# Copyright 2020-2021 Huawei Technologies Co., Ltd
#
# 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.
"""
The module text.transforms is inherited from _c_dataengine
and is implemented based on ICU4C and cppjieba in C++.
It's a high performance module to process NLP text.
Users can use Vocab to build their own dictionary,
use appropriate tokenizers to split sentences into different tokens,
and use Lookup to find the index of tokens in Vocab.
.. Note::
A constructor's arguments for every class in this module must be saved into the
class attributes (self.xxx) to support save() and load().
Examples:
>>> text_file_dataset_dir = ["/path/to/text_file_dataset_file"] # contains 1 or multiple text files
>>> # Create a dataset for text sentences saved as line data in a file
>>> text_file_dataset = ds.TextFileDataset(dataset_files=text_file_dataset_dir, shuffle=False)
>>> # Tokenize sentences to unicode characters
>>> tokenizer = text.UnicodeCharTokenizer()
>>> # Load vocabulary from list
>>> vocab = text.Vocab.from_list(word_list=['深', '圳', '欢', '迎', '您'])
>>> # Use Lookup operator to map tokens to ids
>>> lookup = text.Lookup(vocab=vocab)
>>> text_file_dataset = text_file_dataset.map(operations=[tokenizer, lookup])
>>> # if text line in dataset_file is:
>>> # 深圳欢迎您
>>> # then the output will be:
>>> # {'text': array([0, 1, 2, 3, 4], dtype=int32)}
"""
import os
import re
import platform
import numpy as np
import mindspore._c_dataengine as cde
from mindspore import dtype as mstype
from .utils import JiebaMode, NormalizeForm, to_str, SPieceTokenizerOutType, SPieceTokenizerLoadType
from .validators import check_lookup, check_jieba_add_dict, \
check_jieba_add_word, check_jieba_init, check_with_offsets, check_unicode_script_tokenizer, \
check_wordpiece_tokenizer, check_regex_replace, check_regex_tokenizer, check_basic_tokenizer, check_ngram, \
check_pair_truncate, check_to_number, check_bert_tokenizer, check_python_tokenizer, check_slidingwindow, \
check_sentence_piece_tokenizer
from ..core.datatypes import mstype_to_detype
from ..core.validator_helpers import replace_none
from ..transforms.c_transforms import TensorOperation
class TextTensorOperation(TensorOperation):
"""
Base class of Text Tensor Ops
"""
def parse(self):
raise NotImplementedError("TextTensorOperation has to implement parse() method.")
DE_C_INTER_JIEBA_MODE = {
JiebaMode.MIX: cde.JiebaMode.DE_JIEBA_MIX,
JiebaMode.MP: cde.JiebaMode.DE_JIEBA_MP,
JiebaMode.HMM: cde.JiebaMode.DE_JIEBA_HMM
}
DE_C_INTER_SENTENCEPIECE_LOADTYPE = {
SPieceTokenizerLoadType.FILE: cde.SPieceTokenizerLoadType.DE_SPIECE_TOKENIZER_LOAD_KFILE,
SPieceTokenizerLoadType.MODEL: cde.SPieceTokenizerLoadType.DE_SPIECE_TOKENIZER_LOAD_KMODEL
}
DE_C_INTER_SENTENCEPIECE_OUTTYPE = {
SPieceTokenizerOutType.STRING: cde.SPieceTokenizerOutType.DE_SPIECE_TOKENIZER_OUTTYPE_KString,
SPieceTokenizerOutType.INT: cde.SPieceTokenizerOutType.DE_SPIECE_TOKENIZER_OUTTYPE_KINT
}
[docs]class JiebaTokenizer(TextTensorOperation):
"""
Tokenize Chinese string into words based on dictionary.
Note:
The integrity of the HMMSEgment algorithm and MPSegment algorithm files must be confirmed.
Args:
hmm_path (str): Dictionary file is used by HMMSegment algorithm.
The dictionary can be obtained on the official website of cppjieba.
mp_path (str): Dictionary file is used by MPSegment algorithm.
The dictionary can be obtained on the official website of cppjieba.
mode (JiebaMode, optional): Valid values can be any of [JiebaMode.MP, JiebaMode.HMM,
JiebaMode.MIX](default=JiebaMode.MIX).
- JiebaMode.MP, tokenize with MPSegment algorithm.
- JiebaMode.HMM, tokenize with Hidden Markov Model Segment algorithm.
