sqlglot.helper
1from __future__ import annotations 2 3import datetime 4import inspect 5import logging 6import re 7import sys 8import typing as t 9from collections.abc import Collection, Set, Iterable, Sequence, Iterator, Mapping 10from copy import copy 11from difflib import get_close_matches 12from enum import Enum 13from itertools import count 14from builtins import type as Type 15 16try: 17 from mypy_extensions import mypyc_attr, trait, i64 18except ImportError: 19 20 def mypyc_attr(*attrs: str, **kwattrs: object) -> t.Callable[[t.Any], t.Any]: # type: ignore[misc] 21 return lambda f: f 22 23 def trait(f: t.Any) -> t.Any: # type: ignore[misc] 24 return f 25 26 i64 = int # type: ignore[misc,assignment] 27 28 29T = t.TypeVar("T") 30E = t.TypeVar("E") 31 32if t.TYPE_CHECKING: 33 from sqlglot.expressions import Expr 34 35 36CAMEL_CASE_PATTERN = re.compile("(?<!^)(?=[A-Z])") 37PYTHON_VERSION = sys.version_info[:2] 38logger = logging.getLogger("sqlglot") 39 40 41class AutoName(Enum): 42 """ 43 This is used for creating Enum classes where `auto()` is the string form 44 of the corresponding enum's identifier (e.g. FOO.value results in "FOO"). 45 46 Reference: https://docs.python.org/3/howto/enum.html#using-automatic-values 47 """ 48 49 def _generate_next_value_(name, _start, _count, _last_values): 50 return name 51 52 53def suggest_closest_match_and_fail( 54 kind: str, 55 word: str, 56 possibilities: Iterable[str], 57) -> None: 58 close_matches = get_close_matches(word, possibilities, n=1) 59 60 similar = seq_get(close_matches, 0) or "" 61 if similar: 62 similar = f" Did you mean {similar}?" 63 64 raise ValueError(f"Unknown {kind} '{word}'.{similar}") 65 66 67def seq_get(seq: Sequence[T], index: int) -> T | None: 68 """Returns the value in `seq` at position `index`, or `None` if `index` is out of bounds.""" 69 try: 70 return seq[index] 71 except IndexError: 72 return None 73 74 75def ensure_list(value: T | list[T] | tuple[T, ...] | None) -> list[T]: 76 """ 77 Ensures that a value is a list, otherwise casts or wraps it into one. 78 79 Args: 80 value: The value of interest. 81 82 Returns: 83 The value cast as a list if it's a list or a tuple, or else the value wrapped in a list. 84 """ 85 if value is None: 86 return [] 87 if isinstance(value, list): 88 return value 89 if isinstance(value, tuple): 90 return list(value) 91 92 return [value] 93 94 95@t.overload 96def ensure_collection(value: Collection[T]) -> Collection[T]: ... 97 98 99@t.overload 100def ensure_collection(value: T) -> Collection[T]: ... 101 102 103def ensure_collection(value): 104 """ 105 Ensures that a value is a collection (excluding `str` and `bytes`), otherwise wraps it into a list. 106 107 Args: 108 value: The value of interest. 109 110 Returns: 111 The value if it's a collection, or else the value wrapped in a list. 112 """ 113 if value is None: 114 return [] 115 return ( 116 value if isinstance(value, Collection) and not isinstance(value, (str, bytes)) else [value] 117 ) 118 119 120def csv(*args: str, sep: str = ", ") -> str: 121 """ 122 Formats any number of string arguments as CSV. 123 124 Args: 125 args: The string arguments to format. 126 sep: The argument separator. 127 128 Returns: 129 The arguments formatted as a CSV string. 130 """ 131 return sep.join(arg for arg in args if arg) 132 133 134def subclasses( 135 module_name: str, 136 classes: Type[T] | tuple[Type[T], ...], 137 exclude: set[Type[T]] = set(), 138) -> list[Type[T]]: 139 """ 140 Returns all subclasses for a collection of classes, possibly excluding some of them. 141 142 Args: 143 module_name: The name of the module to search for subclasses in. 144 classes: Class(es) we want to find the subclasses of. 145 exclude: Classes we want to exclude from the returned list. 146 147 Returns: 148 The target subclasses. 