Only return macros that are valid in their current position, ie. an
attached macro is not valid on a nominal.
Also return freestanding expression macros in code block item position
and handle the new freestanding code item macros.
Resolves rdar://105563583.
Using a virutal output backend to capture all the outputs from
swift-frontend invocation. This allows redirecting and/or mirroring
compiler outputs to multiple location using different OutputBackend.
As an example usage for the virtual outputs, teach swift compiler to
check its output determinism by running the compiler invocation
twice and compare the hash of all its outputs.
Virtual output will be used to enable caching in the future.
Previously we would only enable by default when
`parseArgs` was called. However this wouldn't
enable it for clients such as LLDB, who provide
their own invocation. Switch the default to `true`
in the `LangOptions`, and remove some redundant
uses of `-enable-experimental-string-processing`.
The frontend flag remains, as it may be useful to
disable.
rdar://107419385
rdar://101765556
This ensures that interface gen reports an error when importing a framework Swift module
that also imports the underlying C++ module into Swift, when interop is disabled, so that
we can retry the interface gen with interop enabled.
Pass back the original location (ie. where the macro was expanded, not
the location that the generated code would be inserted) for cursor info
and indexing. Also mark any declarations/references within generated
source as implicit.
Resolves rdar://107209132.
Update to have a single refactoring collection method for cursor
refactorings and another for ranges. The various functions were only
needed because of the extra availability information on renames, so just
give that to all refactorings.
Make a single 'PluginRegistry' and share it between SwiftASTManager,
IDEInspectionInstance, and CompileInstance. And inject the plugin
registry to ASTContext right after 'CompilerInstance.setup()'
That way, all sema-capable ASTContext in SourceKit share a single
PluginRegistry.
I want to reserve Feature::MoveOnly only for move-only types and other
things that are part of SE-390. Other prototyped features like
noimplicitcopy and some older names for consume were left behind
as guarded by this Feature. That's really not the right way to do it,
as people will expect that the feature is enabled all the time, which
would put those unofficial features into on-by-default. So this change
introduces two new Features to guard those unofficial features.
Update requests to handle being passed a separate `key.primary_file`
which specifies the file to use for building the AST. `key.sourcefile`
is then the file to find in `SourceManager`, which could be a generated
buffer.
Resolves rdar://106863186.
This hooks up the cursor info infrastructure to be able to pass through multiple, ambiguous results. There are still minor issues that cause solver-based cursor info to not actually report the ambiguous results but those will be fixed in a follow-up PR.
This executable is intended to be installed in the toolchain and act as
an executable compiler plugin just like other 'macro' plugins.
This plugin server has an optional method 'loadPluginLibrary' that
dynamically loads dylib plugins.
The compiler has a newly added option '-external-plugin-path'. This
option receives a pair of the plugin library search path (just like
'-plugin-path') and the corresponding "plugin server" path, separated
by '#'. i.e.
-external-plugin-path
<plugin library search path>#<plugin server executable path>
For exmaple, when there's a macro decl:
@freestanding(expression)
macro stringify<T>(T) -> (T, String) =
#externalMacro(module: "BasicMacro", type: "StringifyMacro")
The compiler look for 'libBasicMacro.dylib' in '-plugin-path' paths,
if not found, it falls back to '-external-plugin-path' and tries to find
'libBasicMacro.dylib' in them. If it's found, the "plugin server" path
is launched just like an executable plugin, then 'loadPluginLibrary'
method is invoked via IPC, which 'dlopen' the library path in the plugin
server. At the actual macro expansion, the mangled name for
'BasicMacro.StringifyMacro' is used to resolve the macro just like
dylib plugins in the compiler.
This is useful for
* Isolating the plugin process, so the plugin crashes doesn't result
the compiler crash
* Being able to use library plugins linked with other `swift-syntax`
versions
rdar://105104850
Rather than using `ModuleDecl::isSystemModule()` to determine whether a
module is not a user module, instead check whether the module was
defined adjacent to the compiler or if it's part of the SDK.
If no SDK path was given, then `isSystemModule` is still used as a
fallback.
Resolves rdar://89253201.
Retrieving local rename ranges and the local rename refactoring both had
almost identical methods, except for the addition of retrieving the
outermost shadowed decl that was added a couple months back. Merge them.
Resolves rdar://106529370.
For future usage from other host libraries written in Swift
For CMake:
* Explicitly specify LINKER_LANGAGE to CXX in existing components so
that 'swiftc' is not used when linking with 'swiftASTGen'
* Add 'EMIT_MODULE' argument to 'add_pure_swift_host_library' to emit
.swiftmodule usable from other Swift libraries.
For unified builds, LLVM with the update to stable/20221013 includes its
own FindLibEdit, which shares many of the same names than Swift's
FindLibEdit, except that they differ in the target name.
Match both LLVM and Swift target names, so unified builds can find
LibEdit::LibEdit correctly and not try to link against libedit
mistakenly.
This should not affect Darwin/Linux builds from upstream Swift, since
they build non-unified in most people setups (including CI).
Once the API has gone through Swift Evolution, we will want to implicitly
import the _Backtracing module. Add code to do that, but set it to off
by default for now.
rdar://105394140
The dependency of the Observation library on the observation macro
plugin introduces a direct dependency of a target library on a host
library, (lib -> stdlib) that we'd like to avoid. Instead, make the
Swift frontend binary depend on the macro plugin libraries that we
build, so that it's the complete host-side stack.
