## Summary
Closes https://github.com/astral-sh/ty/issues/957
As explained in https://github.com/astral-sh/ty/issues/957, literal
union types for recursively defined values can be widened early to
speed up the convergence of fixed-point iterations.
This PR achieves this by embedding a marker in `UnionType` that
distinguishes whether a value is recursively defined.
This also allows us to identify values that are not recursively
defined, so I've increased the limit on the number of elements in a
literal union type for such values.
Edit: while this PR doesn't provide the significant performance
improvement initially hoped for, it does have the benefit of allowing
the number of elements in a literal union to be raised above the salsa
limit, and indeed mypy_primer results revealed that a literal union of
220 elements was actually being used.
## Test Plan
`call/union.md` has been updated
Fixes https://github.com/astral-sh/ty/issues/1587
## Summary
Perform cycle normalization on typevar bounds and constraints (similar
to how it was already done for typevar defaults) in order to ensure
convergence in cyclic cases.
There might be another fix here that could avoid the cycle in many more
cases, where we don't eagerly evaluate typevar bounds/constraints on
explicit specialization, but just accept the given specialization and
later evaluate to see whether we need to emit a diagnostic on it. But
the current fix here is sufficient to solve the problem and matches the
patterns we use to ensure cycle convergence elsewhere, so it seems good
for now; left a TODO for the other idea.
This fix is sufficient to make us not panic, but not sufficient to get
the semantics fully correct; see the TODOs in the tests. I have ideas
for fixing that as well, but it seems worth at least getting this in to
fix the panic.
## Test Plan
Test that previously panicked now does not.
---------
Co-authored-by: Alex Waygood <Alex.Waygood@Gmail.com>
This makes auto-import include modules in suggestions.
In this initial implementation, we permit this to include submodules as
well. This is in contrast to what we do in `import ...` completions.
It's easy to change this behavior, but I think it'd be interesting to
run with this for now to see how well it works.
The existing importer functionality always required
an import request with a module and a member in that
module. But we want to be able to insert import statements
for a module itself and not any members in the module.
This is basically changing `member: &str` to an
`Option<&str>` and fixing the fallout in a way that
makes sense for module-only imports.
I think changes to this value are generally noise. It's hard to tell
what it means and it isn't especially actionable. We already have an
eval running in CI for completion ranking, so I don't think it's
terribly important to care about ranking here in e2e tests _generally_.
A completion lacking a module reference doesn't necessarily mean that
the symbol is defined within the current module. I believe the intent
here is that it means that no import is required to use it.
These are all improvements here with one slight regression on
`reveal_type` ranking. The previous completions offered were:
```
$ cargo r -q -p ty_completion_eval show-one ty-extensions-lower-stdlib
ENOTRECOVERABLE (module: errno)
REG_WHOLE_HIVE_VOLATILE (module: winreg)
SQLITE_NOTICE_RECOVER_WAL (module: _sqlite3)
SupportsGetItemViewable (module: _typeshed)
removeHandler (module: unittest.signals)
reveal_mro (module: ty_extensions)
reveal_protocol_interface (module: ty_extensions)
reveal_type (module: typing) (*, 8/10)
_remove_original_values (module: _osx_support)
_remove_universal_flags (module: _osx_support)
-----
found 10 completions
```
And now they are:
```
$ cargo r -q -p ty_completion_eval show-one ty-extensions-lower-stdlib
ENOTRECOVERABLE (module: errno)
REG_WHOLE_HIVE_VOLATILE (module: winreg)
SQLITE_NOTICE_RECOVER_WAL (module: sqlite3)
SQLITE_NOTICE_RECOVER_WAL (module: sqlite3.dbapi2)
removeHandler (module: unittest)
removeHandler (module: unittest.signals)
reveal_mro (module: ty_extensions)
reveal_protocol_interface (module: ty_extensions)
reveal_type (module: typing) (*, 9/9)
-----
found 9 completions
```
Some completions were removed (because they are now considered
unexported) and some were added (likely do to better re-export support).
This particular case probably warrants more special attention anyway.
So I think this is fine. (It's only a one-ranking regression.)
This applies recursively. So if *any* component of a module name starts
with a `_`, then symbols from that module are excluded from auto-import.
The exception is when it's a module within first party code. Then we
want to include it in auto-import.
Note that the `Deprecated` symbols from `importlib.metadata` are no
longer offered because 1) `importlib.metadata` defined `__all__` and 2)
the `Deprecated` symbols aren't in it. These seem to not be a part of
its public API according to the docs, so this seems right to me.
This commit (mostly) re-implements the support for `__all__` in
ty-proper, but inside the auto-import AST scanner.
When `__all__` isn't present in a module, we fall back to conventions to
determine whether a symbol is exported or not:
https://docs.python.org/3/library/index.html
However, in keeping with current practice for non-auto-import
completions, we continue to provide sunder and dunder names as
re-exports.
