aboutsummaryrefslogtreecommitdiffhomepage
path: root/libs/pydantic/generics.py
blob: a75b6b987da7335f390945ee40195ea2f96c65e9 (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
import sys
import types
import typing
from typing import (
    TYPE_CHECKING,
    Any,
    ClassVar,
    Dict,
    ForwardRef,
    Generic,
    Iterator,
    List,
    Mapping,
    Optional,
    Tuple,
    Type,
    TypeVar,
    Union,
    cast,
)
from weakref import WeakKeyDictionary, WeakValueDictionary

from typing_extensions import Annotated, Literal as ExtLiteral

from .class_validators import gather_all_validators
from .fields import DeferredType
from .main import BaseModel, create_model
from .types import JsonWrapper
from .typing import display_as_type, get_all_type_hints, get_args, get_origin, typing_base
from .utils import all_identical, lenient_issubclass

if sys.version_info >= (3, 10):
    from typing import _UnionGenericAlias
if sys.version_info >= (3, 8):
    from typing import Literal

GenericModelT = TypeVar('GenericModelT', bound='GenericModel')
TypeVarType = Any  # since mypy doesn't allow the use of TypeVar as a type

CacheKey = Tuple[Type[Any], Any, Tuple[Any, ...]]
Parametrization = Mapping[TypeVarType, Type[Any]]

# weak dictionaries allow the dynamically created parametrized versions of generic models to get collected
# once they are no longer referenced by the caller.
if sys.version_info >= (3, 9):  # Typing for weak dictionaries available at 3.9
    GenericTypesCache = WeakValueDictionary[CacheKey, Type[BaseModel]]
    AssignedParameters = WeakKeyDictionary[Type[BaseModel], Parametrization]
else:
    GenericTypesCache = WeakValueDictionary
    AssignedParameters = WeakKeyDictionary

# _generic_types_cache is a Mapping from __class_getitem__ arguments to the parametrized version of generic models.
# This ensures multiple calls of e.g. A[B] return always the same class.
_generic_types_cache = GenericTypesCache()

# _assigned_parameters is a Mapping from parametrized version of generic models to assigned types of parametrizations
# as captured during construction of the class (not instances).
# E.g., for generic model `Model[A, B]`, when parametrized model `Model[int, str]` is created,
# `Model[int, str]`: {A: int, B: str}` will be stored in `_assigned_parameters`.
# (This information is only otherwise available after creation from the class name string).
_assigned_parameters = AssignedParameters()


class GenericModel(BaseModel):
    __slots__ = ()
    __concrete__: ClassVar[bool] = False

    if TYPE_CHECKING:
        # Putting this in a TYPE_CHECKING block allows us to replace `if Generic not in cls.__bases__` with
        # `not hasattr(cls, "__parameters__")`. This means we don't need to force non-concrete subclasses of
        # `GenericModel` to also inherit from `Generic`, which would require changes to the use of `create_model` below.
        __parameters__: ClassVar[Tuple[TypeVarType, ...]]

    # Setting the return type as Type[Any] instead of Type[BaseModel] prevents PyCharm warnings
    def __class_getitem__(cls: Type[GenericModelT], params: Union[Type[Any], Tuple[Type[Any], ...]]) -> Type[Any]:
        """Instantiates a new class from a generic class `cls` and type variables `params`.

        :param params: Tuple of types the class . Given a generic class
            `Model` with 2 type variables and a concrete model `Model[str, int]`,
            the value `(str, int)` would be passed to `params`.
        :return: New model class inheriting from `cls` with instantiated
            types described by `params`. If no parameters are given, `cls` is
            returned as is.

