If 'this' (implicit or explicit) was used as an extension receiver,
and the corresponding call required a smart-cast,
this information was effectively lost in "old" resolution & inference,
but is required by "old" JVM BE to generate proper CHECKCASTs.
In "short" version, LHS is always evaluated before RHS,
and RHS may be not evaluated if LHS is null.
So, it makes sense to use "short" version in cases when RHS can't have
side effects (because of more compact bytecode and more opportunities
for code elimination).
This makes sense for non-floating-point primitive type
(boolean, char, byte, short, int, long):
floating-point types use specialized versions of 'areEqual'.
Design decision: if the field for a companion object should have
non-public visibility, generate it with @Deprecated annotation in
language version 1.2.
TODO: generate it with proper visibility in 1.3 and later.
KT-11567 Companion object INSTANCE field more visible than companion object class itself
Dex ignores subsequent line numbers for same instructions and interprets
instruction after inline as if they were inlined. This makes debugger
behaves as if there's nowhere to stop on line with breakpoint.
This also makes stepping through inline function consistent with
non-inline analog. In both context debugger now stops on '}'.
#KT-18949 Fixed
#KT-17120 Fixed
The problem is that now that the local delegated property metadata is in
the $$delegatedProperties array of the containing class, the access to
it from code calling an inline function with a local delegated property
is illegal.
Currently it seems to be a lot of work to support this rather rare case
properly (see the comment in ExpressionCodegen.getVariableMetadataValue)
so we postpone it and return the old behavior of using the anonymous
KProperty subclass for metadata
Initialization of companion object members (e.g., delegate properties
using provideDelegate convention) can depend on property metadata array,
which in turn can be initialized before other class members.
#KT-18902 Fixed Target versions 1.1.5
When we have some custom implementation of Comparable, it's important
that we compare values exactly as 'lowBound <= a && a <= highBound'.
Make sure that evaluation order and compareTo calls match for
optimized and non-optimized case.
As of Kotlin 1.0 and 1.1, expression 'a in x .. y' is considered
equivalent to 'x.rangeTo(y).a', and should be evaluated in the following
order:
1. x
2. y
3. a
4. compare x with a
5. compare y with a (if needed)
It's safe to upcast integer types to Long,
floating-point types to Double.
So we don't have to create a range instance for cases such as
fun testLongInInt(x: Long, a: Int, b: Int) =
x in a .. b
which is equivalent to
fun testLongInInt(x: Long, a: Int, b: Int) =
x in a.toLong() .. b.toLong()
DUP_X1; POP = SWAP
p1_a; p1_b; SWAP = p1_b; p1_a
where p1_a, p1_b are instructions without side effects pushing value of
size 1 on stack.
E.g.: ACONST_NULL; ALOAD 0; SWAP = ALOAD 0; ACONST_NULL
NOP; NOP = NOP
Provide BoundedValue-based implementation of InExpressionGenerator,
test it on range of comparable values.
Drop unneeded test (range of comparables is already tested by
ranges/contains/inComparableRanges.kt).
Dmitry Petrov