- JiebaMode.MIX, tokenize with a mix of MPSegment and HMMSegment algorithm.
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> from mindspore.dataset.text import JiebaMode
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> jieba_hmm_file = "/path/to/jieba/hmm/file"
>>> jieba_mp_file = "/path/to/jieba/mp/file"
>>> tokenizer_op = text.JiebaTokenizer(jieba_hmm_file, jieba_mp_file, mode=JiebaMode.MP, with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=False, then output three columns {["token", dtype=str], ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.JiebaTokenizer(jieba_hmm_file, jieba_mp_file, mode=JiebaMode.MP, with_offsets=True)
>>> text_file_dataset_1 = text_file_dataset_1.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start", "offsets_limit"],
... column_order=["token", "offsets_start", "offsets_limit"])
"""
@check_jieba_init
def __init__(self, hmm_path, mp_path, mode=JiebaMode.MIX, with_offsets=False):
if not isinstance(mode, JiebaMode):
raise TypeError("Wrong input type for mode, should be JiebaMode.")
self.mode = mode
self.__check_path__(hmm_path)
self.hmm_path = hmm_path
self.__check_path__(mp_path)
self.mp_path = mp_path
self.with_offsets = with_offsets
self.words = []
def parse(self):
jieba_tokenizer = cde.JiebaTokenizerOperation(self.hmm_path, self.mp_path,
DE_C_INTER_JIEBA_MODE[self.mode],
self.with_offsets)
for word in self.words:
jieba_tokenizer.add_word(word[0], word[1])
return jieba_tokenizer
[docs] @check_jieba_add_word
def add_word(self, word, freq=None):
"""
Add a user defined word to JiebaTokenizer's dictionary.
Args:
word (str): The word to be added to the JiebaTokenizer instance.
The added word will not be written into the built-in dictionary on disk.
freq (int, optional): The frequency of the word to be added. The higher the frequency,
the better chance the word will be tokenized (default=None, use default frequency).
Examples:
>>> from mindspore.dataset.text import JiebaMode
>>> jieba_hmm_file = "/path/to/jieba/hmm/file"
>>> jieba_mp_file = "/path/to/jieba/mp/file"
>>> jieba_op = text.JiebaTokenizer(jieba_hmm_file, jieba_mp_file, mode=JiebaMode.MP)
>>> sentence_piece_vocab_file = "/path/to/sentence/piece/vocab/file"
>>> with open(sentence_piece_vocab_file, 'r') as f:
... for line in f:
... word = line.split(',')[0]
... jieba_op.add_word(word)
>>> text_file_dataset = text_file_dataset.map(operations=jieba_op, input_columns=["text"])
"""
if freq is None:
self.words.append((word, 0))
else:
self.words.append((word, freq))
[docs] @check_jieba_add_dict
def add_dict(self, user_dict):
"""
Add a user defined word to JiebaTokenizer's dictionary.
Args:
user_dict (Union[str, dict]): One of the two loading methods is file path(str) loading
(according to the Jieba dictionary format) and the other is Python dictionary(dict) loading,
Python Dict format: {word1:freq1, word2:freq2,...}.
Jieba dictionary format : word(required), freq(optional), such as:
.. code-block::
word1 freq1
word2 None
word3 freq3
Only valid word-freq pairs in user provided file will be added into the dictionary.
Rows containing invalid input will be ignored. No error nor warning Status is returned.
Examples:
>>> from mindspore.dataset.text import JiebaMode
>>> jieba_hmm_file = "/path/to/jieba/hmm/file"
>>> jieba_mp_file = "/path/to/jieba/mp/file"
>>> user_dict = {"男默女泪": 10}
>>> jieba_op = text.JiebaTokenizer(jieba_hmm_file, jieba_mp_file, mode=JiebaMode.MP)
>>> jieba_op.add_dict(user_dict)
>>> text_file_dataset = text_file_dataset.map(operations=jieba_op, input_columns=["text"])
"""
if isinstance(user_dict, str):
self.__add_dict_py_file(user_dict)
elif isinstance(user_dict, dict):
for k, v in user_dict.items():
self.add_word(k, v)
else:
raise TypeError("The type of user_dict must str or dict.")
