IrDeclarationOrigin.FILE_CLASS is used in CallableReferenceLowering to
generate correct declaration owner.
Many reflection tests start to fail with this commit because they are
now treating callable references to top level declarations as Kotlin
symbols and fail because there's no JVM signature for them; this is
fixed in subsequent commits (previously, they worked because without
Kotlin metadata, these files were treated as Java classes)
Most of these tests used this directive as a way to opt in to a new
language feature, and most of those features are already stable for a
long time, so no opt-in is needed. Some other tests used the directive
to opt out from a language feature, replace those by the `LANGUAGE`
directive. One test used the directive to test behavior that actually
depended on the API version; use `API_VERSION` directive there instead.
See how we translate raw types to Kotlin model:
RawType(A) = A<ErasedUpperBound(T1), ...>
ErasedUpperBound(T : G<t>) = G<*> // UpperBound(T) is a type G<t> with arguments
ErasedUpperBound(T : A) = A // UpperBound(T) is a type A without arguments
ErasedUpperBound(T : F) = UpperBound(F) // UB(T) is another type parameter F
Stack overflow happens with the following classes:
class A<X extends B> // NB: raw type B in upper bound
class B<Y extends A> // NB: raw type A in upper bound
when calculating raw type for A, we start calculate ErasedUpperBound(Y),
thus starting calculating raw type for B => ErasedUpperBound(X) => RawType(A),
so we have SOE here.
The problem is that we calculating the arguments for these raw types eagerly,
while from the definition of ErasedUpperBound(Y) we only need a type constructor
of raw type B (and the number of parameters), we don't use its arguments.
The solution is to make arguments calculating for raw types lazy
#KT-16528 Fixed
It works only for Java methods and it's purpose is Java overridability rules emulation,
namely distinction of primitive types and their wrappers.
For example `void foo(Integer x)` should not be an override for `void foo(int x)`
#KT-11440 Fixed
#KT-11389 Fixed
1. ConstantValue
* just holds some value and its type
* implementations for concrete constants
2. CompileTimeConstant
* is only produced by ConstantExpressionEvaluator
* has additional flags (canBeUsedInAnnotation etc)
* has two implementations TypedCompileTimeConstant containing a constant value
and IntegerValueConstant which does not have exact type
* can be converted to ConstantValue
Adjustt usages to use ConstantValue if flags are not needed
Add tests for some uncovered cases