When `__all__` is present, we respect it strictly. That is, a symbol is
exported *if and only if* it's in `__all__`. This is somewhat stricter
than pylance seemingly is. I felt like it was a good idea to start here,
and we can relax it based on user demand (perhaps through a setting).
This simplifies the existing visitor by DRYing it up slightly.
We also add tests for the existing functionality. In particular,
we want to add support for re-export conventions, and that
warrants more careful testing.
## Summary
I realized we don't really test `DefinitionKind::ImportFromSubmodule` in
the IDE at all, so here's a bunch of them, just recording our current
behaviour.
## Test Plan
*stares at the camera*
## Summary
I have no idea what I'm doing with the fix (all the interesting stuff is
in the second commit).
The basic problem is the compiler emits the diagnostic:
```
x: "foobar"
^^^^^^
```
Which the suppression code-action hands the end of to `Tokens::after`
which then panics because that function panics if handed an offset that
is in the middle of a token.
Fixes https://github.com/astral-sh/ty/issues/1748
## Test Plan
Many tests added (only the e2e test matters).
## Summary
This makes an importing file a required argument to module resolution,
and if the fast-path cached query fails to resolve the module, take the
slow-path uncached (could be cached if we want)
`desperately_resolve_module` which will walk up from the importing file
until it finds a `pyproject.toml` (arbitrary decision, we could try
every ancestor directory), at which point it takes one last desperate
attempt to use that directory as a search-path. We do not continue
walking up once we've found a `pyproject.toml` (arbitrary decision, we
could keep going up).
Running locally, this fixes every broken-for-workspace-reasons import in
pyx's workspace!
* Fixes https://github.com/astral-sh/ty/issues/1539
* Improves https://github.com/astral-sh/ty/issues/839
## Test Plan
The workspace tests see a huge improvement on most absolute imports.
Fixes https://github.com/astral-sh/ty/issues/1716.
## Test plan
I added a corpus snippet that causes us to panic on `main` (I tested by
running `cargo run -p ty_python_semantic --test=corpus` without the fix
applied).
## Summary
This PR re-implements [return-in-generator
(B901)](https://docs.astral.sh/ruff/rules/return-in-generator/#return-in-generator-b901)
for async generators as a semantic syntax error. This is not a syntax
error for sync generators, so we'll need to preserve both the lint rule
and the syntax error in this case.
It also updates B901 and the new implementation to catch cases where the
generator's `yield` or `yield from` expression is part of another
statement, as in:
```py
def foo():
return (yield)
```
These were previously not caught because we only looked for
`Stmt::Expr(Expr::Yield)` in `visit_stmt` instead of visiting `yield`
expressions directly. I think this modification is within the spirit of
the rule and safe to try out since the rule is in preview.
## Test Plan
<!-- How was it tested? -->
I have written tests as directed in #17412
---------
Signed-off-by: 11happy <soni5happy@gmail.com>
Signed-off-by: 11happy <bhuminjaysoni@gmail.com>
Co-authored-by: Brent Westbrook <brentrwestbrook@gmail.com>
Co-authored-by: Brent Westbrook <36778786+ntBre@users.noreply.github.com>
## Summary
Star-imports can not just affect the state of symbols that they pull in,
they can also affect the state of members that are associated with those
symbols. For example, if `obj.attr` was previously narrowed from `int |
None` to `int`, and a star-import now overwrites `obj`, then the
narrowing on `obj.attr` should be "reset".
This PR keeps track of the state of associated members during star
imports and properly models the flow of their corresponding state
through the control flow structure that we artificially create for
star-imports.
See [this
comment](https://github.com/astral-sh/ty/issues/1355#issuecomment-3607125005)
for an explanation why this caused ty to see certain `asyncio` symbols
as not being accessible on Python 3.14.
closes https://github.com/astral-sh/ty/issues/1355
## Ecosystem impact
```diff
async-utils (https://github.com/mikeshardmind/async-utils)
- src/async_utils/bg_loop.py:115:31: error[invalid-argument-type] Argument to bound method `set_task_factory` is incorrect: Expected `_TaskFactory | None`, found `def eager_task_factory[_T_co](loop: AbstractEventLoop | None, coro: Coroutine[Any, Any, _T_co@eager_task_factory], *, name: str | None = None, context: Context | None = None) -> Task[_T_co@eager_task_factory]`
- Found 30 diagnostics
+ Found 29 diagnostics
mitmproxy (https://github.com/mitmproxy/mitmproxy)
+ mitmproxy/utils/asyncio_utils.py:96:60: warning[unused-ignore-comment] Unused blanket `type: ignore` directive
- test/conftest.py:37:31: error[invalid-argument-type] Argument to bound method `set_task_factory` is incorrect: Expected `_TaskFactory | None`, found `def eager_task_factory[_T_co](loop: AbstractEventLoop | None, coro: Coroutine[Any, Any, _T_co@eager_task_factory], *, name: str | None = None, context: Context | None = None) -> Task[_T_co@eager_task_factory]`
```
All of these seem to be correct, they give us a different type for
`asyncio` symbols that are now imported from different
`sys.version_info` branches (where we previously failed to recognize
some of these as statically true/false).