        """

        def _cache_key(_params: Any) -> CacheKey:
            args = get_args(_params)
            # python returns a list for Callables, which is not hashable
            if len(args) == 2 and isinstance(args[0], list):
                args = (tuple(args[0]), args[1])
            return cls, _params, args

        cached = _generic_types_cache.get(_cache_key(params))
        if cached is not None:
            return cached
        if cls.__concrete__ and Generic not in cls.__bases__:
            raise TypeError('Cannot parameterize a concrete instantiation of a generic model')
        if not isinstance(params, tuple):
            params = (params,)
        if cls is GenericModel and any(isinstance(param, TypeVar) for param in params):
            raise TypeError('Type parameters should be placed on typing.Generic, not GenericModel')
        if not hasattr(cls, '__parameters__'):
            raise TypeError(f'Type {cls.__name__} must inherit from typing.Generic before being parameterized')

        check_parameters_count(cls, params)
        # Build map from generic typevars to passed params
        typevars_map: Dict[TypeVarType, Type[Any]] = dict(zip(cls.__parameters__, params))
        if all_identical(typevars_map.keys(), typevars_map.values()) and typevars_map:
            return cls  # if arguments are equal to parameters it's the same object

        # Create new model with original model as parent inserting fields with DeferredType.
        model_name = cls.__concrete_name__(params)
        validators = gather_all_validators(cls)

        type_hints = get_all_type_hints(cls).items()
        instance_type_hints = {k: v for k, v in type_hints if get_origin(v) is not ClassVar}

        fields = {k: (DeferredType(), cls.__fields__[k].field_info) for k in instance_type_hints if k in cls.__fields__}

        model_module, called_globally = get_caller_frame_info()
        created_model = cast(
            Type[GenericModel],  # casting ensures mypy is aware of the __concrete__ and __parameters__ attributes
            create_model(
                model_name,
                __module__=model_module or cls.__module__,
                __base__=(cls,) + tuple(cls.__parameterized_bases__(typevars_map)),
                __config__=None,
                __validators__=validators,
                __cls_kwargs__=None,
                **fields,
            ),
        )

        _assigned_parameters[created_model] = typevars_map

        if called_globally:  # create global reference and therefore allow pickling
            object_by_reference = None
            reference_name = model_name
            reference_module_globals = sys.modules[created_model.__module__].__dict__
            while object_by_reference is not created_model:
                object_by_reference = reference_module_globals.setdefault(reference_name, created_model)
                reference_name += '_'

        created_model.Config = cls.Config

        # Find any typevars that are still present in the model.
        # If none are left, the model is fully "concrete", otherwise the new
        # class is a generic class as well taking the found typevars as
        # parameters.
        new_params = tuple(
            {param: None for param in iter_contained_typevars(typevars_map.values())}
        )  # use dict as ordered set
        created_model.__concrete__ = not new_params
        if new_params:
            created_model.__parameters__ = new_params

        # Save created model in cache so we don't end up creating duplicate
        # models that should be identical.
        _generic_types_cache[_cache_key(params)] = created_model
        if len(params) == 1:
            _generic_types_cache[_cache_key(params[0])] = created_model

        # Recursively walk class type hints and replace generic typevars
        # with concrete types that were passed.
        _prepare_model_fields(created_model, fields, instance_type_hints, typevars_map)

        return created_model

    @classmethod
    def __concrete_name__(cls: Type[Any], params: Tuple[Type[Any], ...]) -> str:
        """Compute class name for child classes.

        :param params: Tuple of types the class . Given a generic class
            `Model` with 2 type variables and a concrete model `Model[str, int]`,
            the value `(str, int)` would be passed to `params`.
        :return: String representing a the new class where `params` are
            passed to `cls` as type variables.

