Foundation needs to be loaded early in the process for Swift's runtime
to properly initialize bridging support; otherwise it may cause issues
like unrecognized selectors. When scripting, load Foundation early in
performFrontend before any swift code runs.
rdar://129528115
UnsafeContinuations can be stored in variables or properties,
so it's important for RemoteMirror to be able to at least minimally
recognize them.
This just treats an UnsafeContinuation as a refcounted pointer.
Which might be "good enough" for now.
Working towards rdar://110351406
Rather than only protecting the insertion and non-const access to
`ContextSpecificCacheMap` in ScanningService, extend the mutex
protection to all accesses. Even a 'const' lookup in the cache map is
not thread safe because the `StringMap` could be in the process of being
rehashed.
rdar://127205953
In this part of the code, we are attempting to merge all of the operands into
the same region and then assigning all non-Sendable results of the function to
that same region. The problem that was occuring here was a thinko due to the
control flow of the code here not separating nicely the case of whether or not
we had operands or not. Previously this did not matter, since we just used the
first result in such a case... but since we changed to assign to the first
operand element in some cases, it matters now. To fix this, I split the confused
logic into two different easy to follow control paths... one if we have operands
and one where we do not have an operand. In the case where we have a first
operand, we merge our elements into its region. If we do not have any operands,
then we just perform one large region assign fresh.
This was not exposed by code that used non-coroutines since in SIL only
coroutines today have multiple results.
rdar://132767643
[Dependency Scanning] Disable validation of Swift dependency modules' existing pre-built candidate binary module files in the scanner, on a non-caching build.
Sema's sendable checking is subsumed by the region isolation SIL pass. Now
that region isolation is always enabled under complete concurrency checking,
the code can be deleted from the actor isolation checker. Note that this
removes these diagnostics from targeted concurrency checking. I think it's
better to remove these diagnostics from targeted checking because in many
cases, they're false positive data-race reports that the programmer ultimately
won't have to address. If we want these diagnostics in targeted checking, we
should do it via region isolation.
Always add constraints, find fixes during simplify.
New separate fix for allow generic function specialization.
Improve parse heuristic for isGenericTypeDisambiguatingToken.
Degrade concrete type specialization fix to warning for macros.
We need this at least until we have 'dependsOn(self)' syntax.
When 'self' is nonescapable and the result is 'void', assume that 'self' depends
on a single nonescapable argument.
If the bodies themselves don't have a
`#sourceLocation` in them, there should be no
harm in skipping; the parsed virtual files get
recorded on the SourceManager, so will be
accessible when doing delayed parsing. The
`InPoundLineEnvironment` flag will be inaccurate,
but that's only needed for the parsing of
`#sourceLocation` itself.
The changes to allow for partial consumption unintentionally also allowed for
`self` to be consumed as a whole during `deinit`, which we don't yet want to
allow because it could lead to accidental "resurrection" and/or accidental
infinite recursion if the consuming method lets `deinit` be implicitly run
again. This makes it an error again. The experimental feature
`ConsumeSelfInDeinit` will allow it for test coverage or experimentation
purposes. rdar://132761460
The reverse-condfail workaround needs to be removed, and this is the
first step to allowing the stdlib to build with conditionally escapable
types.
resolves rdar://132453000
As-is, this default interferes with the incremental build machinery which conservatively assumes that binary module dependencies must cause dependents to be re-built.
The main changes are:
*) Rewrite everything in swift. So far, parts of memory-behavior analysis were already implemented in swift. Now everything is done in swift and lives in `AliasAnalysis.swift`. This is a big code simplification.
*) Support many more instructions in the memory-behavior analysis - especially OSSA instructions, like `begin_borrow`, `end_borrow`, `store_borrow`, `load_borrow`. The computation of end_borrow effects is now much more precise. Also, partial_apply is now handled more precisely.
*) Simplify and reduce type-based alias analysis (TBAA). The complexity of the old TBAA comes from old days where the language and SIL didn't have strict aliasing and exclusivity rules (e.g. for inout arguments). Now TBAA is only needed for code using unsafe pointers. The new TBAA handles this - and not more. Note that TBAA for classes is already done in `AccessBase.isDistinct`.
*) Handle aliasing in `begin_access [modify]` scopes. We already supported truly immutable scopes like `begin_access [read]` or `ref_element_addr [immutable]`. For `begin_access [modify]` we know that there are no other reads or writes to the access-address within the scope.
*) Don't cache memory-behavior results. It turned out that the hit-miss rate was pretty bad (~ 1:7). The overhead of the cache lookup took as long as recomputing the memory behavior.