def __add_dict_py_file(self, file_path):
"""Add user defined word by file"""
words_list = self.__parser_file(file_path)
for data in words_list:
if data[1] is None:
freq = 0
else:
freq = int(data[1])
self.add_word(data[0], freq)
def __parser_file(self, file_path):
"""parser user defined word by file"""
if not os.path.exists(file_path):
raise ValueError(
"user dict file {} is not exist.".format(file_path))
real_file_path = os.path.realpath(file_path)
file_dict = open(real_file_path)
data_re = re.compile('^\\s*([^\\s*]+?)\\s*([0-9]+)?\\s*$', re.U)
words_list = []
for item in file_dict:
data = item.strip()
if not isinstance(data, str):
data = self.__decode(data)
tmp = data_re.match(data)
if not tmp:
continue
words = tmp.groups()
words_list.append(words)
file_dict.close()
return words_list
def __decode(self, data):
"""decode the dict file to utf8"""
try:
data = data.decode('utf-8')
except UnicodeDecodeError:
raise ValueError("user dict file must be utf8 format.")
return data.lstrip('\ufeff')
def __check_path__(self, model_path):
"""check model path"""
if not os.path.exists(os.path.realpath(model_path)):
raise ValueError(
" jieba mode file {} is not exist.".format(model_path))
[docs]class Lookup(TextTensorOperation):
"""
Look up a word into an id according to the input vocabulary table.
Args:
vocab (Vocab): A vocabulary object.
unknown_token (str, optional): Word is used for lookup. In case of the word is out of vocabulary (OOV),
the result of lookup will be replaced with unknown_token. If the unknown_token is not specified or
it is OOV, runtime error will be thrown (default={}, means no unknown_token is specified).
data_type (mindspore.dtype, optional): The data type that lookup operation maps
string to(default=mindspore.int32).
Examples:
>>> # Load vocabulary from list
>>> vocab = text.Vocab.from_list(['深', '圳', '欢', '迎', '您'])
>>> # Use Lookup operator to map tokens to ids
>>> lookup = text.Lookup(vocab)
>>> text_file_dataset = text_file_dataset.map(operations=[lookup])
"""
@check_lookup
def __init__(self, vocab, unknown_token=None, data_type=mstype.int32):
self.vocab = vocab
self.unknown_token = unknown_token
self.data_type = data_type
def parse(self):
return cde.LookupOperation(self.vocab, self.unknown_token, str(mstype_to_detype(self.data_type)))
[docs]class Ngram(TextTensorOperation):
"""
TensorOp to generate n-gram from a 1-D string Tensor.
Refer to https://en.wikipedia.org/wiki/N-gram#Examples for an overview of what n-gram is and how it works.
Args:
n (list[int]): n in n-gram, which is a list of positive integers. For example, if n=[4, 3], then the result
would be a 4-gram followed by a 3-gram in the same tensor. If the number of words is not enough to make up
for a n-gram, an empty string will be returned. For example, 3 grams on ["mindspore", "best"] will result in
an empty string produced.
left_pad (tuple, optional): Padding performed on left side of the sequence shaped like ("pad_token", pad_width).
`pad_width` will be capped at n-1. For example, specifying left_pad=("_", 2) would pad left side of the
sequence with "__" (default=None).
right_pad (tuple, optional): Padding performed on right side of the sequence shaped like
("pad_token", pad_width). `pad_width` will be capped at n-1. For example, specifying right_pad=("_", 2)
would pad right side of the sequence with "__" (default=None).
separator (str, optional): Symbol used to join strings together. For example. if 2-gram is
["mindspore", "amazing"] with separator="-", the result would be ["mindspore-amazing"]
(default=None, which will use whitespace as separator).
Examples:
>>> ngram_op = text.Ngram(3, separator="-")
>>> output = ngram_op(["WildRose Country", "Canada's Ocean Playground", "Land of Living Skies"])
>>> # output
>>> # ["WildRose Country-Canada's Ocean Playground-Land of Living Skies"]
>>> # same ngram_op called through map
>>> text_file_dataset = text_file_dataset.map(operations=ngram_op)
"""
@check_ngram
def __init__(self, n, left_pad=("", 0), right_pad=("", 0), separator=" "):
self.ngrams = n
self.left_pad = left_pad
self.right_pad = right_pad
self.separator = separator
def parse(self):
return cde.NgramOperation(self.ngrams, self.left_pad, self.right_pad, self.separator)
[docs]class SentencePieceTokenizer(TextTensorOperation):
"""
Tokenize scalar token or 1-D tokens to tokens by sentencepiece.
Args:
mode (Union[str, SentencePieceVocab]): If the input parameter is a file, then its type should be string.
