_size,
                max_length_in=max_length_in,
                max_length_out=max_length_out,
                min_batch_size=min_batch_size,
                shortest_first=shortest_first,
                ikey=ikey,
                iaxis=iaxis,
                okey=okey,
                oaxis=oaxis, )
        if count == "bin":
            batches = batchfy_by_bin(
                sorted_data,
                batch_bins=batch_bins,
                min_batch_size=min_batch_size,
                shortest_first=shortest_first,
                ikey=ikey,
                okey=okey, )
        if count == "frame":
            batches = batchfy_by_frame(
                sorted_data,
                max_frames_in=batch_frames_in,
                max_frames_out=batch_frames_out,
                max_frames_inout=batch_frames_inout,
                min_batch_size=min_batch_size,
                shortest_first=shortest_first,
                ikey=ikey,
                okey=okey, )
        batches_list.append(batches)

    if len(batches_list) == 1:
        batches = batches_list[0]
    else:
        # Concat list. This way is faster than "sum(batch_list, [])"
        batches = list(itertools.chain(*batches_list))

    # for debugging
    if num_batches > 0:
        batches = batches[:num_batches]
    logger.info("# minibatches: " + str(len(batches)))

    # batch: List[List[Tuple[str, dict]]]
    return batches
add batchfy 3 years ago			`# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.`
			`#`
			`# Licensed under the Apache License, Version 2.0 (the "License");`
			`# you may not use this file except in compliance with the License.`
			`# You may obtain a copy of the License at`
			`#`
			`# http://www.apache.org/licenses/LICENSE-2.0`
			`#`
			`# Unless required by applicable law or agreed to in writing, software`
			`# distributed under the License is distributed on an "AS IS" BASIS,`
			`# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`# See the License for the specific language governing permissions and`
			`# limitations under the License.`
fix reference format 3 years ago			`# Modified from espnet(https://github.com/espnet/espnet)`
add batchfy 3 years ago			`import itertools`

			`import numpy as np`

merge deepspeech, parakeet and text_processing into paddlespeech 3 years ago			`from paddlespeech.s2t.utils.log import Log`
add batchfy 3 years ago
			`__all__ = ["make_batchset"]`

			`logger = Log(__name__).getlog()`


			`def batchfy_by_seq(`
			`sorted_data,`
			`batch_size,`
			`max_length_in,`
			`max_length_out,`
			`min_batch_size=1,`
			`shortest_first=False,`
			`ikey="input",`
			`iaxis=0,`
			`okey="output",`
			`oaxis=0, ):`
			`"""Make batch set from json dictionary`

			`:param List[(str, Dict[str, Any])] sorted_data: dictionary loaded from data.json`
			`:param int batch_size: batch size`
			`:param int max_length_in: maximum length of input to decide adaptive batch size`
			`:param int max_length_out: maximum length of output to decide adaptive batch size`
			`:param int min_batch_size: mininum batch size (for multi-gpu)`
			`:param bool shortest_first: Sort from batch with shortest samples`
			`to longest if true, otherwise reverse`
			`:param str ikey: key to access input`
			`(for ASR ikey="input", for TTS, MT ikey="output".)`
			`:param int iaxis: dimension to access input`
			`(for ASR, TTS iaxis=0, for MT iaxis="1".)`
			`:param str okey: key to access output`
			`(for ASR, MT okey="output". for TTS okey="input".)`
			`:param int oaxis: dimension to access output`
			`(for ASR, TTS, MT oaxis=0, reserved for future research, -1 means all axis.)`
			`:return: List[List[Tuple[str, dict]]] list of batches`
			`"""`
			`if batch_size <= 0:`
			`raise ValueError(f"Invalid batch_size={batch_size}")`

			`# check #utts is more than min_batch_size`
			`if len(sorted_data) < min_batch_size:`
			`raise ValueError(`
			`f"#utts({len(sorted_data)}) is less than min_batch_size({min_batch_size})."`
			`)`

