Use the delayed parsing of function bodies for source imports, and
switch source imports over to lazy type checking. There's no point in
doing a full type check for them.
Lazy parsing for the members of nominal types and extensions depends
only on information already present in
`IterableDeclContext`. Eliminate the use of PersistentParserState as
an intermediary and have the member-parsing request construct a new
`Parser` instance itself to handle parsing. Make this possible even
for ill-formed nominal types/extensions to simplify the code path.
Eliminate `LazyMemberParser` and all of its uses, because it was only
present for lazy member parsing, which no longer needs it.
Ensure that lazy parsing of the members of nominal type definitions
and extensions is handled through a request. Most of the effort here
is in establishing a new request zone for parser requests.
ABI checker imports Swift frameworks by using Swift interfaces for various
reasons. The existing way of controlling preferred importing mechanism is by
setting an environment variable (SWIFT_FORCE_MODULE_LOADING), which may lead
to performance issues because the stdlib could also be loaded in this way.
This patch adds a new front-end option to specify module names for
which we prefer to importing via Swift interface. The option currently is only
accessible via swift-api-digester.
rdar://54559888
Now that we've moved to C++14, we no longer need the llvm::make_unique
implementation from STLExtras.h. This patch is a mechanical replacement
of (hopefully) all the llvm::make_unique instances in the swift repo.
This refactors DWARFImporter to become a part of ClangImporter, since
it needs access to many of its implementation details anyway. The
DWARFImporterDelegate is just another mechanism for deserializing
Clang ASTs and once we have a Clang AST, the processing is effectively
the same.
We want SILGen and IRGen to also be able to trigger delayed parsing if
necessary, so tweak things here a bit. For now this is NFC, since name
lookup triggers delayed parsing of all types and extensions the first
time a name lookup is performed -- but that is about to change.
Traditionally a serialized binary Swift module (as used in debug info)
can only be imported if all of its Clang dependencies can be imported
*from source*.
- Swift's ClangImporter imports Clang modules by converting Clang AST
types into Swift AST types.
- LLDB knows how to find Clang types in DWARF or other debug info and
can synthesize a Clang AST from that information.
This patch introduces a DWARFImporter delegate that is implemented by
LLDB to connect these two components. With this, a Clang type can be
found (by name) in the debug info and handed over to ClangImporter to
create a Swift type from it. This path has lower fidelity than
importing the Clang modules from source, since it is missing out on
Swiftication annotations and other metadata that is not serialized in
DWARF, but it's invaluable as a fallback mechanism for the debugger
when source code for the Clang modules isn't available or the modules
are otherwise not buildable.
rdar://problem/49233932
This flag adds diagnostic names to the end of their messages, e.g. 'error: cannot convert value of type '[Any]' to specified type '[Int]' [cannot_convert_initializer_value]'. It's intended to be used for debugging purposes when working on the compiler.
IDE functionality needs some internal type checking logics, e.g. checking
whether an extension is applicable to a concrete type. We used to directly
expose an header from sema called IDETypeChecking.h so that IDE functionalities
could invoke these APIs. The goal of the commit and following commits is to
expose evaluator requests instead of directly exposing function entry points from
sema so that we could later move IDETypeChecking.h to libIDE and implement these functions
by internally evaluating these requests.
The clang importer has to deal with two virtual file systems, one coming
from clang, and one coming from swift. Currently, if both are set, we
emit a diagnostic that we'll pick the swift one.
This commit changes that, by merging the two virtual file systems. The
motivation for this change is the reproducer infrastructure in LLDB,
which adds a third virtual file system to the mix.
The clang importer has to deal with two virtual file systems, one coming
from clang, and one coming from swift. Currently, if both are set, we
emit a diagnostic that we'll pick the swift one.
This commit changes that, by merging the two virtual file systems into a
single overlay file system, and using that. To make this possible, we
always initialize the file manager with an overlay file system. In the
clang importer, we then create a new overlay file system, starting with
the one coming from clang, and adding overlays from swift on top.
The motivation for this change is the reproducer infrastructure in LLDB,
which adds a third virtual file system to the mix.
This mode is supposed to get all its configuration information from
the switftinterface being read in, but that means that the ASTContext
and ClangImporter that get created by default may not be a sensible
configuration (for example, a mismatched target and SDK, which Clang
emits a warning about). Avoid this by just not creating the ASTContext
if it's already been determined that the frontend is building a module
from a parseable interface.
This change PCMacro and PlaygroundTransform to return an a moduleID and
fileID in addition to the source location information. The Frontend has
been changed to run PCMacro and PlaygroundTransform on all input files
instead of the main file only.
The tests have been updated to conform to these changes with an addition
of module and file ID specific tests. The Playgrounds related tests were
adjusted to make a module out of the stub interface files since those
files should not have PCMacro and PlaygroundTransform applied to them.
rdar://problem/50821146
I thought it would be useful to allow some uses of a module to be
'@_implementationOnly' and others to not be in case someone wanted to
change from one to the other gradually, but it turns out that if
you're trying to /make/ an import implementation-only, you want to
know everywhere you used it.
rdar://problem/50748157
Keep track of information that led the module interface loader to reject loading a compiled module, if it needed to fall back to compiling an interface.
rdar://47792754
form SerializedModuleLoader into its own ModuleLoader class. (NFC-ish)
This gives better control over the order in which the various module
load mechanisms are applied.
When a Swift module built with debug info imports a library without
debug info from a textual interface, the textual interface is
necessary to reconstruct types defined in the library's interface. By
recording the Swift interface files in DWARF dsymutil can collect them
and LLDB can find them.
rdar://problem/49751363
Don't check for all ABI symbols when building the OnoneSupport
.swiftmodule. Whether we serialize all symbols is irrelevant. They
only need to be in the dylib for ABI purposes.
When we build incrementally, we produce "partial swiftmodules" for
each input source file, then merge them together into the final
compiled module that, among other things, gets used for debugging.
Without this, we'd drop @_implementationOnly imports and any types
from the modules that were imported during the module-merging step
and then be unable to debug those types
When compiling SwiftOnoneSupport, issue errors for missing functions which are expected in the module.
This ensures ABI compatibility.
rdar://problem/48924409
...and remove the option. This is ~technically~ CLI-breaking because
Swift 5 shipped this as a hidden driver option, but it wouldn't have
/done/ anything in Swift 5, so I think it's okay to remove.
Note that if a parseable interface (.swiftinterface) and a binary
interface (.swiftmodule) are both present, the binary one will still
be preferred. This just /allows/ parseable interfaces to be used.
rdar://problem/36885834
A ‘forwarding module’ is a YAML file that’s meant to stand in for a .swiftmodule file and provide an up-to-date description of its dependencies, always using modification times.
When a ‘prebuilt module’ is first loaded, we verify that it’s up-to-date by hashing all of its dependencies. Since this is orders of magnitude slower than reading mtimes, we’ll install a `forwarding module` containing the mtimes of the now-validated dependencies.
Rather than eagerly doing a bunch of name lookups to establish the known
protocol kind, lazily match the ProtocolDecl to the list of known
protocols as-needed. This eliminates a bunch of up-front unqualified
name lookups when spinning up a type checker.