```diff
dd-trace-py (https://github.com/DataDog/dd-trace-py)
- ddtrace/contrib/internal/asyncio/patch.py:39:12: error[invalid-argument-type] Argument to function `unwrap` is incorrect: Expected `WrappedFunction`, found `def create_task[_T](self, coro: Coroutine[Any, Any, _T@create_task] | Generator[Any, None, _T@create_task], *, name: object = None) -> Task[_T@create_task]`
+ ddtrace/contrib/internal/asyncio/patch.py:39:12: error[invalid-argument-type] Argument to function `unwrap` is incorrect: Expected `WrappedFunction`, found `def create_task[_T](self, coro: Generator[Any, None, _T@create_task] | Coroutine[Any, Any, _T@create_task], *, name: object = None) -> Task[_T@create_task]`
```
Similar, but only results in a diagnostic change.
## Test Plan
Added a regression test
This fixes a non-determinism that we were seeing in the constraint set
tests in https://github.com/astral-sh/ruff/pull/21715.
In this test, we create the following constraint set, and then try to
create a specialization from it:
```
(T@constrained_by_gradual_list = list[Base])
∨
(Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
```
That is, `T` is either specifically `list[Base]`, or it's any `list`.
Our current heuristics say that, absent other restrictions, we should
specialize `T` to the more specific type (`list[Base]`).
In the correct test output, we end up creating a BDD that looks like
this:
```
(T@constrained_by_gradual_list = list[Base])
┡━₁ always
└─₀ (Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
┡━₁ always
└─₀ never
```
In the incorrect output, the BDD looks like this:
```
(Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
┡━₁ always
└─₀ never
```
The difference is the ordering of the two individual constraints. Both
constraints appear in the first BDD, but the second BDD only contains `T
is any list`. If we were to force the second BDD to contain both
constraints, it would look like this:
```
(Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
┡━₁ always
└─₀ (T@constrained_by_gradual_list = list[Base])
┡━₁ always
└─₀ never
```
This is the standard shape for an OR of two constraints. However! Those
two constraints are not independent of each other! If `T` is
specifically `list[Base]`, then it's definitely also "any `list`". From
that, we can infer the contrapositive: that if `T` is not any list, then
it cannot be `list[Base]` specifically. When we encounter impossible
situations like that, we prune that path in the BDD, and treat it as
`false`. That rewrites the second BDD to the following:
```
(Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
┡━₁ always
└─₀ (T@constrained_by_gradual_list = list[Base])
┡━₁ never <-- IMPOSSIBLE, rewritten to never
└─₀ never
```
We then would see that that BDD node is redundant, since both of its
outgoing edges point at the `never` node. Our BDDs are _reduced_, which
means we have to remove that redundant node, resulting in the BDD we saw
above:
```
(Bottom[list[Any]] ≤ T@constrained_by_gradual_list ≤ Top[list[Any]])
┡━₁ always
└─₀ never <-- redundant node removed
```
The end result is that we were "forgetting" about the `T = list[Base]`
constraint, but only for some BDD variable orderings.
To fix this, I'm leaning in to the fact that our BDDs really do need to
"remember" all of the constraints that they were created with. Some
combinations might not be possible, but we now have the sequent map,
which is quite good at detecting and pruning those.
So now our BDDs are _quasi-reduced_, which just means that redundant
nodes are allowed. (At first I was worried that allowing redundant nodes
would be an unsound "fix the glitch". But it turns out they're real!
[This](https://ieeexplore.ieee.org/abstract/document/130209) is the
paper that introduces them, though it's very difficult to read. Knuth
mentions them in §7.1.4 of
[TAOCP](https://course.khoury.northeastern.edu/csu690/ssl/bdd-knuth.pdf),
and [this paper](https://par.nsf.gov/servlets/purl/10128966) has a nice
short summary of them in §2.)
While we're here, I've added a bunch of `debug` and `trace` level log
messages to the constraint set implementation. I was getting tired of
having to add these by hands over and over. To enable them, just set
`TY_LOG` in your environment, e.g.
```sh
env TY_LOG=ty_python_semantic::types::constraints::SequentMap=trace ty check ...
```
[Note, this has an `internal` label because are still not using
`specialize_constrained` in anything user-facing yet.]
## Summary
For a type alias like the one below, where `UnknownClass` is something
with a dynamic type, we previously lost track of the fact that this
dynamic type was explicitly specialized *with a type variable*. If that
alias is then later explicitly specialized itself (`MyAlias[int]`), we
would miscount the number of legacy type variables and emit a
`invalid-type-arguments` diagnostic
([playground](https://play.ty.dev/886ae6cc-86c3-4304-a365-510d29211f85)).