			`# make list of minibatches`
			`minibatches = []`
			`start = 0`
			`while True:`
			`_, info = sorted_data[start]`
			`ilen = int(info[ikey][iaxis]["shape"][0])`
			`olen = (int(info[okey][oaxis]["shape"][0]) if oaxis >= 0 else`
			`max(map(lambda x: int(x["shape"][0]), info[okey])))`
			`factor = max(int(ilen / max_length_in), int(olen / max_length_out))`
			`# change batchsize depending on the input and output length`
			`# if ilen = 1000 and max_length_in = 800`
			`# then b = batchsize / 2`
			`# and max(min_batches, .) avoids batchsize = 0`
			`bs = max(min_batch_size, int(batch_size / (1 + factor)))`
			`end = min(len(sorted_data), start + bs)`
			`minibatch = sorted_data[start:end]`
			`if shortest_first:`
			`minibatch.reverse()`

			`# check each batch is more than minimum batchsize`
			`if len(minibatch) < min_batch_size:`
			`mod = min_batch_size - len(minibatch) % min_batch_size`
			`additional_minibatch = [`
			`sorted_data[i] for i in np.random.randint(0, start, mod)`
			`]`
			`if shortest_first:`
			`additional_minibatch.reverse()`
			`minibatch.extend(additional_minibatch)`
			`minibatches.append(minibatch)`

			`if end == len(sorted_data):`
			`break`
			`start = end`

			`# batch: List[List[Tuple[str, dict]]]`
			`return minibatches`


			`def batchfy_by_bin(`
			`sorted_data,`
			`batch_bins,`
			`num_batches=0,`
			`min_batch_size=1,`
			`shortest_first=False,`
			`ikey="input",`
			`okey="output", ):`
			`"""Make variably sized batch set, which maximizes`

			the number of bins up to `batch_bins`.

			`:param List[(str, Dict[str, Any])] sorted_data: dictionary loaded from data.json`
			`:param int batch_bins: Maximum frames of a batch`
			`:param int num_batches: # number of batches to use (for debug)`
			`:param int min_batch_size: minimum batch size (for multi-gpu)`
			:param int test: Return only every `test` batches
			`:param bool shortest_first: Sort from batch with shortest samples`
			`to longest if true, otherwise reverse`

			`:param str ikey: key to access input (for ASR ikey="input", for TTS ikey="output".)`
			`:param str okey: key to access output (for ASR okey="output". for TTS okey="input".)`

			`:return: List[Tuple[str, Dict[str, List[Dict[str, Any]]]] list of batches`
			`"""`
			`if batch_bins <= 0:`
			`raise ValueError(f"invalid batch_bins={batch_bins}")`
			`length = len(sorted_data)`
			`idim = int(sorted_data[0][1][ikey][0]["shape"][1])`
			`odim = int(sorted_data[0][1][okey][0]["shape"][1])`
			`logger.info("# utts: " + str(len(sorted_data)))`
			`minibatches = []`
			`start = 0`
			`n = 0`
			`while True:`
			`# Dynamic batch size depending on size of samples`
			`b = 0`
			`next_size = 0`
			`max_olen = 0`
			`while next_size < batch_bins and (start + b) < length:`
			`ilen = int(sorted_data[start + b][1][ikey][0]["shape"][0]) * idim`
			`olen = int(sorted_data[start + b][1][okey][0]["shape"][0]) * odim`
			`if olen > max_olen:`
			`max_olen = olen`
			`next_size = (max_olen + ilen) * (b + 1)`
			`if next_size <= batch_bins:`
			`b += 1`
			`elif next_size == 0:`
			`raise ValueError(`
			`f"Can't fit one sample in batch_bins ({batch_bins}): "`
			`f"Please increase the value")`
			`end = min(length, start + max(min_batch_size, b))`
			`batch = sorted_data[start:end]`
			`if shortest_first:`
			`batch.reverse()`
			`minibatches.append(batch)`
			`# Check for min_batch_size and fixes the batches if needed`
			`i = -1`
			`while len(minibatches[i]) < min_batch_size:`
			`missing = min_batch_size - len(minibatches[i])`
			`if -i == len(minibatches):`
			`minibatches[i + 1].extend(minibatches[i])`
			`minibatches = minibatches[1:]`
			`break`
			`else:`
			`minibatches[i].extend(minibatches[i - 1][:missing])`
			`minibatches[i - 1] = minibatches[i - 1][missing:]`
			`i -= 1`
			`if end == length:`
			`break`
			`start = end`
			`n += 1`
			`if num_batches > 0:`
			`minibatches = minibatches[:num_batches]`
			`lengths = [len(x) for x in minibatches]`
			`logger.info(`
			`str(len(minibatches)) + " batches containing from " + str(min(lengths))`
			`+ " to " + str(max(lengths)) + " samples " + "(avg " + str(`
			`int(np.mean(lengths))) + " samples).")`
			`return minibatches`