149 """ 150 return [ 151 obj 152 for _, obj in inspect.getmembers( 153 sys.modules[module_name], 154 lambda obj: inspect.isclass(obj) and issubclass(obj, classes) and obj not in exclude, 155 ) 156 ] 157 158 159def camel_to_snake_case(name: str) -> str: 160 """Converts `name` from camelCase to snake_case and returns the result.""" 161 return CAMEL_CASE_PATTERN.sub("_", name).upper() 162 163 164def while_changing(expression: E, func: t.Callable[[E], E]) -> E: 165 """ 166 Applies a transformation to a given expression until a fix point is reached. 167 168 Args: 169 expression: The expression to be transformed. 170 func: The transformation to be applied. 171 172 Returns: 173 The transformed expression. 174 """ 175 176 while True: 177 start_hash = hash(expression) 178 expression = func(expression) 179 end_hash = hash(expression) 180 181 if start_hash == end_hash: 182 break 183 184 return expression 185 186 187def tsort(dag: dict[T, set[T]]) -> list[T]: 188 """ 189 Sorts a given directed acyclic graph in topological order. 190 191 Args: 192 dag: The graph to be sorted. 193 194 Returns: 195 A list that contains all of the graph's nodes in topological order. 196 """ 197 result = [] 198 199 for node, deps in tuple(dag.items()): 200 for dep in deps: 201 if dep not in dag: 202 dag[dep] = set() 203 204 while dag: 205 current = {node for node, deps in dag.items() if not deps} 206 207 if not current: 208 raise ValueError("Cycle error") 209 210 for node in current: 211 dag.pop(node) 212 213 for deps in dag.values(): 214 deps -= current 215 216 result.extend(sorted(current)) # type: ignore 217 218 return result 219 220 221def find_new_name(taken: Collection[str], base: str) -> str: 222 """ 223 Searches for a new name. 224 225 Args: 226 taken: A collection of taken names. 227 base: Base name to alter. 228 229 Returns: 230 The new, available name. 231 """ 232 if base not in taken: 233 return base 234 235 i = 2 236 new = f"{base}_{i}" 237 while new in taken: 238 i += 1 239 new = f"{base}_{i}" 240 241 return new 242 243 244def is_int(text: str) -> bool: 245 return is_type(text, int) 246 247 248def is_float(text: str) -> bool: 249 return is_type(text, float) 250 251 252def is_type(text: str, target_type: Type) -> bool: 253 try: 254 target_type(text) 255 return True 256 except ValueError: 257 return False 258 259 260def name_sequence(prefix: str) -> t.Callable[[], str]: 261 """Returns a name generator given a prefix (e.g. a0, a1, a2, ... if the prefix is "a").""" 262 sequence = count() 263 return lambda: f"{prefix}{next(sequence)}" 264 265 266def object_to_dict(obj: t.Any, **kwargs) -> dict: 267 """Returns a dictionary created from an object's attributes.""" 268 return { 269 **{k: v.copy() if hasattr(v, "copy") else copy(v) for k, v in vars(obj).items()}, 270 **kwargs, 271 } 272 273 274def split_num_words( 275 value: str, sep: str, min_num_words: int, fill_from_start: bool = True 276) -> list[str | None]: 277 """ 278 Perform a split on a value and return N words as a result with `None` used for words that don't exist. 279 280 Args: 281 value: The value to be split. 282 sep: The value to use to split on. 283 min_num_words: The minimum number of words that are going to be in the result. 284 fill_from_start: Indicates that if `None` values should be inserted at the start or end of the list. 285 286 Examples: 287 >>> split_num_words("db.table", ".", 3) 288 [None, 'db', 'table'] 289 >>> split_num_words("db.table", ".", 3, fill_from_start=False) 290 ['db', 'table', None] 291 >>> split_num_words("db.table", ".", 1) 292 ['db', 'table'] 293 294 Returns: 295 The list of words returned by `split`, possibly augmented by a number of `None` values. 296 """ 297 words = value.split(sep) 298 if fill_from_start: 299 return [None] * (min_num_words - len(words)) + words 300 return words + [None] * (min_num_words - len(words)) 301 302 303def is_iterable(value: t.Any) -> bool: 304 """ 305 Checks if the value is an iterable, excluding the types `str` and `bytes`. 