        This method can be overridden to achieve a custom naming scheme for GenericModels.
        """
        param_names = [display_as_type(param) for param in params]
        params_component = ', '.join(param_names)
        return f'{cls.__name__}[{params_component}]'

    @classmethod
    def __parameterized_bases__(cls, typevars_map: Parametrization) -> Iterator[Type[Any]]:
        """
        Returns unbound bases of cls parameterised to given type variables

        :param typevars_map: Dictionary of type applications for binding subclasses.
            Given a generic class `Model` with 2 type variables [S, T]
            and a concrete model `Model[str, int]`,
            the value `{S: str, T: int}` would be passed to `typevars_map`.
        :return: an iterator of generic sub classes, parameterised by `typevars_map`
            and other assigned parameters of `cls`

        e.g.:
        ```
        class A(GenericModel, Generic[T]):
            ...

        class B(A[V], Generic[V]):
            ...

        assert A[int] in B.__parameterized_bases__({V: int})
        ```
        """

        def build_base_model(
            base_model: Type[GenericModel], mapped_types: Parametrization
        ) -> Iterator[Type[GenericModel]]:
            base_parameters = tuple(mapped_types[param] for param in base_model.__parameters__)
            parameterized_base = base_model.__class_getitem__(base_parameters)
            if parameterized_base is base_model or parameterized_base is cls:
                # Avoid duplication in MRO
                return
            yield parameterized_base

        for base_model in cls.__bases__:
            if not issubclass(base_model, GenericModel):
                # not a class that can be meaningfully parameterized
                continue
            elif not getattr(base_model, '__parameters__', None):
                # base_model is "GenericModel"  (and has no __parameters__)
                # or
                # base_model is already concrete, and will be included transitively via cls.
                continue
            elif cls in _assigned_parameters:
                if base_model in _assigned_parameters:
                    # cls is partially parameterised but not from base_model
                    # e.g. cls = B[S], base_model = A[S]
                    # B[S][int] should subclass A[int],  (and will be transitively via B[int])
                    # but it's not viable to consistently subclass types with arbitrary construction
                    # So don't attempt to include A[S][int]
                    continue
                else:  # base_model not in _assigned_parameters:
                    # cls is partially parameterized, base_model is original generic
                    # e.g.  cls = B[str, T], base_model = B[S, T]
                    # Need to determine the mapping for the base_model parameters
                    mapped_types: Parametrization = {
                        key: typevars_map.get(value, value) for key, value in _assigned_parameters[cls].items()
                    }
                    yield from build_base_model(base_model, mapped_types)
            else:
                # cls is base generic, so base_class has a distinct base
                # can construct the Parameterised base model using typevars_map directly
                yield from build_base_model(base_model, typevars_map)


def replace_types(type_: Any, type_map: Mapping[Any, Any]) -> Any:
    """Return type with all occurrences of `type_map` keys recursively replaced with their values.

    :param type_: Any type, class or generic alias
    :param type_map: Mapping from `TypeVar` instance to concrete types.
    :return: New type representing the basic structure of `type_` with all
        `typevar_map` keys recursively replaced.

    >>> replace_types(Tuple[str, Union[List[str], float]], {str: int})
    Tuple[int, Union[List[int], float]]

    """
    if not type_map:
        return type_

    type_args = get_args(type_)
    origin_type = get_origin(type_)

    if origin_type is Annotated:
        annotated_type, *annotations = type_args
        return Annotated[replace_types(annotated_type, type_map), tuple(annotations)]

    if (origin_type is ExtLiteral) or (sys.version_info >= (3, 8) and origin_type is Literal):
        return type_map.get(type_, type_)
    # Having type args is a good indicator that this is a typing module
    # class instantiation or a generic alias of some sort.
    if type_args:
        resolved_type_args = tuple(replace_types(arg, type_map) for arg in type_args)
        if all_identical(type_args, resolved_type_args):
            # If all arguments are the same, there is no need to modify the
            # type or create a new object at all
            return type_
        if (
            origin_type is not None
            and isinstance(type_, typing_base)
            and not isinstance(origin_type, typing_base)
            and getattr(type_, '_name', None) is not None
        ):
            # In python < 3.9 generic aliases don't exist so any of these like `list`,
            # `type` or `collections.abc.Callable` need to be translated.
            # See: https://www.python.org/dev/peps/pep-0585
            origin_type = getattr(typing, type_._name)
        assert origin_type is not None
        # PEP-604 syntax (Ex.: list | str) is represented with a types.UnionType object that does not have __getitem__.
        # We also cannot use isinstance() since we have to compare types.
        if sys.version_info >= (3, 10) and origin_type is types.UnionType:  # noqa: E721
            return _UnionGenericAlias(origin_type, resolved_type_args)
        return origin_type[resolved_type_args]