			`def batchfy_by_frame(`
			`sorted_data,`
			`max_frames_in,`
			`max_frames_out,`
			`max_frames_inout,`
			`num_batches=0,`
			`min_batch_size=1,`
			`shortest_first=False,`
			`ikey="input",`
			`okey="output", ):`
			`"""Make variable batch set, which maximizes the number of frames to max_batch_frame.`

			`:param List[(str, Dict[str, Any])] sorteddata: dictionary loaded from data.json`
			`:param int max_frames_in: Maximum input frames of a batch`
			`:param int max_frames_out: Maximum output frames of a batch`
			`:param int max_frames_inout: Maximum input+output frames of a batch`
			`:param int num_batches: # number of batches to use (for debug)`
			`:param int min_batch_size: minimum batch size (for multi-gpu)`
			:param int test: Return only every `test` batches
			`:param bool shortest_first: Sort from batch with shortest samples`
			`to longest if true, otherwise reverse`

			`:param str ikey: key to access input (for ASR ikey="input", for TTS ikey="output".)`
			`:param str okey: key to access output (for ASR okey="output". for TTS okey="input".)`

			`:return: List[Tuple[str, Dict[str, List[Dict[str, Any]]]] list of batches`
			`"""`
			`if max_frames_in <= 0 and max_frames_out <= 0 and max_frames_inout <= 0:`
			`raise ValueError(`
			"At least, one of `--batch-frames-in`, `--batch-frames-out` or "
			"`--batch-frames-inout` should be > 0")
			`length = len(sorted_data)`
			`minibatches = []`
			`start = 0`
			`end = 0`
			`while end != length:`
			`# Dynamic batch size depending on size of samples`
			`b = 0`
			`max_olen = 0`
			`max_ilen = 0`
			`while (start + b) < length:`
			`ilen = int(sorted_data[start + b][1][ikey][0]["shape"][0])`
			`if ilen > max_frames_in and max_frames_in != 0:`
			`raise ValueError(`
			`f"Can't fit one sample in --batch-frames-in ({max_frames_in}): "`
			`f"Please increase the value")`
			`olen = int(sorted_data[start + b][1][okey][0]["shape"][0])`
			`if olen > max_frames_out and max_frames_out != 0:`
			`raise ValueError(`
			`f"Can't fit one sample in --batch-frames-out ({max_frames_out}): "`
			`f"Please increase the value")`
			`if ilen + olen > max_frames_inout and max_frames_inout != 0:`
			`raise ValueError(`
			`f"Can't fit one sample in --batch-frames-out ({max_frames_inout}): "`
			`f"Please increase the value")`
			`max_olen = max(max_olen, olen)`
			`max_ilen = max(max_ilen, ilen)`
			`in_ok = max_ilen * (b + 1) <= max_frames_in or max_frames_in == 0`
			`out_ok = max_olen * (b + 1) <= max_frames_out or max_frames_out == 0`
			`inout_ok = (max_ilen + max_olen) * (`
			`b + 1) <= max_frames_inout or max_frames_inout == 0`
			`if in_ok and out_ok and inout_ok:`
			`# add more seq in the minibatch`
			`b += 1`
			`else:`
			`# no more seq in the minibatch`
			`break`
			`end = min(length, start + b)`
			`batch = sorted_data[start:end]`
			`if shortest_first:`
			`batch.reverse()`
			`minibatches.append(batch)`
			`# Check for min_batch_size and fixes the batches if needed`
			`i = -1`
			`while len(minibatches[i]) < min_batch_size:`
			`missing = min_batch_size - len(minibatches[i])`
			`if -i == len(minibatches):`
			`minibatches[i + 1].extend(minibatches[i])`
			`minibatches = minibatches[1:]`
			`break`
			`else:`
			`minibatches[i].extend(minibatches[i - 1][:missing])`
			`minibatches[i - 1] = minibatches[i - 1][missing:]`
			`i -= 1`
			`start = end`
			`if num_batches > 0:`
			`minibatches = minibatches[:num_batches]`
			`lengths = [len(x) for x in minibatches]`
			`logger.info(`
			`str(len(minibatches)) + " batches containing from " + str(min(lengths))`
			`+ " to " + str(max(lengths)) + " samples" + "(avg " + str(`
			`int(np.mean(lengths))) + " samples).")`

