The change is needed for the parallel resolution (^KT-55750), so we can resolve the declaration
under a lock that is specific to this declaration.
Previously, if LL FIR was resolving some FirClass, LL FIR resolved all its children too, and it had no control over what parts of the FIR tree were modified.
The same applied to the designation path, sometimes the classes on the designation path
might be unexpectedly (and without lock) modified.
This commit introduces LLFirResolveTarget, which specifies which exact declarations should be resolved during the lazy resolution of the declaration.
All elements outside the declarations specified for resolve in LLFirResolveTarget, should not be modified.
The logic of lazy transformers is the following:
- Go to target declaration collecting all scopes from the file and containing classes
- Resolve only declarations that are specified by the LLFirResolveTarget, performing the resolve under a separate lock for each declaration
^KT-56543
^KT-57619 Fixed
If property call receiver is something real (like another property or a
function call), then it should not be shortened because the semantics
might change
^KTIJ-25232 Fixed
The existing K2 reference shortener collects all the PSI elements to
shorten. As a result, it possibly shortens duplicated PSI elements. For
example,
```
// FILE: main.kt
package a.b.c
fun test(n: Int) {
return if (<expr>x.y.z.Outer.Inner.VALUE0 > x.y.z.Outer.Inner.VALUE1</expr>) 1
else n
}
// FILE: values.kt
package x.y.z
class Outer {
object Inner {
val VALUE0 = 13
val VALUE1 = 17
}
}
```
for the above code, the existing K2 reference shortener tried to shorten
- x.y.z.Outer.Inner -> Inner
- x.y.z.Outer.Inner.VALUE0 -> VALUE0
- x.y.z.Outer.Inner -> Inner
- x.y.z.Outer.Inner.VALUE1 -> VALUE1
`x.y.z.Outer.Inner` is included in the list to shorten twice.
When it actually shortens the PSI elements, it shortens only
- x.y.z.Outer.Inner.VALUE0 -> VALUE0
- x.y.z.Outer.Inner.VALUE1 -> VALUE1
but it imports all of
- x.y.z.Outer.Inner
- x.y.z.Outer.Inner.VALUE0
- x.y.z.Outer.Inner.VALUE1
As a result, it has unnecessary additional import directives.
This commit fixes the issue by avoiding duplicated shortening for a
single PSI element.
so the check is functionally the same as in K1.
#KT-57064 fixed
#KT-57065 fixed
One of the tests introduced here (javaMappedCtors) revealed an
additional issue, filed as KT-57368
Those scopes always contain all nested classifiers,
while only some of them are available without
explicit import. There are other, more reliable
scopes (like FirNestedClassifierScopeWithSubstitution)
which are stricter about which classifiers
they recognise as valid
^KTIJ-24684 Fixed
^KTIJ-24662 Fixed
If an annotation doesn't specify an explicit use-site target,
previously it was added to both, the primary constructor value parameter
and the property in the FIR. Then, in FIR2IR, only the "correct" one was
added to the IR. Move up the deduplication logic into the frontend.
^KT-56177 Fixed
Support FirStringConcatenationCall in FirCompileTimeConstantEvaluator.
This allows string templates ("foo${bar}") to be evaluated as constants,
assuming the interpolated expressions are themselves constant.
In addition, fixes some handling bugs with KtConstantEvaluationMode,
where some expressions that are not valid in a `const val` declaration
were being supported for `CONSTANT_EXPRESSION_EVALUATION`, including
non-static final Java fields in FIR, and composite expressions of
non-const properties in FE1.0.
- KTIJ-24574 occurred because a local destructuring declaration was
erroneously returned as the non-local containing declaration of an
element by `getNonLocalContainingOrThisDeclaration`. This occurred in
`init` blocks.
KTIJ-24574 fixed
Use expanded ConeTypes to get correct parameters and return types
Also, fix the order of rendering modifiers in `KtFunctionalTypeRenderer`
^KTIJ-24527 Fixed
For the following example, when we run the reference shortener, it
drops `a.b.c` qualifier, because it matches "FOURTH".
```
package a.b.c
fun <T, E, D> foo(a: T, b: E, c: D) = a.hashCode() + b.hashCode() + c.hashCode() // FIRST
fun <E> E.foo() = hashCode() // SECOND
object Receiver {
fun <T, E, D> foo(a: T, b: E, c: D) = a.hashCode() + b.hashCode() + c.hashCode() // THIRD
fun foo(a: Int, b: Boolean, c: String) = a.hashCode() + b.hashCode() + c.hashCode() // FOURTH
fun test(): Int {
fun foo(a: Int, b: Boolean, c: Int) = a + b.hashCode() + c // FIFTH
return <expr>a.b.c.foo(1, false, "bar")</expr>
}
}
```
As shown in the above example, when SHORTEN_IF_ALEADY_IMPORTED option is
given from a user, the reference shortener has to check whether it can
drop the qualifier without changing the referenced symbol and if it is
possible to do that without adding a new import directive, it deletes
the qualifier.