306 307 Examples: 308 >>> is_iterable([1,2]) 309 True 310 >>> is_iterable("test") 311 False 312 313 Args: 314 value: The value to check if it is an iterable. 315 316 Returns: 317 A `bool` value indicating if it is an iterable. 318 """ 319 from sqlglot.expressions import Expr 320 321 return hasattr(value, "__iter__") and not isinstance(value, (str, bytes, Expr)) 322 323 324def flatten(values: Iterable[Iterable[t.Any] | t.Any]) -> Iterator[t.Any]: 325 """ 326 Flattens an iterable that can contain both iterable and non-iterable elements. Objects of 327 type `str` and `bytes` are not regarded as iterables. 328 329 Examples: 330 >>> list(flatten([[1, 2], 3, {4}, (5, "bla")])) 331 [1, 2, 3, 4, 5, 'bla'] 332 >>> list(flatten([1, 2, 3])) 333 [1, 2, 3] 334 335 Args: 336 values: The value to be flattened. 337 338 Yields: 339 Non-iterable elements in `values`. 340 """ 341 for value in values: 342 if is_iterable(value): 343 yield from flatten(value) 344 else: 345 yield value 346 347 348def dict_depth(d: t.Any) -> int: 349 """ 350 Get the nesting depth of a dictionary. 351 352 Example: 353 >>> dict_depth(None) 354 0 355 >>> dict_depth({}) 356 1 357 >>> dict_depth({"a": "b"}) 358 1 359 >>> dict_depth({"a": {}}) 360 2 361 >>> dict_depth({"a": {"b": {}}}) 362 3 363 """ 364 try: 365 return 1 + dict_depth(next(iter(d.values()))) 366 except AttributeError: 367 # d doesn't have attribute "values" 368 return 0 369 except StopIteration: 370 # d.values() returns an empty sequence 371 return 1 372 373 374def first(it: Iterable[T]) -> T: 375 """Returns the first element from an iterable (useful for sets).""" 376 return next(i for i in it) 377 378 379@t.overload 380def to_bool(value: None) -> None: ... 381 382 383@t.overload 384def to_bool(value: bool) -> bool: ... 385 386 387@t.overload 388def to_bool(value: str) -> str | bool: ... 389 390 391def to_bool(value: str | bool | None) -> str | bool | None: 392 if isinstance(value, bool) or value is None: 393 return value 394 395 # Coerce the value to boolean if it matches to the truthy/falsy values below 396 value_lower = value.lower() 397 if value_lower in ("true", "1"): 398 return True 399 if value_lower in ("false", "0"): 400 return False 401 402 return value 403 404 405def merge_ranges(ranges: list[tuple[t.Any, t.Any]]) -> list[tuple[t.Any, t.Any]]: 406 """ 407 Merges a sequence of ranges, represented as tuples (low, high) whose values 408 belong to some totally-ordered set. 409 410 Example: 411 >>> merge_ranges([(1, 3), (2, 6)]) 412 [(1, 6)] 413 """ 414 if not ranges: 415 return [] 416 417 ranges = sorted(ranges) 418 419 merged = [ranges[0]] 420 421 for start, end in ranges[1:]: 422 last_start, last_end = merged[-1] 423 424 if start <= last_end: 425 merged[-1] = (last_start, max(last_end, end)) 426 else: 427 merged.append((start, end)) 428 429 return merged 430 431 432def is_iso_date(text: str) -> bool: 433 try: 434 datetime.date.fromisoformat(text) 435 return True 436 except ValueError: 437 return False 438 439 440def is_iso_datetime(text: str) -> bool: 441 try: 442 datetime.datetime.fromisoformat(text) 443 return True 444 except ValueError: 445 return False 446 447 448# Interval units that operate on date components 449DATE_UNITS = {"day", "week", "month", "quarter", "year", "year_month"} 450 451 452def is_date_unit(expression: Expr | None) -> bool: 453 return expression is not None and expression.name.lower() in DATE_UNITS 454 455 456K = t.TypeVar("K") 457V = t.TypeVar("V") 458 459 460class SingleValuedMapping(Mapping[K, V]): 461 """ 462 Mapping where all keys return the same value. 463 464 This rigamarole is meant to avoid copying keys, which was originally intended 465 as an optimization while qualifying columns for tables with lots of columns. 466 """ 467 468 def __init__(self, keys: Collection[K], value: V): 469 self._keys = keys if isinstance(keys, Set) else set(keys) 470 self._value = value 471 472 def __getitem__(self, key: K) -> V: 473 if key in self._keys: 474 return self._value 475 raise KeyError(key) 476 477 def __len__(self) -> int: 478 return len(self._keys) 479 480 def __iter__(self) -> Iterator[K]: 481 return iter(self._keys)