			`return minibatches`


			`def batchfy_shuffle(data, batch_size, min_batch_size, num_batches,`
			`shortest_first):`
			`import random`

			`logger.info("use shuffled batch.")`
			`sorted_data = random.sample(data.items(), len(data.items()))`
			`logger.info("# utts: " + str(len(sorted_data)))`
			`# make list of minibatches`
			`minibatches = []`
			`start = 0`
			`while True:`
			`end = min(len(sorted_data), start + batch_size)`
			`# check each batch is more than minimum batchsize`
			`minibatch = sorted_data[start:end]`
			`if shortest_first:`
			`minibatch.reverse()`
			`if len(minibatch) < min_batch_size:`
			`mod = min_batch_size - len(minibatch) % min_batch_size`
			`additional_minibatch = [`
			`sorted_data[i] for i in np.random.randint(0, start, mod)`
			`]`
			`if shortest_first:`
			`additional_minibatch.reverse()`
			`minibatch.extend(additional_minibatch)`
			`minibatches.append(minibatch)`
			`if end == len(sorted_data):`
			`break`
			`start = end`

			`# for debugging`
			`if num_batches > 0:`
			`minibatches = minibatches[:num_batches]`
			`logger.info("# minibatches: " + str(len(minibatches)))`
			`return minibatches`


			`BATCH_COUNT_CHOICES = ["auto", "seq", "bin", "frame"]`
			`BATCH_SORT_KEY_CHOICES = ["input", "output", "shuffle"]`


			`def make_batchset(`
			`data,`
			`batch_size=0,`
			`max_length_in=float("inf"),`
			`max_length_out=float("inf"),`
			`num_batches=0,`
			`min_batch_size=1,`
			`shortest_first=False,`
			`batch_sort_key="input",`
			`count="auto",`
			`batch_bins=0,`
			`batch_frames_in=0,`
			`batch_frames_out=0,`
			`batch_frames_inout=0,`
			`iaxis=0,`
			`oaxis=0, ):`
			`"""Make batch set from json dictionary`

			`if utts have "category" value,`

fix docstring 3 years ago			`>>> data = [{'category': 'A', 'input': ..., 'utt':'utt1'},`
			`... {'category': 'B', 'input': ..., 'utt':'utt2'},`
			`... {'category': 'B', 'input': ..., 'utt':'utt3'},`
			`... {'category': 'A', 'input': ..., 'utt':'utt4'}]`
add batchfy 3 years ago			`>>> make_batchset(data, batchsize=2, ...)`
			`[[('utt1', ...), ('utt4', ...)], [('utt2', ...), ('utt3': ...)]]`

			`Note that if any utts doesn't have "category",`
			`perform as same as batchfy_by_{count}`

fix io; add test 3 years ago			`:param List[Dict[str, Any]] data: dictionary loaded from data.json`
add batchfy 3 years ago			`:param int batch_size: maximum number of sequences in a minibatch.`
			`:param int batch_bins: maximum number of bins (frames x dim) in a minibatch.`
			`:param int batch_frames_in: maximum number of input frames in a minibatch.`
			`:param int batch_frames_out: maximum number of output frames in a minibatch.`
			`:param int batch_frames_out: maximum number of input+output frames in a minibatch.`
			`:param str count: strategy to count maximum size of batch.`
add beam search with scorers 3 years ago			`For choices, see io.batchfy.BATCH_COUNT_CHOICES`
add batchfy 3 years ago
			`:param int max_length_in: maximum length of input to decide adaptive batch size`
			`:param int max_length_out: maximum length of output to decide adaptive batch size`
			`:param int num_batches: # number of batches to use (for debug)`
			`:param int min_batch_size: minimum batch size (for multi-gpu)`
			`:param bool shortest_first: Sort from batch with shortest samples`
			`to longest if true, otherwise reverse`
			`:param str batch_sort_key: how to sort data before creating minibatches`
			`["input", "output", "shuffle"]`
			`:param bool swap_io: if True, use "input" as output and "output"`
			as input in `data` dict
			`:param bool mt: if True, use 0-axis of "output" as output and 1-axis of "output"`
			as input in `data` dict
			`:param int iaxis: dimension to access input`
			`(for ASR, TTS iaxis=0, for MT iaxis="1".)`
			`:param int oaxis: dimension to access output (for ASR, TTS, MT oaxis=0,`
			`reserved for future research, -1 means all axis.)`
			`:return: List[List[Tuple[str, dict]]] list of batches`
			`"""`
			`# check args`
			`if count not in BATCH_COUNT_CHOICES:`
			`raise ValueError(`
			`f"arg 'count' ({count}) should be one of {BATCH_COUNT_CHOICES}")`
			`if batch_sort_key not in BATCH_SORT_KEY_CHOICES:`
			`raise ValueError(f"arg 'batch_sort_key' ({batch_sort_key}) should be "`
			`f"one of {BATCH_SORT_KEY_CHOICES}")`