If the input parameter is a SentencePieceVocab object, then its type should be SentencePieceVocab.
out_type (SPieceTokenizerOutType): The type of output, it can be any of [SPieceTokenizerOutType.STRING,
SPieceTokenizerOutType.INT].
- SPieceTokenizerOutType.STRING, means output type of SentencePice Tokenizer is string.
- SPieceTokenizerOutType.INT, means output type of SentencePice Tokenizer is int.
Examples:
>>> from mindspore.dataset.text import SentencePieceModel, SPieceTokenizerOutType
>>> sentence_piece_vocab_file = "/path/to/sentence/piece/vocab/file"
>>> vocab = text.SentencePieceVocab.from_file([sentence_piece_vocab_file], 5000, 0.9995,
... SentencePieceModel.UNIGRAM, {})
>>> tokenizer = text.SentencePieceTokenizer(vocab, out_type=SPieceTokenizerOutType.STRING)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer)
"""
@check_sentence_piece_tokenizer
def __init__(self, mode, out_type):
self.mode = mode
self.out_type = out_type
def parse(self):
return cde.SentencePieceTokenizerOperation(self.mode, DE_C_INTER_SENTENCEPIECE_OUTTYPE[self.out_type])
[docs]class SlidingWindow(TextTensorOperation):
"""
Construct a tensor from given data (only support 1-D for now), where each element in the dimension axis
is a slice of data starting at the corresponding position, with a specified width.
Args:
width (int): The width of the window. It must be an integer and greater than zero.
axis (int, optional): The axis along which the sliding window is computed (default=0).
Examples:
>>> dataset = ds.NumpySlicesDataset(data=[[1, 2, 3, 4, 5]], column_names="col1")
>>> # Data before
>>> # | col1 |
>>> # +--------------+
>>> # | [[1, 2, 3, 4, 5]] |
>>> # +--------------+
>>> dataset = dataset.map(operations=text.SlidingWindow(3, 0))
>>> # Data after
>>> # | col1 |
>>> # +--------------+
>>> # | [[1, 2, 3], |
>>> # | [2, 3, 4], |
>>> # | [3, 4, 5]] |
>>> # +--------------+
"""
@check_slidingwindow
def __init__(self, width, axis=0):
self.width = width
self.axis = axis
def parse(self):
return cde.SlidingWindowOperation(self.width, self.axis)
[docs]class ToNumber(TextTensorOperation):
"""
Tensor operation to convert every element of a string tensor to a number.
Strings are cast according to the rules specified in the following links, except that any strings which represent
negative numbers cannot be cast to an unsigned integer type, rules links are as follows:
https://en.cppreference.com/w/cpp/string/basic_string/stof,
https://en.cppreference.com/w/cpp/string/basic_string/stoul,
Args:
data_type (mindspore.dtype): Type to be cast to. Must be a numeric type in mindspore.dtype.
Raises:
RuntimeError: If strings are invalid to cast, or are out of range after being cast.
Examples:
>>> from mindspore import dtype as mstype
>>> data = [["1", "2", "3"]]
>>> dataset = ds.NumpySlicesDataset(data)
>>> to_number_op = text.ToNumber(mstype.int8)
>>> dataset = dataset.map(operations=to_number_op)
"""
@check_to_number
def __init__(self, data_type):
data_type = mstype_to_detype(data_type)
self.data_type = str(data_type)
def parse(self):
return cde.ToNumberOperation(self.data_type)
[docs]class TruncateSequencePair(TextTensorOperation):
"""
Truncate a pair of rank-1 tensors such that the total length is less than max_length.
This operation takes two input tensors and returns two output Tensors.
Args:
max_length (int): Maximum length required.
Examples:
>>> dataset = ds.NumpySlicesDataset(data={"col1": [[1, 2, 3]], "col2": [[4, 5]]})
>>> # Data before
>>> # | col1 | col2 |
>>> # +-----------+-----------|
>>> # | [1, 2, 3] | [4, 5] |
>>> # +-----------+-----------+
>>> truncate_sequence_pair_op = text.TruncateSequencePair(max_length=4)
>>> dataset = dataset.map(operations=truncate_sequence_pair_op)
>>> # Data after
>>> # | col1 | col2 |
>>> # +-----------+-----------+
>>> # | [1, 2] | [4, 5] |
>>> # +-----------+-----------+
"""
@check_pair_truncate
def __init__(self, max_length):
self.max_length = max_length
def parse(self):
return cde.TruncateSequencePairOperation(self.max_length)
[docs]class UnicodeCharTokenizer(TextTensorOperation):
"""
Tokenize a scalar tensor of UTF-8 string to Unicode characters.