It needs two steps:
1. Collect all candidate symbols matching the signature e.g., function
arguments / type arguments
2. Determine whether the referenced symbol has the highest reference
priority when we drops the qualifier depending on scopes
This commit uses `AllCandidatesResolver(shorteningContext.analysisSession.useSiteSession).
getAllCandidates( .. fake FIR call/property-access ..)` for step1.
For step2, we use a heuristic based on scopes of candidates. If a
candidate symbol is under the same scope with the target expression, it
has a `FirLocalScope` which has the high priority. So when we have a
candidate under a `FirLocalScope` and the actual referenced symbol is
different from the candidate, we must avoid dropping its qualifier
because the shortening will change its semantics i.e., reference.
The order of scopes depending on their scope types is:
1. FirLocalScope
2. FirClassUseSiteMemberScope / FirNestedClassifierScope
3. FirExplicitSimpleImportingScope
4. FirPackageMemberScope
5. others
Note that for "others" the above rule can be wrong. Please update it if
you find other scopes that have a priority higher than the specified
scopes.
One of non-trivial parts is the priority among multiple
FirClassUseSiteMemberScope and FirNestedClassifierScope. They are
basically scopes for class declarations. We decide their priorities
based on the distance of class declaration from the target expression.
Note that we take a strict approach to reject all false positive. For
example, when we are not sure, we don't shorten it to avoid changing its
semantics.
TODO: One corner case is handling receivers. We have to update
```
private fun shortenIfAlreadyImported(
firQualifiedAccess: FirQualifiedAccess,
calledSymbol: FirCallableSymbol<*>,
expressionInScope: KtExpression,
): Boolean
```
The current implementation cannot handle the following example:
```
package foo
class Foo {
fun test() {
// It references FIRST. Removing `foo` lets it reference SECOND.
<caret>foo.myRun {
42
}
}
}
inline fun <R> myRun(block: () -> R): R = block() // FIRST
inline fun <T, R> T.myRun(block: T.() -> R): R = block() // SECOND
```
Tests related to TODO:
- analysis/analysis-api/testData/components/referenceShortener/referenceShortener/receiver2.kt
- analysis/analysis-api/testData/components/referenceShortener/referenceShortener/receiver3.kt
FirReferenceResolveHelper internally checks whether the referenced class
id matches the qualifed access or not. If they do not match, it reports
an error. When the companion object has the same name as the class,
resolving a qualified expression access to a member of the companion
object causes an error because of the mismatch e.g.,
```
package my.sample
class Test {
fun a() {
my.sample.<caret>Test.say()
}
companion object Test {
fun say() {}
}
}
```
This commit fixes the issue.
TODO: When the companion object has a name difference from class, it
does not report an error but the resolution result is wrong in FIR. See
KT-56167.
---
Commentary from rebaser: the issue mentioned in this code is
fixed in 71a368e06e, so the actual
fix is omitted, and only test data is preserved
FunctionalTypeKind can be used in FE 1.0 too, so there is no need to
keep both classes. Also, removal of FunctionClassKind simplifies work
with FunctionalTypeKind in common code, like Analysis Api
and assert that symbol is not a substitution/intersection override
in the `compute` method otherwise.
Because `fakeOverrideSubstitution` should be calculated for all real
implicit types, no call to this method should actually happen.
Otherwise, it can be problematic to create a session
which would contain the full designation path:
`provider.getFirCallableContainerFile(symbol)`
returns `firFile` of a super class which might be from module `a`,
when declaration and its outer classes are from module `b`.
^KTIJ-24105
^ KTIJ-24385
Temp property to store receiver is generated for `a.b++` expression.
If this property's psi corresponds to receiver expr, then FirProperty
would be found by mapper if receiver is requested.
It works unexpectedly, because FirProperty is normally not expected by expression.
This change set fake sources for generated FirProperty, so it won't be found
by source psi
^ KTIJ-24373
when resolving selector expr of a dot qualified expression,
parent qualified expression is resolved
see `KtFirCallResolver.getContainingDotQualifiedExpressionForSelectorExpression`,
Fir is filled with the data. Then,
during final mapping from Fir -> psi, one need to perform the opposite:
take `selectionExpression` to get the initial KtCallExpression
Render KFunctionN and KSuspendFunctionN by their class names, rather
than using arrow syntax. These types have additional functionality
beyond purely being able to invoke them (e.g. getting the name of the
referred function), so using arrow syntax throws away that functionality
and may cause breakages in the resulting code.
Dmitrii Gridin