			`ikey = "input"`
			`okey = "output"`
			`batch_sort_axis = 0 # index of list`
			`if count == "auto":`
			`if batch_size != 0:`
			`count = "seq"`
			`elif batch_bins != 0:`
			`count = "bin"`
			`elif batch_frames_in != 0 or batch_frames_out != 0 or batch_frames_inout != 0:`
			`count = "frame"`
			`else:`
			`raise ValueError(`
			f"cannot detect `count` manually set one of {BATCH_COUNT_CHOICES}"
			`)`
			`logger.info(f"count is auto detected as {count}")`

			`if count != "seq" and batch_sort_key == "shuffle":`
			`raise ValueError(`
			`"batch_sort_key=shuffle is only available if batch_count=seq")`

			`category2data = {} # Dict[str, dict]`
fix io; add test 3 years ago			`for v in data:`
			`k = v['utt']`
add batchfy 3 years ago			`category2data.setdefault(v.get("category"), {})[k] = v`

			`batches_list = [] # List[List[List[Tuple[str, dict]]]]`
			`for d in category2data.values():`
			`if batch_sort_key == "shuffle":`
			`batches = batchfy_shuffle(d, batch_size, min_batch_size,`
			`num_batches, shortest_first)`
			`batches_list.append(batches)`
			`continue`

			`# sort it by input lengths (long to short)`
			`sorted_data = sorted(`
			`d.items(),`
			`key=lambda data: int(data[1][batch_sort_key][batch_sort_axis]["shape"][0]),`
			`reverse=not shortest_first, )`
			`logger.info("# utts: " + str(len(sorted_data)))`
fix dataloader 3 years ago
add batchfy 3 years ago			`if count == "seq":`
			`batches = batchfy_by_seq(`
			`sorted_data,`
			`batch_size=batch_size,`
			`max_length_in=max_length_in,`
			`max_length_out=max_length_out,`
			`min_batch_size=min_batch_size,`
			`shortest_first=shortest_first,`
			`ikey=ikey,`
			`iaxis=iaxis,`
			`okey=okey,`
			`oaxis=oaxis, )`
			`if count == "bin":`
			`batches = batchfy_by_bin(`
			`sorted_data,`
			`batch_bins=batch_bins,`
			`min_batch_size=min_batch_size,`
			`shortest_first=shortest_first,`
			`ikey=ikey,`
			`okey=okey, )`
			`if count == "frame":`
			`batches = batchfy_by_frame(`
			`sorted_data,`
			`max_frames_in=batch_frames_in,`
			`max_frames_out=batch_frames_out,`
			`max_frames_inout=batch_frames_inout,`
			`min_batch_size=min_batch_size,`
			`shortest_first=shortest_first,`
			`ikey=ikey,`
			`okey=okey, )`
			`batches_list.append(batches)`

			`if len(batches_list) == 1:`
			`batches = batches_list[0]`
			`else:`
			`# Concat list. This way is faster than "sum(batch_list, [])"`
			`batches = list(itertools.chain(*batches_list))`

			`# for debugging`
			`if num_batches > 0:`
			`batches = batches[:num_batches]`
			`logger.info("# minibatches: " + str(len(batches)))`

			`# batch: List[List[Tuple[str, dict]]]`
fix dataloader 3 years ago			`return batches`