Args:
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> tokenizer_op = text.UnicodeCharTokenizer(with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str], ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.UnicodeCharTokenizer(with_offsets=True)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start", "offsets_limit"],
... column_order=["token", "offsets_start", "offsets_limit"])
"""
@check_with_offsets
def __init__(self, with_offsets=False):
self.with_offsets = with_offsets
def parse(self):
return cde.UnicodeCharTokenizerOperation(self.with_offsets)
[docs]class WordpieceTokenizer(TextTensorOperation):
"""
Tokenize scalar token or 1-D tokens to 1-D subword tokens.
Args:
vocab (Vocab): A vocabulary object.
suffix_indicator (str, optional): Used to show that the subword is the last part of a word (default='##').
max_bytes_per_token (int, optional): Tokens exceeding this length will not be further split (default=100).
unknown_token (str, optional): When a token cannot be found: if 'unknown_token' is empty string,
return the token directly, else return 'unknown_token' (default='[UNK]').
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> vocab_list = ["book", "cholera", "era", "favor", "##ite", "my", "is", "love", "dur", "##ing", "the"]
>>> vocab = text.Vocab.from_list(vocab_list)
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> tokenizer_op = text.WordpieceTokenizer(vocab=vocab, unknown_token='[UNK]',
... max_bytes_per_token=100, with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str], ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.WordpieceTokenizer(vocab=vocab, unknown_token='[UNK]',
... max_bytes_per_token=100, with_offsets=True)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start", "offsets_limit"],
... column_order=["token", "offsets_start", "offsets_limit"])
"""
@check_wordpiece_tokenizer
def __init__(self, vocab, suffix_indicator='##', max_bytes_per_token=100,
unknown_token='[UNK]', with_offsets=False):
self.vocab = vocab
self.suffix_indicator = suffix_indicator
self.max_bytes_per_token = max_bytes_per_token
self.unknown_token = unknown_token
self.with_offsets = with_offsets
def parse(self):
return cde.WordpieceTokenizerOperation(self.vocab, self.suffix_indicator, self.max_bytes_per_token,
self.unknown_token, self.with_offsets)
[docs]class PythonTokenizer:
"""
Class that applies user-defined string tokenizer into input string.
Args:
tokenizer (Callable): Python function that takes a `str` and returns a list of `str` as tokens.
Examples:
>>> def my_tokenizer(line):
... return line.split()
>>> text_file_dataset = text_file_dataset.map(operations=text.PythonTokenizer(my_tokenizer))
"""
@check_python_tokenizer
def __init__(self, tokenizer):
self.pyfunc = tokenizer
self.tokenizer = np.vectorize(lambda x: np.array(tokenizer(x), dtype='U'), signature='()->(n)')
self.random = False
def __call__(self, in_array):
if not isinstance(in_array, np.ndarray):
raise TypeError("input should be a NumPy array. Got {}.".format(type(in_array)))
if in_array.dtype.type is np.bytes_:
in_array = to_str(in_array)
try:
tokens = self.tokenizer(in_array)
except Exception as e:
raise RuntimeError("Error occurred in Pyfunc [" + str(self.pyfunc.__name__) + "], error message: " + str(e))
return tokens
if platform.system().lower() != 'windows':
DE_C_INTER_NORMALIZE_FORM = {
NormalizeForm.NONE: cde.NormalizeForm.DE_NORMALIZE_NONE,
NormalizeForm.NFC: cde.NormalizeForm.DE_NORMALIZE_NFC,
NormalizeForm.NFKC: cde.NormalizeForm.DE_NORMALIZE_NFKC,
NormalizeForm.NFD: cde.NormalizeForm.DE_NORMALIZE_NFD,
NormalizeForm.NFKD: cde.NormalizeForm.DE_NORMALIZE_NFKD
}
[docs] class BasicTokenizer(TextTensorOperation):
"""
Tokenize a scalar tensor of UTF-8 string by specific rules.
Note:
BasicTokenizer is not supported on Windows platform yet.