```py
T = TypeVar("T")
MyAlias: TypeAlias = UnknownClass[T] | None
```
The solution implemented here is not pretty, but we can hopefully get
rid of it via https://github.com/astral-sh/ty/issues/1711. Also, once we
properly support `ParamSpec` and `Concatenate`, we should be able to
remove some of this code.
This addresses many of the `invalid-type-arguments` false-positives in
https://github.com/astral-sh/ty/issues/1685. With this change, there are
still some diagnostics of this type left. Instead of implementing even
more (rather sophisticated) workarounds for these cases as well, it
might be much easier to wait for full `ParamSpec`/`Concatenate` support
and then try again.
A disadvantage of this implementation is that we lose track of some
`@Todo` types and replace them with `Unknown`. We could spend more
effort and try to preserve them, but I'm unsure if this is the best use
of our time right now.
## Test Plan
New Markdown tests.
## Summary
Implement default-specialization of generic type aliases (implicit or
PEP-613) if they are used in a type expression without an explicit
specialization.
closes https://github.com/astral-sh/ty/issues/1690
## Typing conformance
```diff
-generics_defaults_specialization.py:26:5: error[type-assertion-failure] Type `SomethingWithNoDefaults[int, str]` does not match asserted type `SomethingWithNoDefaults[int, DefaultStrT]`
```
That's exactly what we want ✔️
All other tests in this file pass as well, with the exception of this
assertion, which is just wrong (at least according to our
interpretation, `type[Bar] != <class 'Bar'>`). I checked that we do
correctly default-specialize the type parameter which is not displayed
in the diagnostic that we raise.
```py
class Bar(SubclassMe[int, DefaultStrT]): ...
assert_type(Bar, type[Bar[str]]) # ty: Type `type[Bar[str]]` does not match asserted type `<class 'Bar'>`
```
## Ecosystem impact
Looks like I should have included this last week 😎
## Test Plan
Updated pre-existing tests and add a few new ones.
## Summary
This PR implements syntax error where a default type parameter is
followed by a non-default type parameter.
https://github.com/astral-sh/ruff/issues/17412#issuecomment-3584088217
## Test Plan
I have written inline tests as directed in #17412
---------
Signed-off-by: 11happy <bhuminjaysoni@gmail.com>
Signed-off-by: 11happy <soni5happy@gmail.com>
This adds a new `suppression` module to the `ruff_linter` crate, similar
to the suppression
module for ty, to parse comments for ruff suppression directives, such
as `# ruff: disable[CODE]`.
## Summary
Fixes#21750 and a related bug in `PLE1142`. We were not properly
considering generators to be valid `await` contexts, which caused the
`F704` issue. One of the tests I added for this also uncovered an issue
in `PLE1142` for comprehensions nested within async generators because
we were only checking the current scope rather than traversing the
nested context.
## Test Plan
Both of these rules are implemented as semantic syntax errors, so I
added tests (and fixes) in both Ruff and ty.
In the following example, there are two occurrences of `typing.Self`,
one for `Foo.foo` and one for `Bar.bar`:
```py
from typing import Self, reveal_type
class Foo[T]:
def foo(self: Self) -> T:
raise NotImplementedError
class Bar:
def bar(self: Self, x: Foo[Self]):
# SHOULD BE: bound method Foo[Self@bar].foo() -> Self@bar
# revealed: bound method Foo[Self@bar].foo() -> Foo[Self@bar]
reveal_type(x.foo)
def f[U: Bar](x: Foo[U]):
# revealed: bound method Foo[U@f].foo() -> U@f
reveal_type(x.foo)
```
When accessing a bound method, we replace any occurrences of `Self` with
the bound `self` type.
We were doing this correctly for the second reveal. We would first apply
the specialization, getting `(self: Self@foo) -> U@F` as the signature
of `x.foo`. We would then bind the `self` parameter, substituting
`Self@foo` with `Foo[U@F]` as part of that. The return type was already
specialized to `U@F`, so that substitution had no further affect on the
type that we revealed.
In the first reveal, we would follow the same process, but we confused
the two occurrences of `Self`. We would first apply the specialization,
getting `(self: Self@foo) -> Self@bar` as the method signature. We would
then try to bind the `self` parameter, substituting `Self@foo` with
`Foo[Self@bar]`. However, because we didn't distinguish the two separate
`Self`s, and applied the substitution to the return type as well as to
the `self` parameter.
The fix is to track which particular `Self` we're trying to substitute
when applying the type mapping.
Fixes https://github.com/astral-sh/ty/issues/1713
Here are a bunch of (variously failing and passing) mdtests that reflect
the kinds of issues people encounter when running ty over an entire
workspace without sufficient hand-holding (especially because in the IDE
it is unclear *how* to provide that hand-holding).
The `Display` implementation for constraint sets is brittle, and
deserves a rethink. But later! It's perfectly fine for printf debugging;
we just shouldn't be writing mdtests that depend on any particular
rendering details. Most of these tests can be replaced with an
equivalence check that actually validates that the _behavior_ of two
constraint sets are identical.
