Datasets:

echodict
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NeMo

	# Copyright (c) 2022, NVIDIA CORPORATION. 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.

	import math
	from typing import Dict, List, Tuple

	import numpy as np
	from numpy import ndarray
	from sklearn.preprocessing import PowerTransformer, QuantileTransformer, RobustScaler

	from nemo.utils import logging

	__all__ = ["IntCode", "FloatCode", "CategoryCode", "ColumnCodes"]


	class Code(object):
	def compute_code(self, data_series: ndarray):
	"""
	@params:
	data_series: an array of input data used to calculate mapping
	"""
	raise NotImplementedError()

	def __init__(self, col_name: str, code_len: int, start_id: int, fillall: bool = True, hasnan: bool = True):
	"""
	@params:
	col_name: name of the column
	code_len: number of tokens used to code the column.
	start_id: offset for token_id.
	fillall: if True, reserve space for digit number even the digit number is
	not present in the data_series. Otherwise, only reserve space for the numbers
	in the data_series.
	hasnan: if True, reserve space for nan
	"""
	self.name = col_name
	self.code_len = code_len
	self.start_id = start_id
	self.end_id = start_id
	self.fillall = fillall
	self.hasnan = hasnan

	def encode(self, item: str) -> List[int]:
	raise NotImplementedError()

	def decode(self, ids: List[int]) -> str:
	raise NotImplementedError()

	@property
	def code_range(self) -> List[Tuple[int, int]]:
	"""
	get the vocab id range for each of the encoded tokens
	@returns [(min, max), (min, max), ...]
	"""
	return [(self.start_id, self.end_id)]


	class IntCode(Code):
	def __init__(
	self, col_name: str, code_len: int, start_id: int, fillall: bool = True, base: int = 100, hasnan: bool = True
	):
	super().__init__(col_name, code_len, start_id, fillall, hasnan)
	self.base = base
	self.int_min: int = None

	def compute_code(self, data_series: ndarray):
	significant_val = self.array_convert_to_int(data_series)

	digits_id_to_item = [{} for _ in range(self.code_len)]
	digits_item_to_id = [{} for _ in range(self.code_len)]
	for i in range(self.code_len):
	id_to_item = digits_id_to_item[i]
	item_to_id = digits_item_to_id[i]
	v = (significant_val // self.base ** i) % self.base
	if self.fillall:
	uniq_items = range(0, self.base)
	else:
	uniq_items = sorted(np.unique(v).tolist())
	for k in range(len(uniq_items)):
	item = str(uniq_items[k])
	item_to_id[item] = self.end_id
	id_to_item[self.end_id] = item
	self.end_id += 1
	self.digits_id_to_item = digits_id_to_item
	self.digits_item_to_id = digits_item_to_id
	self.NA_token = 'nan'
	if self.hasnan:
	self.end_id += 1 # add the N/A token
	codes = []
	ranges = self.code_range
	for i in ranges:
	codes.append(i[1] - 1)
	self.NA_token_id = codes

	def array_convert_to_int(self, val: ndarray):
	val = val.astype(int)
	self.int_min = val.min()
	return val - self.int_min

	def convert_to_int(self, val: float) -> int:
	return int(val) - self.int_min

	def reverse_convert_to_int(self, val: int) -> int:
	return val + self.int_min

	@property
	def code_range(self) -> List[Tuple[int, int]]:
	"""
	get the vocab id range for each of the encoded tokens
	@returns [(min, max), (min, max), ...]
	"""
	# first largest digits
	outputs = []
	c = 0
	for i in reversed(range(self.code_len)):
	ids = self.digits_id_to_item[i].keys()
	if c == 0:
	if self.hasnan:
	outputs.append((min(ids), max(ids) + 2)) # the first token contains the N/A
	else:
	outputs.append((min(ids), max(ids) + 1)) # non N/A
	else:
	outputs.append((min(ids), max(ids) + 1))
	c += 1
	return outputs

	def encode(self, item: str) -> List[int]:
	if self.hasnan and item == self.NA_token:
	return self.NA_token_id
	elif not self.hasnan and item == self.NA_token:
	raise ValueError(f"colum {self.name} cannot handle nan, please set hasnan=True")
	val = float(item)
	val_int = self.convert_to_int(val)
	digits = []
	for i in range(self.code_len):
	digit = (val_int // self.base ** i) % self.base
	digits.append(str(digit))
	if (val_int // self.base ** self.code_len) != 0:
	raise ValueError("not right length")
	codes = []
	for i in reversed(range(self.code_len)):
	digit_str = digits[i]
	if digit_str in self.digits_item_to_id[i]:
	codes.append(self.digits_item_to_id[i][digit_str])
	else:
	# find the nearest encode id
	allowed_digits = np.array([int(d) for d in self.digits_item_to_id[i].keys()])
	near_id = np.argmin(np.abs(allowed_digits - int(digit_str)))
	digit_str = str(allowed_digits[near_id])
	codes.append(self.digits_item_to_id[i][digit_str])
	logging.warning('out of domain num is encounterd, use nearest code')
	return codes

