| from __future__ import annotations | |
| from typing import ( | |
| TYPE_CHECKING, | |
| Generic, | |
| Iterable, | |
| Iterator, | |
| Mapping, | |
| Sequence, | |
| ) | |
| from .structs import CT, KT, RT, Matches, RequirementInformation | |
| if TYPE_CHECKING: | |
| from typing import Any, Protocol | |
| class Preference(Protocol): | |
| def __lt__(self, __other: Any) -> bool: ... | |
| class AbstractProvider(Generic[RT, CT, KT]): | |
| """Delegate class to provide the required interface for the resolver.""" | |
| def identify(self, requirement_or_candidate: RT | CT) -> KT: | |
| """Given a requirement or candidate, return an identifier for it. | |
| This is used to identify, e.g. whether two requirements | |
| should have their specifier parts merged or a candidate matches a | |
| requirement via ``find_matches()``. | |
| """ | |
| raise NotImplementedError | |
| def get_preference( | |
| self, | |
| identifier: KT, | |
| resolutions: Mapping[KT, CT], | |
| candidates: Mapping[KT, Iterator[CT]], | |
| information: Mapping[KT, Iterator[RequirementInformation[RT, CT]]], | |
| backtrack_causes: Sequence[RequirementInformation[RT, CT]], | |
| ) -> Preference: | |
| """Produce a sort key for given requirement based on preference. | |
| As this is a sort key it will be called O(n) times per backtrack | |
| step, where n is the number of `identifier`s, if you have a check | |
| which is expensive in some sense. E.g. It needs to make O(n) checks | |
| per call or takes significant wall clock time, consider using | |
| `narrow_requirement_selection` to filter the `identifier`s, which | |
| is applied before this sort key is called. | |
| The preference is defined as "I think this requirement should be | |
| resolved first". The lower the return value is, the more preferred | |
| this group of arguments is. | |
| :param identifier: An identifier as returned by ``identify()``. This | |
| identifies the requirement being considered. | |
| :param resolutions: Mapping of candidates currently pinned by the | |
| resolver. Each key is an identifier, and the value is a candidate. | |
| The candidate may conflict with requirements from ``information``. | |
| :param candidates: Mapping of each dependency's possible candidates. | |
| Each value is an iterator of candidates. | |
| :param information: Mapping of requirement information of each package. | |
| Each value is an iterator of *requirement information*. | |
| :param backtrack_causes: Sequence of *requirement information* that are | |
| the requirements that caused the resolver to most recently | |
| backtrack. | |
| A *requirement information* instance is a named tuple with two members: | |
| * ``requirement`` specifies a requirement contributing to the current | |
| list of candidates. | |
| * ``parent`` specifies the candidate that provides (depended on) the | |
| requirement, or ``None`` to indicate a root requirement. | |
| The preference could depend on various issues, including (not | |
| necessarily in this order): | |
| * Is this package pinned in the current resolution result? | |
| * How relaxed is the requirement? Stricter ones should probably be | |
| worked on first? (I don't know, actually.) | |
| * How many possibilities are there to satisfy this requirement? Those | |
| with few left should likely be worked on first, I guess? | |
| * Are there any known conflicts for this requirement? We should | |
| probably work on those with the most known conflicts. | |
| A sortable value should be returned (this will be used as the ``key`` | |
| parameter of the built-in sorting function). The smaller the value is, | |
| the more preferred this requirement is (i.e. the sorting function | |
| is called with ``reverse=False``). | |
| """ | |
| raise NotImplementedError | |
| def find_matches( | |
| self, | |
| identifier: KT, | |
| requirements: Mapping[KT, Iterator[RT]], | |
| incompatibilities: Mapping[KT, Iterator[CT]], | |
| ) -> Matches[CT]: | |
| """Find all possible candidates that satisfy the given constraints. | |
| :param identifier: An identifier as returned by ``identify()``. All | |
| candidates returned by this method should produce the same | |
| identifier. | |
| :param requirements: A mapping of requirements that all returned | |