## Summary
Fixes false positives in SIM222 and SIM223 where truthiness was
incorrectly assumed for `tuple(x)`, `list(x)`, `set(x)` when `x` is not
iterable.
Fixes#21473.
## Problem
`Truthiness::from_expr` recursively called itself on arguments to
iterable initializers (`tuple`, `list`, `set`) without checking if the
argument is iterable, causing false positives for cases like `tuple(0)
or True` and `tuple("") or True`.
## Approach
Added `is_definitely_not_iterable` helper and updated
`Truthiness::from_expr` to return `Unknown` for non-iterable arguments
(numbers, booleans, None) and string literals when called with iterable
initializers, preventing incorrect truthiness assumptions.
## Test Plan
Added test cases to `SIM222.py` and `SIM223.py` for `tuple("")`,
`tuple(0)`, `tuple(1)`, `tuple(False)`, and `tuple(None)` with `or True`
and `and False` patterns.
---------
Co-authored-by: Brent Westbrook <brentrwestbrook@gmail.com>
## Summary
Marks fixes as unsafe when they change return types (`None` → `Path`,
`str`/`bytes` → `Path`, `str` → `Path`), except when the call is a
top-level expression.
Fixes#21431.
## Problem
Fixes for `os.rename`, `os.replace`, `os.getcwd`/`os.getcwdb`, and
`os.readlink` were marked safe despite changing return types, which can
break code that uses the return value.
## Approach
Added `is_top_level_expression_call` helper to detect when a call is a
top-level expression (return value unused). Updated
`check_os_pathlib_two_arg_calls` and `check_os_pathlib_single_arg_calls`
to mark fixes as unsafe unless the call is a top-level expression.
Updated PTH109 to use the helper for applicability determination.
## Test Plan
Updated snapshots for `preview_full_name.py`, `preview_import_as.py`,
`preview_import_from.py`, and `preview_import_from_as.py` to reflect
unsafe markers.
---------
Co-authored-by: Brent Westbrook <brentrwestbrook@gmail.com>
Previously, the code action to do auto-import on a pre-existing symbol
assumed that the auto-importer would always generate an import
statement. But sometimes an import statement already exists.
A good example of this is the following snippet:
```
import warnings
@deprecated
def myfunc(): pass
```
Specifically, `deprecated` exists in `warnings` but isn't currently
imported. A code action to fix this could feasibly do two
transformations here. One is:
```
import warnings
@warnings.deprecated
def myfunc(): pass
```
Another is:
```
from warnings import deprecated
import warnings
@deprecated
def myfunc(): pass
```
The existing auto-import infrastructure chooses the former, since it
reuses a pre-existing import statement. But this PR chooses the latter
for the case of a code action. I'm not 100% sure this is the correct
choice, but it seems to defer more strongly to what the user has typed.
That is, that they want to use it unqualified because it's what has been
typed. So we should add the necessary import statement to make that
work.
Fixesastral-sh/ty#1668
This works by adding a third module resolution mode that lets the caller
opt into _some_ shadowing of modules that is otherwise not allowed (for
`typing` and `typing_extensions`).
Fixesastral-sh/ty#1658
## Summary
If you manage to create an `typing.GenericAlias` instance without us
knowing how that was created, then we don't know what to do with this in
a type annotation. So it's better to be explicit and show an error
instead of failing silently with a `@Todo` type.
## Test Plan
* New Markdown tests
* Zero ecosystem impact
## Summary
We had tests for this already, but they used generic classes that were
bivariant in their type parameter, and so this case wasn't captured.
closes https://github.com/astral-sh/ty/issues/1702
## Test Plan
Updated Markdown tests
## Summary
These projects from `mypy_primer` were missing from both `good.txt` and
`bad.txt` for some reason. I thought about writing a script that would
verify that `good.txt` + `bad.txt` = `mypy_primer.projects`, but that's
not completely trivial since there are projects like `cpython` only
appear once in `good.txt`. Given that we can hopefully soon get rid of
both of these files (and always run on all projects), it's probably not
worth the effort. We are usually notified of all `mypy_primer` changes.
## Test Plan
CI on this PR
## Summary
The exact behavior around what's allowed vs. disallowed was partly
detected through trial and error in the runtime.
I was a little confused by [this
comment](https://github.com/python/cpython/pull/129352) that says
"`NamedTuple` subclasses cannot be inherited from" because in practice
that doesn't appear to error at runtime.
Closes [#1683](https://github.com/astral-sh/ty/issues/1683).
## Summary
This is another small refactor for
https://github.com/astral-sh/ruff/pull/21445 that splits the single
`paramspec.md` into `generics/legacy/paramspec.md` and
`generics/pep695/paramspec.md`.
## Test Plan
Make sure that all mdtests pass.