Args:
lower_case (bool, optional): If True, apply CaseFold, NormalizeUTF8 with `NFD` mode, RegexReplace operation
on input text to fold the text to lower case and strip accents characters. If False, only apply
NormalizeUTF8 operation with the specified mode on input text (default=False).
keep_whitespace (bool, optional): If True, the whitespace will be kept in output tokens (default=False).
normalization_form (NormalizeForm, optional): Used to specify a specific normalize mode
(default=NormalizeForm.NONE). This is only effective when `lower_case` is False. It can be any of
[NormalizeForm.NONE, NormalizeForm.NFC, NormalizeForm.NFKC, NormalizeForm.NFD, NormalizeForm.NFKD].
- NormalizeForm.NONE, do nothing for input string tensor.
- NormalizeForm.NFC, normalize with Normalization Form C.
- NormalizeForm.NFKC, normalize with Normalization Form KC.
- NormalizeForm.NFD, normalize with Normalization Form D.
- NormalizeForm.NFKD, normalize with Normalization Form KD.
preserve_unused_token (bool, optional): If True, do not split special tokens like
'[CLS]', '[SEP]', '[UNK]', '[PAD]', '[MASK]' (default=True).
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> from mindspore.dataset.text import NormalizeForm
>>>
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> tokenizer_op = text.BasicTokenizer(lower_case=False,
... keep_whitespace=False,
... normalization_form=NormalizeForm.NONE,
... preserve_unused_token=True,
... with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str],
>>> # ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.BasicTokenizer(lower_case=False,
... keep_whitespace=False,
... normalization_form=NormalizeForm.NONE,
... preserve_unused_token=True,
... with_offsets=True)
>>> text_file_dataset_1 = text_file_dataset_1.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start",
... "offsets_limit"],
... column_order=["token", "offsets_start",
... "offsets_limit"])
"""
@check_basic_tokenizer
def __init__(self, lower_case=False, keep_whitespace=False, normalization_form=NormalizeForm.NONE,
preserve_unused_token=True, with_offsets=False):
if not isinstance(normalization_form, NormalizeForm):
raise TypeError("Wrong input type for normalization_form, should be enum of 'NormalizeForm'.")
self.lower_case = lower_case
self.keep_whitespace = keep_whitespace
self.normalization_form = DE_C_INTER_NORMALIZE_FORM[normalization_form]
self.preserve_unused_token = preserve_unused_token
self.with_offsets = with_offsets
def parse(self):
return cde.BasicTokenizerOperation(self.lower_case, self.keep_whitespace, self.normalization_form,
self.preserve_unused_token, self.with_offsets)
[docs] class BertTokenizer(TextTensorOperation):
"""
Tokenizer used for Bert text process.
Note:
BertTokenizer is not supported on Windows platform yet.
Args:
vocab (Vocab): A vocabulary object.
suffix_indicator (str, optional): Used to show that the subword is the last part of a word (default='##').
max_bytes_per_token (int, optional): If Tokens exceeding this length, it will not be further
split (default=100).
unknown_token (str, optional): When an unknown token is found, return the token directly if `unknown_token`
is an empty string, else return `unknown_token` instead (default='[UNK]').
lower_case (bool, optional): If True, apply CaseFold, NormalizeUTF8 with `NFD` mode, RegexReplace operation
on input text to fold the text to lower case and strip accented characters. If False, only apply
NormalizeUTF8 operation with the specified mode on input text (default=False).
keep_whitespace (bool, optional): If True, the whitespace will be kept in out tokens (default=False).
normalization_form (NormalizeForm, optional): This parameter is used to specify a specific normalize mode,
only effective when `lower_case` is False. See NormalizeUTF8 for details (default=NormalizeForm.NONE).
preserve_unused_token (bool, optional): If True, do not split special tokens like
'[CLS]', '[SEP]', '[UNK]', '[PAD]', '[MASK]' (default=True).
