From now on, the old JVM backend will report an error by default when
compiling against class files produced by the JVM IR backend. This is
needed because we're not yet sure that the ABI generated by JVM IR is
fully correct and do not want to land in a 2-dimensional compatibility
situation where we'll need to consider twice more scenarios when
introducing any breaking change in the language. This is generally OK
since the JVM IR backend is still going to be experimental in 1.4.
However, for purposes of users which _do_ need to compile something with
the old backend against JVM IR, we provide two new compiler flags:
* -Xallow-jvm-ir-dependencies -- allows to suppress the error when
compiling with the old backend against JVM IR.
* -Xir-binary-with-stable-api -- allows to mark the generated binaries
as stable, when compiling anything with JVM IR, so that dependent
modules will compile even with the old backend automatically. In this
case, the author usually does not care for the generated ABI, or s/he
ensures that it's consistent with the one expected by the old compiler
with some external tools.
Internally, this is implemented by storing two new flags in
kotlin.Metadata: one tells if the class file was compiled with the JVM
IR, and another tells if the class file is stable (in case it's compiled
with JVM IR). Implementation is similar to the diagnostic reported by
the pre-release dependency checker.
Sometimes IC raises compilation errors when rebuild succeeds.
This happens because IC uses serialized decriptors
for non-dirty files. Serialized descriptors can be different
from source file descriptors. For example, a source file
may contain an implicit return type or an implicit visibility
for overridden methods, but serialized descriptors always
contain explicit return types & methods' visibilities.
These problems can be solved by expanding a scope of incremental compilation
just after the analysis, but before error reporting & code generation.
In other words, we need to compare descriptors before error reporting and code generation.
If there are new dirty files, current round of IC must be aborted,
next round must be performed with new dirty files.
This commit implements IC scope expansion for JS Klib compiler
#KT-13677
#KT-28233
An uninferred parameter stub may leak through calculation of CST(Inv<Uninferred Stub>, Nothing) into a result type.
A stub type in the result type means a type error. So we can afford recalculating
CST with stub-containing types filtered out, since its an error anyway.
This prevents stub types leakages and helps with reporting type error diagnostics.
KT-35914 Fixed
KT-35943 Fixed
The problem in the added test was that a suspend lambda was represented
by a function reference with a bound argument for the ObjectRef value,
and the corresponding parameter was not the first parameter of the
referenced local function. This happens because
LocalDeclarationsLowering lifts the local function up and adds a
new parameter for the captured ObjectRef (which is bound at the call
site), but the original receiver parameter remains the first unbound
parameter. So, it's no longer correct to rely on the fact that all bound
parameters of a function reference are located in the beginning of the
parameter list, which was kind of assumed in the `withIndex` call in
`AddContinuationLowering.addCreate`.
Also,
1. remove some redundant copies;
2. fix remapping of non-local returns in lambdas if the body is moved
after LocalDeclarationsLowering (the lambda is no longer inside the
body, but must still be visited)
Old version handled only private companions correctly.
Some situations require multiple companion object accessors
(including accessors for protected companion objects from supertypes)
to be generated in the corresponding class.
SyntheticAccessorLowering was initially implemented under the assumption
that any access to an invisible declaration will cause an accessor to be
generated _in the same file_. Moreover, it's declared in the group of
phases that are performed by file.
But this assumption is incorrect for constructors which need to be
hidden (those which take parameters of inline class types), since such
constructor is public and can be called from anywhere. In this case,
SyntheticAccessorLowering actually generated a new accessor for the
hidden constructor for each (!) source file where that constructor is
called, which led to ClassFormatError because of the class file having
multiple methods with the same signature. The internal `functionMap`
cache didn't help because it's not shared among phase instances for
different files (well, it helped to generate not more than one accessor
per usage-file).
In this change, we use the global cache, stored in JvmBackendContext,
for accessors to hidden constructors. Note that after this change, calls
to hidden constructors are always transformed to the corresponding
accessor in SyntheticAccessorLowering right away, but that accessor
might be orphaned for a while (not declared in any parent's
declarations). Only when SyntheticAccessorLowering encounters the
original constructor which needs to be hidden, it adds the accessor
beside it.
The test is sensitive to the file order, so both variants are added.
It's no longer needed since we going to start building libraries using the new BE,
so we have to be sure that everything works well in releases branches too.
Previously JS IR versions of stdlib and kotlin-test were build
by default using compiler previously built on a buildserver.
It had some issues:
- This required us to advance bootstrap every time we made any
incompatible IR changes. This happens often since IR ABI is
not quite stable yet.
- We never tested the exact combination of compiler and stdlib we publish
We tested:
- new compiler with new stdlib build by new compiler (in box tests)
- old compiler with new stdlib build by old compiler (in stdlib tests)
We published:
- new compiler with new stdlib build by old compiler
After this change JS IR compiler tests, builds and publishes
single configuration:
new compiler with new stdlib build by new compiler
JS IR stdlib and kotlin-test are now built using JavaExec of CLI instead
of Gradle plugin to avoid troubles of loading a freshly built plugin.
This also allows to have a granular dependencies: we don't rebuild klib
if we changed a lowering in a compiler backend, but we do rebuild it if
we changed IR serialization algorithm.