## Summary
Add support for generic PEP 613 type aliases and generic implicit type
aliases:
```py
from typing import TypeVar
T = TypeVar("T")
ListOrSet = list[T] | set[T]
def _(xs: ListOrSet[int]):
reveal_type(xs) # list[int] | set[int]
```
closes https://github.com/astral-sh/ty/issues/1643
closes https://github.com/astral-sh/ty/issues/1629
closes https://github.com/astral-sh/ty/issues/1596
closes https://github.com/astral-sh/ty/issues/573
closes https://github.com/astral-sh/ty/issues/221
## Typing conformance
```diff
-aliases_explicit.py:52:5: error[type-assertion-failure] Type `list[int]` does not match asserted type `@Todo(specialized generic alias in type expression)`
-aliases_explicit.py:53:5: error[type-assertion-failure] Type `tuple[str, ...] | list[str]` does not match asserted type `@Todo(Generic specialization of types.UnionType)`
-aliases_explicit.py:54:5: error[type-assertion-failure] Type `tuple[int, int, int, str]` does not match asserted type `@Todo(specialized generic alias in type expression)`
-aliases_explicit.py:56:5: error[type-assertion-failure] Type `(int, str, /) -> str` does not match asserted type `@Todo(Generic specialization of typing.Callable)`
-aliases_explicit.py:59:5: error[type-assertion-failure] Type `int | str | None | list[list[int]]` does not match asserted type `int | str | None | list[@Todo(specialized generic alias in type expression)]`
```
New true negatives ✔️
```diff
+aliases_explicit.py:41:36: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
-aliases_explicit.py:57:5: error[type-assertion-failure] Type `(int, str, str, /) -> None` does not match asserted type `@Todo(Generic specialization of typing.Callable)`
+aliases_explicit.py:57:5: error[type-assertion-failure] Type `(int, str, str, /) -> None` does not match asserted type `(...) -> Unknown`
```
These require `ParamSpec`
```diff
+aliases_explicit.py:67:24: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+aliases_explicit.py:68:24: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+aliases_explicit.py:69:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_explicit.py:70:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_explicit.py:71:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_explicit.py:102:20: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
```
New true positives ✔️
```diff
-aliases_implicit.py:63:5: error[type-assertion-failure] Type `list[int]` does not match asserted type `@Todo(specialized generic alias in type expression)`
-aliases_implicit.py:64:5: error[type-assertion-failure] Type `tuple[str, ...] | list[str]` does not match asserted type `@Todo(Generic specialization of types.UnionType)`
-aliases_implicit.py:65:5: error[type-assertion-failure] Type `tuple[int, int, int, str]` does not match asserted type `@Todo(specialized generic alias in type expression)`
-aliases_implicit.py:67:5: error[type-assertion-failure] Type `(int, str, /) -> str` does not match asserted type `@Todo(Generic specialization of typing.Callable)`
-aliases_implicit.py:70:5: error[type-assertion-failure] Type `int | str | None | list[list[int]]` does not match asserted type `int | str | None | list[@Todo(specialized generic alias in type expression)]`
-aliases_implicit.py:71:5: error[type-assertion-failure] Type `list[bool]` does not match asserted type `@Todo(specialized generic alias in type expression)`
```
New true negatives ✔️
```diff
+aliases_implicit.py:54:36: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
-aliases_implicit.py:68:5: error[type-assertion-failure] Type `(int, str, str, /) -> None` does not match asserted type `@Todo(Generic specialization of typing.Callable)`
+aliases_implicit.py:68:5: error[type-assertion-failure] Type `(int, str, str, /) -> None` does not match asserted type `(...) -> Unknown`
```
These require `ParamSpec`
```diff
+aliases_implicit.py:76:24: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+aliases_implicit.py:77:24: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+aliases_implicit.py:78:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_implicit.py:79:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_implicit.py:80:29: error[invalid-type-arguments] Too many type arguments: expected 1, got 2
+aliases_implicit.py:81:25: error[invalid-type-arguments] Type `str` is not assignable to upper bound `int | float` of type variable `TFloat@GoodTypeAlias12`
+aliases_implicit.py:135:20: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
```
New true positives ✔️
```diff
+callables_annotation.py:172:19: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+callables_annotation.py:175:19: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+callables_annotation.py:188:25: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
+callables_annotation.py:189:25: error[invalid-type-arguments] Too many type arguments: expected 0, got 1
```
These require `ParamSpec` and `Concatenate`.