CAMEL_CASE_PATTERN =
re.compile('(?<!^)(?=[A-Z])')
PYTHON_VERSION =
(3, 10)
logger =
<Logger sqlglot (WARNING)>
class
AutoName(enum.Enum):
42class AutoName(Enum): 43 """ 44 This is used for creating Enum classes where `auto()` is the string form 45 of the corresponding enum's identifier (e.g. FOO.value results in "FOO"). 46 47 Reference: https://docs.python.org/3/howto/enum.html#using-automatic-values 48 """ 49 50 def _generate_next_value_(name, _start, _count, _last_values): 51 return name
This is used for creating Enum classes where auto() is the string form
of the corresponding enum's identifier (e.g. FOO.value results in "FOO").
Reference: https://docs.python.org/3/howto/enum.html#using-automatic-values
def
suggest_closest_match_and_fail(kind: str, word: str, possibilities: Iterable[str]) -> None:
54def suggest_closest_match_and_fail( 55 kind: str, 56 word: str, 57 possibilities: Iterable[str], 58) -> None: 59 close_matches = get_close_matches(word, possibilities, n=1) 60 61 similar = seq_get(close_matches, 0) or "" 62 if similar: 63 similar = f" Did you mean {similar}?" 64 65 raise ValueError(f"Unknown {kind} '{word}'.{similar}")
def
seq_get(seq: Sequence[~T], index: int) -> Optional[~T]:
68def seq_get(seq: Sequence[T], index: int) -> T | None: 69 """Returns the value in `seq` at position `index`, or `None` if `index` is out of bounds.""" 70 try: 71 return seq[index] 72 except IndexError: 73 return None
Returns the value in seq at position index, or None if index is out of bounds.
def
ensure_list(value: Union[~T, list[~T], tuple[~T, ...], NoneType]) -> list[~T]:
76def ensure_list(value: T | list[T] | tuple[T, ...] | None) -> list[T]: 77 """ 78 Ensures that a value is a list, otherwise casts or wraps it into one. 79 80 Args: 81 value: The value of interest. 82 83 Returns: 84 The value cast as a list if it's a list or a tuple, or else the value wrapped in a list. 85 """ 86 if value is None: 87 return [] 88 if isinstance(value, list): 89 return value 90 if isinstance(value, tuple): 91 return list(value) 92 93 return [value]
Ensures that a value is a list, otherwise casts or wraps it into one.
Arguments:
- value: The value of interest.
Returns:
The value cast as a list if it's a list or a tuple, or else the value wrapped in a list.
def
ensure_collection(value):
104def ensure_collection(value): 105 """ 106 Ensures that a value is a collection (excluding `str` and `bytes`), otherwise wraps it into a list. 107 108 Args: 109 value: The value of interest. 110 111 Returns: 112 The value if it's a collection, or else the value wrapped in a list. 113 """ 114 if value is None: 115 return [] 116 return ( 117 value if isinstance(value, Collection) and not isinstance(value, (str, bytes)) else [value] 118 )
Ensures that a value is a collection (excluding str and bytes), otherwise wraps it into a list.
Arguments:
- value: The value of interest.
Returns:
The value if it's a collection, or else the value wrapped in a list.
def
csv(*args: str, sep: str = ', ') -> str:
121def csv(*args: str, sep: str = ", ") -> str: 122 """ 123 Formats any number of string arguments as CSV. 124 125 Args: 126 args: The string arguments to format. 127 sep: The argument separator. 128 129 Returns: 130 The arguments formatted as a CSV string. 131 """ 132 return sep.join(arg for arg in args if arg)
Formats any number of string arguments as CSV.
Arguments:
- args: The string arguments to format.
- sep: The argument separator.