    # We handle pydantic generic models separately as they don't have the same
    # semantics as "typing" classes or generic aliases
    if not origin_type and lenient_issubclass(type_, GenericModel) and not type_.__concrete__:
        type_args = type_.__parameters__
        resolved_type_args = tuple(replace_types(t, type_map) for t in type_args)
        if all_identical(type_args, resolved_type_args):
            return type_
        return type_[resolved_type_args]

    # Handle special case for typehints that can have lists as arguments.
    # `typing.Callable[[int, str], int]` is an example for this.
    if isinstance(type_, (List, list)):
        resolved_list = list(replace_types(element, type_map) for element in type_)
        if all_identical(type_, resolved_list):
            return type_
        return resolved_list

    # For JsonWrapperValue, need to handle its inner type to allow correct parsing
    # of generic Json arguments like Json[T]
    if not origin_type and lenient_issubclass(type_, JsonWrapper):
        type_.inner_type = replace_types(type_.inner_type, type_map)
        return type_

    # If all else fails, we try to resolve the type directly and otherwise just
    # return the input with no modifications.
    new_type = type_map.get(type_, type_)
    # Convert string to ForwardRef
    if isinstance(new_type, str):
        return ForwardRef(new_type)
    else:
        return new_type


def check_parameters_count(cls: Type[GenericModel], parameters: Tuple[Any, ...]) -> None:
    actual = len(parameters)
    expected = len(cls.__parameters__)
    if actual != expected:
        description = 'many' if actual > expected else 'few'
        raise TypeError(f'Too {description} parameters for {cls.__name__}; actual {actual}, expected {expected}')


DictValues: Type[Any] = {}.values().__class__


def iter_contained_typevars(v: Any) -> Iterator[TypeVarType]:
    """Recursively iterate through all subtypes and type args of `v` and yield any typevars that are found."""
    if isinstance(v, TypeVar):
        yield v
    elif hasattr(v, '__parameters__') and not get_origin(v) and lenient_issubclass(v, GenericModel):
        yield from v.__parameters__
    elif isinstance(v, (DictValues, list)):
        for var in v:
            yield from iter_contained_typevars(var)
    else:
        args = get_args(v)
        for arg in args:
            yield from iter_contained_typevars(arg)


def get_caller_frame_info() -> Tuple[Optional[str], bool]:
    """
    Used inside a function to check whether it was called globally

    Will only work against non-compiled code, therefore used only in pydantic.generics

    :returns Tuple[module_name, called_globally]
    """
    try:
        previous_caller_frame = sys._getframe(2)
    except ValueError as e:
        raise RuntimeError('This function must be used inside another function') from e
    except AttributeError:  # sys module does not have _getframe function, so there's nothing we can do about it
        return None, False
    frame_globals = previous_caller_frame.f_globals
    return frame_globals.get('__name__'), previous_caller_frame.f_locals is frame_globals


def _prepare_model_fields(
    created_model: Type[GenericModel],
    fields: Mapping[str, Any],
    instance_type_hints: Mapping[str, type],
    typevars_map: Mapping[Any, type],
) -> None:
    """
    Replace DeferredType fields with concrete type hints and prepare them.
    """

    for key, field in created_model.__fields__.items():
        if key not in fields:
            assert field.type_.__class__ is not DeferredType
            # https://github.com/nedbat/coveragepy/issues/198
            continue  # pragma: no cover

        assert field.type_.__class__ is DeferredType, field.type_.__class__

        field_type_hint = instance_type_hints[key]
        concrete_type = replace_types(field_type_hint, typevars_map)
        field.type_ = concrete_type
        field.outer_type_ = concrete_type
        field.prepare()
        created_model.__annotations__[key] = concrete_type