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> from mindspore.dataset.text import NormalizeForm
>>>
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> vocab_list = ["床", "前", "明", "月", "光", "疑", "是", "地", "上", "霜", "举", "头", "望", "低",
... "思", "故", "乡","繁", "體", "字", "嘿", "哈", "大", "笑", "嘻", "i", "am", "mak",
... "make", "small", "mistake", "##s", "during", "work", "##ing", "hour", "😀", "😃",
... "😄", "😁", "+", "/", "-", "=", "12", "28", "40", "16", " ", "I", "[CLS]", "[SEP]",
... "[UNK]", "[PAD]", "[MASK]", "[unused1]", "[unused10]"]
>>> vocab = text.Vocab.from_list(vocab_list)
>>> tokenizer_op = text.BertTokenizer(vocab=vocab, suffix_indicator='##', max_bytes_per_token=100,
... unknown_token='[UNK]', lower_case=False, keep_whitespace=False,
... normalization_form=NormalizeForm.NONE, preserve_unused_token=True,
... with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str],
>>> # ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.BertTokenizer(vocab=vocab, suffix_indicator='##', max_bytes_per_token=100,
... unknown_token='[UNK]', lower_case=False, keep_whitespace=False,
... normalization_form=NormalizeForm.NONE, preserve_unused_token=True,
... with_offsets=True)
>>> text_file_dataset_1 = text_file_dataset_1.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start",
... "offsets_limit"],
... column_order=["token", "offsets_start",
... "offsets_limit"])
"""
@check_bert_tokenizer
def __init__(self, vocab, suffix_indicator='##', max_bytes_per_token=100, unknown_token='[UNK]',
lower_case=False, keep_whitespace=False, normalization_form=NormalizeForm.NONE,
preserve_unused_token=True, with_offsets=False):
if not isinstance(normalization_form, NormalizeForm):
raise TypeError("Wrong input type for normalization_form, should be enum of 'NormalizeForm'.")
self.vocab = vocab
self.suffix_indicator = suffix_indicator
self.max_bytes_per_token = max_bytes_per_token
self.unknown_token = unknown_token
self.lower_case = lower_case
self.keep_whitespace = keep_whitespace
self.normalization_form = DE_C_INTER_NORMALIZE_FORM[normalization_form]
self.preserve_unused_token = preserve_unused_token
self.with_offsets = with_offsets
def parse(self):
return cde.BertTokenizerOperation(self.vocab, self.suffix_indicator, self.max_bytes_per_token,
self.unknown_token, self.lower_case, self.keep_whitespace,
self.normalization_form, self.preserve_unused_token, self.with_offsets)
[docs] class CaseFold(TextTensorOperation):
"""
Apply case fold operation on UTF-8 string tensor, which is aggressive that can convert more characters into
lower case.
Note:
CaseFold is not supported on Windows platform yet.
Examples:
>>> case_op = text.CaseFold()
>>> text_file_dataset = text_file_dataset.map(operations=case_op)
"""
def parse(self):
return cde.CaseFoldOperation()
[docs] class NormalizeUTF8(TextTensorOperation):
"""
Apply normalize operation on UTF-8 string tensor.
Note:
NormalizeUTF8 is not supported on Windows platform yet.
Args:
normalize_form (NormalizeForm, optional): Valid values can be [NormalizeForm.NONE, NormalizeForm.NFC,
NormalizeForm.NFKC, NormalizeForm.NFD, NormalizeForm.NFKD] any of the four unicode
normalized forms(default=NormalizeForm.NFKC).
See http://unicode.org/reports/tr15/ for details.
- NormalizeForm.NONE, do nothing for input string tensor.
- NormalizeForm.NFC, normalize with Normalization Form C.
- NormalizeForm.NFKC, normalize with Normalization Form KC.
- NormalizeForm.NFD, normalize with Normalization Form D.
- NormalizeForm.NFKD, normalize with Normalization Form KD.
Examples:
>>> from mindspore.dataset.text import NormalizeForm
>>> normalize_op = text.NormalizeUTF8(normalize_form=NormalizeForm.NFC)
>>> text_file_dataset = text_file_dataset.map(operations=normalize_op)
"""
def __init__(self, normalize_form=NormalizeForm.NFKC):
if not isinstance(normalize_form, NormalizeForm):
raise TypeError("Wrong input type for normalization_form, should be enum of 'NormalizeForm'.")
normalize_form = replace_none(normalize_form, NormalizeForm.NFKC)
self.normalize_form = DE_C_INTER_NORMALIZE_FORM[normalize_form]
def parse(self):
return cde.NormalizeUTF8Operation(self.normalize_form)
[docs] class RegexReplace(TextTensorOperation):
"""
Replace a part of UTF-8 string tensor with given text according to regular expressions.
See https://unicode-org.github.io/icu/userguide/strings/regexp.html for supported regex pattern.
Note:
RegexReplace is not supported on Windows platform yet.
Args:
pattern (str): the regex expression patterns.
replace (str): the string to replace matched element.
replace_all (bool, optional): If False, only replace first matched element;
if True, replace all matched elements (default=True).