Returns:
The arguments formatted as a CSV string.
def
subclasses( module_name: str, classes: type[~T] | tuple[type[~T], ...], exclude: set[type[~T]] = set()) -> list[type[~T]]:
135def subclasses( 136 module_name: str, 137 classes: Type[T] | tuple[Type[T], ...], 138 exclude: set[Type[T]] = set(), 139) -> list[Type[T]]: 140 """ 141 Returns all subclasses for a collection of classes, possibly excluding some of them. 142 143 Args: 144 module_name: The name of the module to search for subclasses in. 145 classes: Class(es) we want to find the subclasses of. 146 exclude: Classes we want to exclude from the returned list. 147 148 Returns: 149 The target subclasses. 150 """ 151 return [ 152 obj 153 for _, obj in inspect.getmembers( 154 sys.modules[module_name], 155 lambda obj: inspect.isclass(obj) and issubclass(obj, classes) and obj not in exclude, 156 ) 157 ]
Returns all subclasses for a collection of classes, possibly excluding some of them.
Arguments:
- module_name: The name of the module to search for subclasses in.
- classes: Class(es) we want to find the subclasses of.
- exclude: Classes we want to exclude from the returned list.
Returns:
The target subclasses.
def
camel_to_snake_case(name: str) -> str:
160def camel_to_snake_case(name: str) -> str: 161 """Converts `name` from camelCase to snake_case and returns the result.""" 162 return CAMEL_CASE_PATTERN.sub("_", name).upper()
Converts name from camelCase to snake_case and returns the result.
def
while_changing(expression: ~E, func: Callable[[~E], ~E]) -> ~E:
165def while_changing(expression: E, func: t.Callable[[E], E]) -> E: 166 """ 167 Applies a transformation to a given expression until a fix point is reached. 168 169 Args: 170 expression: The expression to be transformed. 171 func: The transformation to be applied. 172 173 Returns: 174 The transformed expression. 175 """ 176 177 while True: 178 start_hash = hash(expression) 179 expression = func(expression) 180 end_hash = hash(expression) 181 182 if start_hash == end_hash: 183 break 184 185 return expression
Applies a transformation to a given expression until a fix point is reached.
Arguments:
- expression: The expression to be transformed.
- func: The transformation to be applied.
Returns:
The transformed expression.
def
tsort(dag: dict[~T, set[~T]]) -> list[~T]:
188def tsort(dag: dict[T, set[T]]) -> list[T]: 189 """ 190 Sorts a given directed acyclic graph in topological order. 191 192 Args: 193 dag: The graph to be sorted. 194 195 Returns: 196 A list that contains all of the graph's nodes in topological order. 197 """ 198 result = [] 199 200 for node, deps in tuple(dag.items()): 201 for dep in deps: 202 if dep not in dag: 203 dag[dep] = set() 204 205 while dag: 206 current = {node for node, deps in dag.items() if not deps} 207 208 if not current: 209 raise ValueError("Cycle error") 210 211 for node in current: 212 dag.pop(node) 213 214 for deps in dag.values(): 215 deps -= current 216 217 result.extend(sorted(current)) # type: ignore 218 219 return result
Sorts a given directed acyclic graph in topological order.
Arguments:
- dag: The graph to be sorted.
Returns:
A list that contains all of the graph's nodes in topological order.
def
find_new_name(taken: Collection[str], base: str) -> str:
222def find_new_name(taken: Collection[str], base: str) -> str: 223 """ 224 Searches for a new name. 225 226 Args: 227 taken: A collection of taken names. 228 base: Base name to alter. 229 230 Returns: 231 The new, available name. 232 """ 233 if base not in taken: 234 return base 235 236 i = 2 237 new = f"{base}_{i}" 238 while new in taken: 239 i += 1 240 new = f"{base}_{i}" 241 242 return new
Searches for a new name.
Arguments:
- taken: A collection of taken names.
- base: Base name to alter.