	def decode(self, ids: List[int]) -> str:
	if self.hasnan and ids[0] == self.NA_token_id[0]:
	return self.NA_token
	v = 0
	for i in reversed(range(self.code_len)):
	digit = int(self.digits_id_to_item[i][ids[self.code_len - i - 1]])
	v += digit * self.base ** i
	v = self.reverse_convert_to_int(v)
	return str(v)


	class FloatCode(IntCode):
	def __init__(
	self,
	col_name: str,
	code_len: int,
	start_id: int,
	fillall: bool = True,
	base: int = 100,
	hasnan: bool = True,
	transform: str = 'quantile',
	):
	super().__init__(col_name, code_len, start_id, fillall, base, hasnan)
	if transform == 'yeo-johnson':
	self.scaler = PowerTransformer(standardize=True)
	elif transform == 'quantile':
	self.scaler = QuantileTransformer(output_distribution='uniform', n_quantiles=100)
	elif transform == 'robust':
	self.scaler = RobustScaler()
	else:
	raise ValueError('Supported data transformations are "yeo-johnson", "quantile", and "robust"')

	def convert_to_int(self, val: float) -> int:
	val = np.expand_dims(np.array(val), axis=0)
	values = self.scaler.transform(val[:, None])[:, 0] - self.mval
	values = (values * self.base ** self.extra_digits).astype(int)
	output = values[0]
	return output

	def array_convert_to_int(self, val: ndarray):
	values = self.scaler.fit_transform(val[:, None])[:, 0]
	self.mval = values.min()
	values = values - self.mval
	digits = int(math.log(values.max(), self.base)) + 1
	# extra digits used for 'float' part of the number
	extra_digits = self.code_len - digits
	if extra_digits < 0:
	raise ValueError("need large length to code the nummber")
	self.extra_digits = extra_digits
	values = (values * self.base ** self.extra_digits).astype(int)
	return values

	def reverse_convert_to_int(self, val: int) -> float:
	val = val / self.base ** self.extra_digits
	val = np.expand_dims(np.array(val), axis=0)
	v = self.scaler.inverse_transform(val[:, None] + self.mval)[0, 0]
	return v

	def decode(self, ids: List[int]) -> str:
	if self.hasnan and ids[0] == self.NA_token_id[0]:
	return self.NA_token
	v = 0
	for i in reversed(range(self.code_len)):
	digit = int(self.digits_id_to_item[i][ids[self.code_len - i - 1]])
	v += digit * self.base ** i
	v = self.reverse_convert_to_int(v)
	accuracy = max(int(abs(np.log10(0.1 / self.base ** self.extra_digits))), 1)
	return f"{v:.{accuracy}f}"


	class CategoryCode(Code):
	def __init__(self, col_name: str, start_id: int):
	super().__init__(col_name, 1, start_id, True, False)

	def compute_code(self, data_series: ndarray):
	uniq_items = np.unique(data_series).tolist()
	id_to_item = {}
	item_to_id = {}
	for i in range(len(uniq_items)):
	item = str(uniq_items[i])
	item_to_id[item] = self.end_id
	id_to_item[self.end_id] = item
	self.end_id += 1
	self.id_to_item = id_to_item
	self.item_to_id = item_to_id

	def encode(self, item) -> List[int]:
	return [self.item_to_id[item]]

	def decode(self, ids: List[int]) -> str:
	return self.id_to_item[ids[0]]


	column_map = {"int": IntCode, "float": FloatCode, "category": CategoryCode}


	class ColumnCodes(object):
	def __init__(self):
	self.column_codes: Dict[str, Code] = {}
	self.columns = []
	self.sizes = []

	@property
	def vocab_size(self):
	return self.column_codes[self.columns[-1]].end_id

	def register(self, name: str, ccode: Code):
	self.columns.append(name)
	self.column_codes[name] = ccode
	self.sizes.append(ccode.code_len)

	def encode(self, col: str, item: str) -> List[int]:
	if col in self.column_codes:
	return self.column_codes[col].encode(item)
	else:
	raise ValueError(f"cannot encode {col} {item}")

	def decode(self, col: str, ids: List[int]) -> str:
	if col in self.column_codes:
	return self.column_codes[col].decode(ids)
	else:
	raise ValueError("cannot decode")

	def get_range(self, column_id: int) -> List[Tuple[int, int]]:
	return self.column_codes[self.columns[column_id]].code_range

	@classmethod
	def get_column_codes(cls, column_configs, example_arrays):
	column_codes = cls()
	beg = 0
	cc = None
	for config in column_configs:
	col_name = config['name']
	coder = column_map[config['code_type']]
	args = config.get('args', {})
	start_id = beg if cc is None else cc.end_id
	args['start_id'] = start_id
	args['col_name'] = col_name
	cc = coder(**args)
	cc.compute_code(example_arrays[col_name])
	column_codes.register(col_name, cc)
	return column_codes