Examples:
>>> pattern = 'Canada'
>>> replace = 'China'
>>> replace_op = text.RegexReplace(pattern, replace)
>>> text_file_dataset = text_file_dataset.map(operations=replace_op)
"""
@check_regex_replace
def __init__(self, pattern, replace, replace_all=True):
self.pattern = pattern
self.replace = replace
self.replace_all = replace_all
def parse(self):
return cde.RegexReplaceOperation(self.pattern, self.replace, self.replace_all)
[docs] class RegexTokenizer(TextTensorOperation):
"""
Tokenize a scalar tensor of UTF-8 string by regex expression pattern.
See https://unicode-org.github.io/icu/userguide/strings/regexp.html for supported regex pattern.
Note:
RegexTokenizer is not supported on Windows platform yet.
Args:
delim_pattern (str): The pattern of regex delimiters.
The original string will be split by matched elements.
keep_delim_pattern (str, optional): The string matched by 'delim_pattern' can be kept as a token
if it can be matched by 'keep_delim_pattern'. The default value is an empty str
which means that delimiters will not be kept as an output token (default='').
with_offsets (bool, optional): Whether or not output offsets of tokens(default=False).
Examples:
>>> # If with_offsets=False, default output is one column {["text", dtype=str]}
>>> delim_pattern = r"[ |,]"
>>> tokenizer_op = text.RegexTokenizer(delim_pattern, with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str],
>>> # ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.RegexTokenizer(delim_pattern, with_offsets=True)
>>> text_file_dataset_1 = text_file_dataset_1.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start",
... "offsets_limit"],
... column_order=["token", "offsets_start",
... "offsets_limit"])
"""
@check_regex_tokenizer
def __init__(self, delim_pattern, keep_delim_pattern='', with_offsets=False):
self.delim_pattern = delim_pattern
self.keep_delim_pattern = keep_delim_pattern
self.with_offsets = with_offsets
def parse(self):
return cde.RegexTokenizerOperation(self.delim_pattern, self.keep_delim_pattern, self.with_offsets)
[docs] class UnicodeScriptTokenizer(TextTensorOperation):
"""
Tokenize a scalar tensor of UTF-8 string based on Unicode script boundaries.
Note:
UnicodeScriptTokenizer is not supported on Windows platform yet.
Args:
keep_whitespace (bool, optional): Whether or not emit whitespace tokens (default=False).
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> tokenizer_op = text.UnicodeScriptTokenizer(keep_whitespace=True, with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str],
>>> # ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.UnicodeScriptTokenizer(keep_whitespace=True, with_offsets=True)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start", "offsets_limit"],
... column_order=["token", "offsets_start", "offsets_limit"])
"""
@check_unicode_script_tokenizer
def __init__(self, keep_whitespace=False, with_offsets=False):
keep_whitespace = replace_none(keep_whitespace, False)
with_offsets = replace_none(with_offsets, False)
self.keep_whitespace = keep_whitespace
self.with_offsets = with_offsets
def parse(self):
return cde.UnicodeScriptTokenizerOperation(self.keep_whitespace, self.with_offsets)
[docs] class WhitespaceTokenizer(TextTensorOperation):
"""
Tokenize a scalar tensor of UTF-8 string on ICU4C defined whitespaces, such as: ' ', '\\\\t', '\\\\r', '\\\\n'.
Note:
WhitespaceTokenizer is not supported on Windows platform yet.
Args:
with_offsets (bool, optional): Whether or not output offsets of tokens (default=False).
Examples:
>>> # If with_offsets=False, default output one column {["text", dtype=str]}
>>> tokenizer_op = text.WhitespaceTokenizer(with_offsets=False)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op)
>>> # If with_offsets=True, then output three columns {["token", dtype=str],
>>> # ["offsets_start", dtype=uint32],
>>> # ["offsets_limit", dtype=uint32]}
>>> tokenizer_op = text.WhitespaceTokenizer(with_offsets=True)
>>> text_file_dataset = text_file_dataset.map(operations=tokenizer_op, input_columns=["text"],
... output_columns=["token", "offsets_start", "offsets_limit"],
... column_order=["token", "offsets_start", "offsets_limit"])
"""
@check_with_offsets
def __init__(self, with_offsets=False):
self.with_offsets = with_offsets
def parse(self):
return cde.WhitespaceTokenizerOperation(self.with_offsets)