```diff
-generics_defaults_specialization.py:26:5: error[type-assertion-failure] Type `SomethingWithNoDefaults[int, str]` does not match asserted type `SomethingWithNoDefaults[int, typing.TypeVar]`
+generics_defaults_specialization.py:26:5: error[type-assertion-failure] Type `SomethingWithNoDefaults[int, str]` does not match asserted type `SomethingWithNoDefaults[int, DefaultStrT]`
```
Favorable diagnostic change ✔️
```diff
-generics_defaults_specialization.py:27:5: error[type-assertion-failure] Type `SomethingWithNoDefaults[int, bool]` does not match asserted type `@Todo(specialized generic alias in type expression)`
```
New true negative ✔️
```diff
-generics_defaults_specialization.py:30:1: error[non-subscriptable] Cannot subscript object of type `<class 'SomethingWithNoDefaults[int, typing.TypeVar]'>` with no `__class_getitem__` method
+generics_defaults_specialization.py:30:15: error[invalid-type-arguments] Too many type arguments: expected between 0 and 1, got 2
```
Correct new diagnostic ✔️
```diff
-generics_variance.py:175:25: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:175:35: error[non-subscriptable] Cannot subscript object of type `<class 'Co[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:179:29: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:179:39: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:183:21: error[non-subscriptable] Cannot subscript object of type `<class 'Co[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:183:27: error[non-subscriptable] Cannot subscript object of type `<class 'Co[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:187:25: error[non-subscriptable] Cannot subscript object of type `<class 'Co[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:187:31: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:191:33: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:191:43: error[non-subscriptable] Cannot subscript object of type `<class 'Co[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:191:49: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:196:5: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:196:15: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
-generics_variance.py:196:25: error[non-subscriptable] Cannot subscript object of type `<class 'Contra[typing.TypeVar]'>` with no `__class_getitem__` method
```
One of these should apparently be an error, but not of this kind, so
this is good ✔️
```diff
-specialtypes_type.py:152:16: error[invalid-type-form] `typing.TypeVar` is not a generic class
-specialtypes_type.py:156:16: error[invalid-type-form] `typing.TypeVar` is not a generic class
```
Good, those were false positives. ✔️
I skipped the analysis for everything involving `TypeVarTuple`.
## Ecosystem impact
**[Full report with detailed
diff](https://david-generic-implicit-alias.ecosystem-663.pages.dev/diff)**
Previous iterations of this PR showed all kinds of problems. In it's
current state, I do not see any large systematic problems, but it is
hard to tell with 5k diagnostic changes.
## Performance
* There is a huge 4x regression in `colour-science/colour`, related to
[this large
file](https://github.com/colour-science/colour/blob/develop/colour/io/luts/tests/test_lut.py)
with [many assignments of hard-coded arrays (lists of lists) to
`np.NDArray`
types](83e754c8b6/colour/io/luts/tests/test_lut.py (L701-L781))
that we now understand. We now take ~2 seconds to check this file, so
definitely not great, but maybe acceptable for now.
## Test Plan
Updated and new Markdown tests
## Summary
This is a bugfix for subtyping of `type[Any]` / `type[T]` and protocols.
## Test Plan
Regression test that will only be really meaningful once
https://github.com/astral-sh/ruff/pull/21553 lands.
## Summary
**This is the final goto-targets with missing
goto-definition/declaration implementations!
You can now theoretically click on all the user-defined names in all the
syntax. 🎉**
This adds:
* goto definition/declaration on patterns/typevars
* find-references/rename on patterns/typevars
* fixes syntax highlighting of `*rest` patterns
This notably *does not* add:
* goto-type for patterns/typevars
* hover for patterns/typevars (because that's just goto-type for names)
Also I realized we were at the precipice of one of the great GotoTarget
sins being resolved, and so I made import aliases also resolve to a
ResolvedDefinition. This removes a ton of cruft and prevents further
backsliding.
Note however that import aliases are, in general, completely jacked up
when it comes to find-references/renames (both before and after this
PR). Previously you could try to rename an import alias and it just
wouldn't do anything. With this change we instead refuse to even let you
try to rename it.
Sorting out why import aliases are jacked up is an ongoing thing I hope
to handle in a followup.
## Test Plan
You'll surely not regret checking in 86 snapshot tests
## Summary
* Fixes https://github.com/astral-sh/ty/issues/1650
* Part of https://github.com/astral-sh/ty/issues/1610
We now handle:
* `.. warning::` (and friends) by bolding the line and rendering the
block as normal (non-code) text
* `.. code::` (and friends) by treating it the same as `::` (fully
deleted if seen, introduce a code block)
* `.. code:: lang` (and friends) by letting it set the language on the
codefence
* `.. versionchanged:: 1.2.3` (and friends) by rendering it like
`warning` but with the version included and italicized
* `.. dsfsdf-unknown:: (lang)` by assuming it's the same as `.. code::
(lang)`
## Test Plan
Snapshots added/updated. I also deleted a bunch of useless checks on
plaintext rendering. It's important for some edge-case tests but not for
the vast majority of tests.
## Summary
This PR adds a new `db` parameter to `Parameters::new` for
https://github.com/astral-sh/ruff/pull/21445. This change creates a
large diff so thought to split it out as it's just a mechanical change.
