Kotlin code for Objective-C interop is always included to stdlib.
It depends on some C++ code. The latter is compiled conditionally -
only for targets supporting Objective-C interop. That might cause
undefined symbols problems when DCE is not enabled.
To deal with it, we usually have trivial stubs in C++ code, used
for targets not supporting Objective-C interop.
This commit adds a couple of such missing stubs.
In case of HMPP structure with common JVM module (e.g. shared between
JVM and Android) one can reference the same field from java code,
so it should be shared between fir2ir sessions
^KT-63574 Fixed
This bug spilled into reference shortener, and then to
"redundant qualifier inspection" and code completion from there;
it caused KTIJ-26024 to reproduce again (but only for anonymous objects)
^KT-64186 Fixed
The entire concept of conventions is deprecated in Gradle. Here it was making the build logic implicit and hard for understanding
^KTI-1473 In Progress
The entire concept of conventions is deprecated in Gradle. The proposed alternative for `BasePluginConvention` is `BasePluginExtension`
^KTI-1473 In Progress
It's going to be deprecated in Gradle 8.3
There's currently no way to pass a `org.gradle.api.provider.Provider` to the JavaExec.systemProperty or Test.systemProperty. There's a workaround using `org.gradle.process.CommandLineArgumentProvider`, but I intentionally don't rework these calls as Gradle is going to allow passing providers to configure system properties: https://github.com/gradle/gradle/issues/12247#issuecomment-1568427242
^KTI-1473 In Progress
e5ae32c removed bitcode embedding from tests. In particular, that commit
disabled bitcode embedding when compiling Swift code (e.g. in ObjCExport
tests).
It seems that bitcode embedding also enables adhoc codesigning in the
linker.
The linker doesn't seem to do adhoc codesigning by default for tvOS
arm64 simulator target, and without a signature the binaries can't run
on the simulator.
So disabling bitcode embedding also disabled adhoc codesigning and made
the tests fail on that target.
Fix this by explicitly passing `-Xlinker -adhoc_codesign` when compiling
Swift code in tests.
This commit is Low Level FIR part of changes around propagated
annotations (aka foreign annotations).
It includes such changes as:
* implicit type phase postpones foreign annotations resolution
* annotation arguments are requests resolution for postponed
annotations from implicit type phase as a pre-resolve step
* body resolve phase just calls lazy resolution for foreign annotations
on demand
* isResolved check for type annotations to be sure that all annotations
are resolved after annotation arguments phase
^KT-63042 Fixed
^KT-63681 Fixed
We shouldn't transform annotations not from declaration side due to
a possible different context and to avoid unexpected transformation of
unrelated declarations
Example:
```kotlin
fun implicitType1() = TopLevelObject.expectedType()
object TopLevelObject {
private const val privateConstVal = "privateConstVal"
fun expectedType(): @Anno(privateConstVal) Int = 4
}
```
Here we will try to transform the annotation from `expectedType`
during `implicitType1` and as the result, we will see unresolved
reference on the declaration side. This commit fixes this issue.
This solution is based on the fact that the compiler anyway will
resolve the propagated annotation on the declaration side.
And it doesn't matter if it is resolved before or after the call site
declaration transformation, because as a global result, we will observe
that all declarations are resolved correctly in the right context.
Hence, this commit fixes the issue in the case of "full resolution"
which is true for the compiler, but it is not correct for Low Level
FIR where we resolve declarations on demand. It will be solved in
the next commits
^KT-63042
Such annotations will be transformed as usual in `FirDeclarationsResolveTransformer.transformRegularClass`.
Also, this transformation doesn't have a corresponding class as a container
^KT-63042