Returns:
The new, available name.
def
is_int(text: str) -> bool:
def
is_float(text: str) -> bool:
def
is_type(text: str, target_type: type) -> bool:
def
name_sequence(prefix: str) -> Callable[[], str]:
261def name_sequence(prefix: str) -> t.Callable[[], str]: 262 """Returns a name generator given a prefix (e.g. a0, a1, a2, ... if the prefix is "a").""" 263 sequence = count() 264 return lambda: f"{prefix}{next(sequence)}"
Returns a name generator given a prefix (e.g. a0, a1, a2, ... if the prefix is "a").
def
object_to_dict(obj: Any, **kwargs) -> dict:
267def object_to_dict(obj: t.Any, **kwargs) -> dict: 268 """Returns a dictionary created from an object's attributes.""" 269 return { 270 **{k: v.copy() if hasattr(v, "copy") else copy(v) for k, v in vars(obj).items()}, 271 **kwargs, 272 }
Returns a dictionary created from an object's attributes.
def
split_num_words( value: str, sep: str, min_num_words: int, fill_from_start: bool = True) -> list[str | None]:
275def split_num_words( 276 value: str, sep: str, min_num_words: int, fill_from_start: bool = True 277) -> list[str | None]: 278 """ 279 Perform a split on a value and return N words as a result with `None` used for words that don't exist. 280 281 Args: 282 value: The value to be split. 283 sep: The value to use to split on. 284 min_num_words: The minimum number of words that are going to be in the result. 285 fill_from_start: Indicates that if `None` values should be inserted at the start or end of the list. 286 287 Examples: 288 >>> split_num_words("db.table", ".", 3) 289 [None, 'db', 'table'] 290 >>> split_num_words("db.table", ".", 3, fill_from_start=False) 291 ['db', 'table', None] 292 >>> split_num_words("db.table", ".", 1) 293 ['db', 'table'] 294 295 Returns: 296 The list of words returned by `split`, possibly augmented by a number of `None` values. 297 """ 298 words = value.split(sep) 299 if fill_from_start: 300 return [None] * (min_num_words - len(words)) + words 301 return words + [None] * (min_num_words - len(words))
Perform a split on a value and return N words as a result with None used for words that don't exist.
Arguments:
- value: The value to be split.
- sep: The value to use to split on.
- min_num_words: The minimum number of words that are going to be in the result.
- fill_from_start: Indicates that if
Nonevalues should be inserted at the start or end of the list.
Examples:
>>> split_num_words("db.table", ".", 3) [None, 'db', 'table'] >>> split_num_words("db.table", ".", 3, fill_from_start=False) ['db', 'table', None] >>> split_num_words("db.table", ".", 1) ['db', 'table']
Returns:
The list of words returned by
split, possibly augmented by a number ofNonevalues.
def
is_iterable(value: Any) -> bool:
304def is_iterable(value: t.Any) -> bool: 305 """ 306 Checks if the value is an iterable, excluding the types `str` and `bytes`. 307 308 Examples: 309 >>> is_iterable([1,2]) 310 True 311 >>> is_iterable("test") 312 False 313 314 Args: 315 value: The value to check if it is an iterable. 316 317 Returns: 318 A `bool` value indicating if it is an iterable. 319 """ 320 from sqlglot.expressions import Expr 321 322 return hasattr(value, "__iter__") and not isinstance(value, (str, bytes, Expr))
Checks if the value is an iterable, excluding the types str and bytes.
Examples:
>>> is_iterable([1,2]) True >>> is_iterable("test") False
Arguments:
- value: The value to check if it is an iterable.
Returns:
A
boolvalue indicating if it is an iterable.
def
flatten( values: Iterable[typing.Union[Iterable[typing.Any], typing.Any]]) -> Iterator[typing.Any]:
325def flatten(values: Iterable[Iterable[t.Any] | t.Any]) -> Iterator[t.Any]: 326 """ 327 Flattens an iterable that can contain both iterable and non-iterable elements. Objects of 328 type `str` and `bytes` are not regarded as iterables. 329 330 Examples: 331 >>> list(flatten([[1, 2], 3, {4}, (5, "bla")])) 332 [1, 2, 3, 4, 5, 'bla'] 333 >>> list(flatten([1, 2, 3])) 334 [1, 2, 3] 335 336 Args: 337 values: The value to be flattened. 338 339 Yields: 340 Non-iterable elements in `values`. 341 """ 342 for value in values: 343 if is_iterable(value): 344 yield from flatten(value) 345 else: 346 yield value
Flattens an iterable that can contain both iterable and non-iterable elements. Objects of
type str and bytes are not regarded as iterables.