The `Parameters::new` method not only creates the `Parameters` but also
analyses the parameters to check what kind it is. For `ParamSpec`
support, it's going to require the `db` to check whether the annotated
type is `ParamSpec` or not. For the current set of parameters that isn't
required because it's only checking whether it's dynamic or not which
doesn't require `db`.
## Summary
Originally I planned to feed this in as a `fix` but I realized that we
probably don't want to be trying to resolve import suggestions while
we're doing type inference. Thus I implemented this as a fallback when
there's no fixes on a diagnostic, which can use the full lsp machinery.
Fixes https://github.com/astral-sh/ty/issues/1552
## Test Plan
Works in the IDE, added some e2e tests.
## Summary
Previously if an explicit specialization failed (e.g. wrong number of
type arguments or violates an upper bound) we just inferred `Unknown`
for the entire type. This actually caused us to panic on an a case of a
recursive upper bound with invalid specialization; the upper bound would
oscillate indefinitely in fixpoint iteration between `Unknown` and the
given specialization. This could be fixed with a cycle recovery
function, but in this case there's a simpler fix: if we infer
`C[Unknown]` instead of `Unknown` for an invalid attempt to specialize
`C`, that allows fixpoint iteration to quickly converge, as well as
giving a more precise type inference.
Other type checkers actually just go with the attempted specialization
even if it's invalid. So if `C` has a type parameter with upper bound
`int`, and you say `C[str]`, they'll emit a diagnostic but just go with
`C[str]`. Even weirder, if `C` has a single type parameter and you say
`C[str, bytes]`, they'll just go with `C[str]` as the type. I'm not
convinced by this approach; it seems odd to have specializations
floating around that explicitly violate the declared upper bound, or in
the latter case aren't even the specialization the annotation requested.
I prefer `C[Unknown]` for this case.
Fixing this revealed an issue with `collections.namedtuple`, which
returns `type[tuple[Any, ...]]`. Due to
https://github.com/astral-sh/ty/issues/1649 we consider that to be an
invalid specialization. So previously we returned `Unknown`; after this
PR it would be `type[tuple[Unknown]]`, leading to more false positives
from our lack of functional namedtuple support. To avoid that I added an
explicit Todo type for functional namedtuples for now.
## Test Plan
Added and updated mdtests.
The conformance suite changes have to do with `ParamSpec`, so no
meaningful signal there.
The ecosystem changes appear to be the expected effects of having more
precise type information (including occurrences of known issues such as
https://github.com/astral-sh/ty/issues/1495 ). Most effects are just
changes to types in diagnostics.
## Summary
Lots of Ruff rules encourage you to make changes that might then cause
ty to start complaining about Liskov violations. Most of these Ruff
rules already refrain from complaining about a method if they see that
the method is decorated with `@override`, but this usually isn't
documented. This PR updates the docs of many Ruff rules to note that
they refrain from complaining about `@override`-decorated methods, and
also adds a similar note to the ty `invalid-method-override`
documentation.
Helps with
https://github.com/astral-sh/ty/issues/1644#issuecomment-3581663859
## Test Plan
- `uvx prek run -a` locally
- CI on this PR
## Summary
This PR updates the explicit specialization logic to avoid using the
call machinery.
Previously, the logic would use the call machinery by converting the
list of type variables into a `Binding` with a single `Signature` where
all the type variables are positional-only parameters with bounds and
constraints as the annotated type and the default type as the default
parameter value. This has the advantage that it doesn't need to
implement any specific logic but the disadvantages are subpar diagnostic
messages as it would use the ones specific to a function call. But, an
important disadvantage is that the kind of type variable is lost in this
translation which becomes important in #21445 where a `ParamSpec` can
specialize into a list of types which is provided using list literal.
For example,
```py
class Foo[T, **P]: ...
Foo[int, [int, str]]
```
This PR converts the logic to use a simple loop using `zip_longest` as
all type variables and their corresponding type argument maps on a 1-1
basis. They cannot be specified using keyword argument either e.g.,
`dict[_VT=str, _KT=int]` is invalid.
This PR also makes an initial attempt to improve the diagnostic message
to specifically target the specialization part by using words like "type
argument" instead of just "argument" and including information like the
type variable, bounds, and constraints. Further improvements can be made
by highlighting the type variable definition or the bounds / constraints
as a sub-diagnostic but I'm going to leave that as a follow-up.
## Test Plan
Update messages in existing test cases.
## Summary
This caused "deterministic but chaotic" ordering of some intersection
types in diagnostics. When calling a union, we infer the argument type
once per matching parameter type, intersecting the inferred types for
the argument expression, and we did that in an unpredictable order.
We do need a hashset here for de-duplication. Sometimes we call large
unions where the type for a given parameter is the same across the
union, we should infer the argument once per parameter type, not once
per union element. So use an `FxIndexSet` instead of an `FxHashSet`.
## Test Plan
With this change, switching between `main` and
https://github.com/astral-sh/ruff/pull/21646 no longer changes the
ordering of the intersection type in the test in
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