With `-experimental-lazy-typecheck` specified during module interface emission,
`collectProtocols()` may be the first piece of code to request the extended
type for a given extension and it therefore needs to ignore invalid extensions
and ensure that diagnostics are emitted.
Also, add some `PrettyStackTrace` coverage to `ModuleInterfaceSupport.cpp` to make
investigating future issues easier.
Resolves rdar://126232836.
This patch adds support for MCCAS when a cache hit is encountered when
trying to replay a compilation, and uses the MCCAS serialization code
to materialize the object file that is the main output of the
compilation.
There are two axes on which a saved frontend flag can be categorized for
printing in a `.swiftinterface` file:
1. Whether the flag is "ignorable" or not.
2. Which levels of interface the flag should be in (public, package).
This refactor ensures that those two axes are modeled independently and
prepares the infrastructure to allow flags to appear in the private and package
interfaces without being included in the public interface.
Having package-name flag in non-package interfaces causes them to be built as if
belonging to a package, which causes an issue for a loading client outside of the
package as follows.
For example, when building X that depends on A with the following dependency chain:
X --> A --> B --(package-only)--> C
1. X itself is not in the same package as A, B, and C.
2. When dependency scanning X, and opening up B, because the scan target is in a
different package domain, the scanner decides that B's package-only dependency
on C is to be ignored.
3. When then finally building A itself, it will load its dependencies, but because
the .private.swiftinterface of A still specifies -package-name, when it loads
B, it will then examine its dependencies and deem that this package-only dependency
on C is required.
Because (2) and (3) disagree, we get an error now when building the private A textual interface.
rdar://130701866
Fix the problem that when the only module can be found is an
invalid/out-of-date swift binary module, canImport and import statement
can have different view for if the module can be imported or not.
Now canImport will evaluate to false if the only module can be found for
name is an invalid swiftmodule, with a warning with the path to the
module so users will not be surprised by such behavior.
rdar://128876895
Add support for serialized diagnostics, parseable output, and other
kinds of output from diagnostics engine to the libSwiftScan
replayCompilation API.
rdar://129015959
We cannot always rely on being able to do so only as an overlay query upon loading 'requires cplusplus' modulemap modules. The 'requires' statement only applies to submodules, and we may not be able to query language feature modulemap attributes in dependency scanning context.
Add a fast path to create swift CompilerInstance when it is only used to
replay output when there is a cache hit. The normal `setup` function is
very expensive to call, especially in cache mode to setup inputs, and it
needs to be called once per input file from libSwiftScan API due to the
current caching granularity.
The fast path will only construct the part that is needed for output
replay, including the CAS, the output backend and caching diagnostic
processor.
rdar://127062609
This change introduces a new compilation target platform to the Swift compiler - visionOS.
- Changes to the compiler build infrastrucuture to support building compiler-adjacent artifacts and test suites for the new target.
- Addition of the new platform kind definition.
- Support for the new platform in language constructs such as compile-time availability annotations or runtime OS version queries.
- Utilities to read out Darwin platform SDK info containing platform mapping data.
- Utilities to support re-mapping availability annotations from iOS to visionOS (e.g. 'updateIntroducedPlatformForFallback', 'updateDeprecatedPlatformForFallback', 'updateObsoletedPlatformForFallback').
- Additional tests exercising platform-specific availability handling and availability re-mapping fallback code-path.
- Changes to existing test suite to accomodate the new platform.
Relying on the corresponding field in the '-explicit-swift-module-map-file' provided by the driver.
Only bridging headers require a module map because that's what aids header include resolution. With lazy module loading today, '.modulemap' parsing which happens when instantiating Clang is responsible for associating headers with modules. Then upon encountering a header include inside the bridging header the compiler knows which module corresponds to said header and is then able to load explicitly-provided PCM for that module. For all other module dependencies, they are only ever queried by-name from Swift, so '.modulemap' parsing is not necessary.
When building a module from its interface, do not diagnose whether or not a
feature is available in production compilers. This is important since older
compilers may be expected to build .swiftinterfaces that were produced by newer
compilers where the feature has been enabled by default.
Resolves rdar://125500318
allow a more standard way to pass experimental features
from build systems. Also moved other flags relevant to
diagnostics from Frontend options to Lang options.
Ref: rdar://124648653
Do not encode cache invariant command-line flags in DWARF since those
flag should not affect code generation or diagnostics. This avoids
generating conflicting cache entry when caching is enabled, and will
make normal incremental builds more likely to hit fast skip codegen
path.
rdar://124222904
In certain cases (e.g. using arm64e interface to build arm64 target),
the target needs to be updated when building swiftinterface. Push the
target overwrite as early as possible to swiftinterface parsing by
providing a preferred target to relevant functions. In such cases, the
wrong target is never observed by other functions to avoid errors like
the sub-invocation was partially setup for the wrong target.
we only check if the loaded module is built from a package interface. This is
not enough as a binary module could just contain exportable decls if built with
experimental-skip-non-exportable-decls, essentially resulting in content equivalent
to interface content. This might be made a default behavior so this PR requires
a module to opt in to allow non-resilient access by a participating client in the
same package.
Since it affects module format, SWIFTMODULE_VERSION_MINOR is updated.
rdar://123651270
ClangImporter’s SwiftLookupTables map Swift names to their corresponding Clang declarations. These tables are built into a module’s clang .pcm file and missing or inaccurate entries can cause name lookup to fail to find an imported declaration.
Swift has always included a helper function that would dump these tables, and swift-ide-test has a command-line switch that would invoke it, but these tools are clumsy to use in many debugging scenarios. Add a frontend flag that dumps the tables at the end of the frontend job, making it a lot easier to get at this information in the context of a specific compilation.
When scanning finds a dependency in the same package, do not load
public/private swiftinterface since they do not have the package level
decl to compile the current module. Always prefer package module (if
enabled), or use binary module, unless it is building a public/private
swiftinterface file in which case the interface file is preferred.
This also does some clean up to sync up the code path between implicit
and explicit module finding path.
rdar://122356964
Swift interfaces currently aren't meant to expose C++ in their API so we should not also bring in this C++-related module dependency which is not found when the ClangImporter is not configured for C++.
We were re-parsing each source file for each top-level diagnostic emitted,
which is... rather inefficient. Cache the parsed source files until
the PrintingDiagnosticConsumer goes away.
The SDK build version is a decent heuristic for expected changes in the
SDK. Any change in SDK, to clang headers in particular, can break
references from cached swiftmodules.
Track the SDK build version as part of the swiftmodule cache hash. This
will ensure we rebuild from swiftinterfaces on SDK updates.
rdar://122655978
A swiftmodule can only be correctly ingested by a compiler
that has a matching state of using or not-using
NoncopyableGenerics.
The reason for this is fundamental: the absence of a Copyable
conformance in the swiftmodule indicates that a type is
noncopyable. Thus, if a compiler with NoncopyableGenerics
reads a swiftmodule that was not compiled with that feature,
it will think every type in that module is noncopyable.
Similarly, if a compiler with NoncopyableGenerics produces a
swiftmodule, there will be Copyable requirements on each
generic parameter that the compiler without the feature will
become confused about.
The solution here is to trigger a module mismatch, so that
the compiler re-generates the swiftmodule file using the
swiftinterface, which has been kept compatible with the compiler
regardless of whether the feature is enabled.