| candidates must satisfy. Each key is an identifier, and the value | |
| an iterator of requirements for that dependency. | |
| :param incompatibilities: A mapping of known incompatibile candidates of | |
| each dependency. Each key is an identifier, and the value an | |
| iterator of incompatibilities known to the resolver. All | |
| incompatibilities *must* be excluded from the return value. | |
| This should try to get candidates based on the requirements' types. | |
| For VCS, local, and archive requirements, the one-and-only match is | |
| returned, and for a "named" requirement, the index(es) should be | |
| consulted to find concrete candidates for this requirement. | |
| The return value should produce candidates ordered by preference; the | |
| most preferred candidate should come first. The return type may be one | |
| of the following: | |
| * A callable that returns an iterator that yields candidates. | |
| * An collection of candidates. | |
| * An iterable of candidates. This will be consumed immediately into a | |
| list of candidates. | |
| """ | |
| raise NotImplementedError | |
| def is_satisfied_by(self, requirement: RT, candidate: CT) -> bool: | |
| """Whether the given requirement can be satisfied by a candidate. | |
| The candidate is guaranteed to have been generated from the | |
| requirement. | |
| A boolean should be returned to indicate whether ``candidate`` is a | |
| viable solution to the requirement. | |
| """ | |
| raise NotImplementedError | |
| def get_dependencies(self, candidate: CT) -> Iterable[RT]: | |
| """Get dependencies of a candidate. | |
| This should return a collection of requirements that `candidate` | |
| specifies as its dependencies. | |
| """ | |
| raise NotImplementedError | |
| def narrow_requirement_selection( | |
| self, | |
| identifiers: Iterable[KT], | |
| resolutions: Mapping[KT, CT], | |
| candidates: Mapping[KT, Iterator[CT]], | |
| information: Mapping[KT, Iterator[RequirementInformation[RT, CT]]], | |
| backtrack_causes: Sequence[RequirementInformation[RT, CT]], | |
| ) -> Iterable[KT]: | |
| """ | |
| An optional method to narrow the selection of requirements being | |
| considered during resolution. This method is called O(1) time per | |
| backtrack step. | |
| :param identifiers: An iterable of `identifiers` as returned by | |
| ``identify()``. These identify all requirements currently being | |
| considered. | |
| :param resolutions: A mapping of candidates currently pinned by the | |
| resolver. Each key is an identifier, and the value is a candidate | |
| that may conflict with requirements from ``information``. | |
| :param candidates: A mapping of each dependency's possible candidates. | |
| Each value is an iterator of candidates. | |
| :param information: A mapping of requirement information for each package. | |
| Each value is an iterator of *requirement information*. | |
| :param backtrack_causes: A sequence of *requirement information* that are | |
| the requirements causing the resolver to most recently | |
| backtrack. | |
| A *requirement information* instance is a named tuple with two members: | |
| * ``requirement`` specifies a requirement contributing to the current | |
| list of candidates. | |
| * ``parent`` specifies the candidate that provides (is depended on for) | |
| the requirement, or ``None`` to indicate a root requirement. | |
| Must return a non-empty subset of `identifiers`, with the default | |
| implementation being to return `identifiers` unchanged. Those `identifiers` | |
| will then be passed to the sort key `get_preference` to pick the most | |
| prefered requirement to attempt to pin, unless `narrow_requirement_selection` | |
| returns only 1 requirement, in which case that will be used without | |
| calling the sort key `get_preference`. | |
| This method is designed to be used by the provider to optimize the | |
| dependency resolution, e.g. if a check cost is O(m) and it can be done | |
| against all identifiers at once then filtering the requirement selection | |
| here will cost O(m) but making it part of the sort key in `get_preference` | |
| will cost O(m*n), where n is the number of `identifiers`. | |
| Returns: | |
| Iterable[KT]: A non-empty subset of `identifiers`. | |
| """ | |
| return identifiers | |