Examples:
>>> list(flatten([[1, 2], 3, {4}, (5, "bla")])) [1, 2, 3, 4, 5, 'bla'] >>> list(flatten([1, 2, 3])) [1, 2, 3]
Arguments:
- values: The value to be flattened.
Yields:
Non-iterable elements in
values.
def
dict_depth(d: Any) -> int:
349def dict_depth(d: t.Any) -> int: 350 """ 351 Get the nesting depth of a dictionary. 352 353 Example: 354 >>> dict_depth(None) 355 0 356 >>> dict_depth({}) 357 1 358 >>> dict_depth({"a": "b"}) 359 1 360 >>> dict_depth({"a": {}}) 361 2 362 >>> dict_depth({"a": {"b": {}}}) 363 3 364 """ 365 try: 366 return 1 + dict_depth(next(iter(d.values()))) 367 except AttributeError: 368 # d doesn't have attribute "values" 369 return 0 370 except StopIteration: 371 # d.values() returns an empty sequence 372 return 1
Get the nesting depth of a dictionary.
Example:
>>> dict_depth(None) 0 >>> dict_depth({}) 1 >>> dict_depth({"a": "b"}) 1 >>> dict_depth({"a": {}}) 2 >>> dict_depth({"a": {"b": {}}}) 3
def
first(it: Iterable[~T]) -> ~T:
375def first(it: Iterable[T]) -> T: 376 """Returns the first element from an iterable (useful for sets).""" 377 return next(i for i in it)
Returns the first element from an iterable (useful for sets).
def
to_bool(value: str | bool | None) -> str | bool | None:
392def to_bool(value: str | bool | None) -> str | bool | None: 393 if isinstance(value, bool) or value is None: 394 return value 395 396 # Coerce the value to boolean if it matches to the truthy/falsy values below 397 value_lower = value.lower() 398 if value_lower in ("true", "1"): 399 return True 400 if value_lower in ("false", "0"): 401 return False 402 403 return value
def
merge_ranges( ranges: list[tuple[typing.Any, typing.Any]]) -> list[tuple[typing.Any, typing.Any]]:
406def merge_ranges(ranges: list[tuple[t.Any, t.Any]]) -> list[tuple[t.Any, t.Any]]: 407 """ 408 Merges a sequence of ranges, represented as tuples (low, high) whose values 409 belong to some totally-ordered set. 410 411 Example: 412 >>> merge_ranges([(1, 3), (2, 6)]) 413 [(1, 6)] 414 """ 415 if not ranges: 416 return [] 417 418 ranges = sorted(ranges) 419 420 merged = [ranges[0]] 421 422 for start, end in ranges[1:]: 423 last_start, last_end = merged[-1] 424 425 if start <= last_end: 426 merged[-1] = (last_start, max(last_end, end)) 427 else: 428 merged.append((start, end)) 429 430 return merged
Merges a sequence of ranges, represented as tuples (low, high) whose values belong to some totally-ordered set.
Example:
>>> merge_ranges([(1, 3), (2, 6)]) [(1, 6)]
def
is_iso_date(text: str) -> bool:
def
is_iso_datetime(text: str) -> bool:
DATE_UNITS =
{'year', 'day', 'month', 'year_month', 'quarter', 'week'}
class
SingleValuedMapping(collections.abc.Mapping[~K, ~V]):
461class SingleValuedMapping(Mapping[K, V]): 462 """ 463 Mapping where all keys return the same value. 464 465 This rigamarole is meant to avoid copying keys, which was originally intended 466 as an optimization while qualifying columns for tables with lots of columns. 467 """ 468 469 def __init__(self, keys: Collection[K], value: V): 470 self._keys = keys if isinstance(keys, Set) else set(keys) 471 self._value = value 472 473 def __getitem__(self, key: K) -> V: 474 if key in self._keys: 475 return self._value 476 raise KeyError(key) 477 478 def __len__(self) -> int: 479 return len(self._keys) 480 481 def __iter__(self) -> Iterator[K]: 482 return iter(self._keys)
Mapping where all keys return the same value.
This rigamarole is meant to avoid copying keys, which was originally intended as an optimization while qualifying columns for tables with lots of columns.