For any operation that can throw an error, such as calls, property
accesses, and non-exhaustive do..catch statements, record the thrown
error type along with the conversion from that thrown error to the
error type expected in context, as appropriate. This will prevent
later stages from having to re-compute the conversion sequences.
While here, eliminate some redundancy in the implementation of
effects checking be consolidating the logic for computing a
`Classification` from a particular expression or other entity.
Add the thrown type into the AST representation of function types,
mapping from function type representations and declarations into the
appropriate thrown type. Add tests for serialization, printing, and
basic equivalence of function types that have thrown errors.
Use FetchContent to include swift-syntax directly in swift. This can be
thought of as an `add_subdirectory` for a directory outside the root.
The default build directory will be `_deps/swiftsyntax-subbuild/`, though
the modules and shared libraries will be built in `lib/swift/host` by
passing down `SWIFT_HOST_LIBRARIES_DEST_DIR` to avoid copying them as we
were doing previously.
These allow multi-statement `if`/`switch` expression
branches that can produce a value at the end by
saying `then <expr>`. This is gated behind
`-enable-experimental-feature ThenStatements`
pending evolution discussion.
This is a futile attempt to discourage future use of getType() by
giving it a "scary" name.
We want people to use getInterfaceType() like with the other decl kinds.
Generate a conjunction for each tap expression body as soon as it
gets a contextual type instead of separate post-factum type-checking
via `typeCheckTapBody`.
Reformatting everything now that we have `llvm` namespaces. I've
separated this from the main commit to help manage merge-conflicts and
for making it a bit easier to read the mega-patch.
This is phase-1 of switching from llvm::Optional to std::optional in the
next rebranch. llvm::Optional was removed from upstream LLVM, so we need
to migrate off rather soon. On Darwin, std::optional, and llvm::Optional
have the same layout, so we don't need to be as concerned about ABI
beyond the name mangling. `llvm::Optional` is only returned from one
function in
```
getStandardTypeSubst(StringRef TypeName,
bool allowConcurrencyManglings);
```
It's the return value, so it should not impact the mangling of the
function, and the layout is the same as `std::optional`, so it should be
mostly okay. This function doesn't appear to have users, and the ABI was
already broken 2 years ago for concurrency and no one seemed to notice
so this should be "okay".
I'm doing the migration incrementally so that folks working on main can
cherry-pick back to the release/5.9 branch. Once 5.9 is done and locked
away, then we can go through and finish the replacement. Since `None`
and `Optional` show up in contexts where they are not `llvm::None` and
`llvm::Optional`, I'm preparing the work now by going through and
removing the namespace unwrapping and making the `llvm` namespace
explicit. This should make it fairly mechanical to go through and
replace llvm::Optional with std::optional, and llvm::None with
std::nullopt. It's also a change that can be brought onto the
release/5.9 with minimal impact. This should be an NFC change.
When you have a type that's ambiguous because it's defined in 2 imported
modules, but you don't have to disambiguate by using the module name,
previously no index references were produced. Now most are for the
common case, but notably nested type constructors and generics still
aren't emitted, partially because of https://github.com/apple/swift/issues/65726
Fixes: https://github.com/apple/swift/issues/64598
Instead of diagnosing in CSApply, let's create a
fix and diagnose in the solver instead.
Additionally, make sure we assign ErrorTypes to
any VarDecls bound by the invalid pattern, which
fixes a crash.
rdar://110638279
Previously we would wait until CSApply, which
would trigger their type-checking in
`coercePatternToType`. This caused a number of
bugs, and hampered solver-based completion, which
does not run CSApply. Instead, form a conjunction
of all the ExprPatterns present, which preserves
some of the previous isolation behavior (though
does not provide complete isolation).
We can then modify `coercePatternToType` to accept
a closure, which allows the solver to take over
rewriting the ExprPatterns it has already solved.
This then sets the stage for the complete removal
of `coercePatternToType`, and doing all pattern
type-checking in the solver.
'MacroExpansionDecl' and 'MacroExpansionExpr' have many common methods.
Introduce a common base class 'FreestandingMacroExpansion' that holds
'MacroExpansionInfo'.
Factor out common expansion logic to 'evaluateFreestandingMacro'
function that resembles 'evaluateAttachedMacro'.
Before this change it was possible to:
1. Call mutating methods on a consume result.
2. assign into a consume (e.x.: var x = ...; (consume x) = value.
From an implementation perspective, this involved just taking the logic I
already used for the CopyExpr and reusing it for ConsumeExpr with some small
tweaks.
rdar://109479440
Some notes:
1. I implemented this as a contextual keyword that can only apply directly to
lvalues. This ensures that we can still call functions called copy, define
variables named copy, etc. I added tests for both the c++ and swift-syntax based
parsers to validate this. So there shouldn't be any source breaks.
2. I did a little bit of type checker work to ensure that we do not treat
copy_expr's result as an lvalue. Otherwise, one could call mutating functions on
it or assign to it, which we do not want since the result of copy_value is
3. As expected, by creating a specific expr, I was able to have much greater
control of the SILGen codegen and thus eliminate extraneous copies and other
weirdness than if we used a function and had to go through SILGenApply.
rdar://101862423
SE-390 concluded with choosing the keyword discard rather than forget for
the statement that disables the deinit of a noncopyable type. This commit
adds parsing support for `discard self` and adds a deprecation warning for
`_forget self`.
rdar://108859077
We shouldn't be allocating placeholders for type
variables in the permanent arena, and we should be
caching them such that equality works.
To achieve this, we need to introduce a new
"solver allocated" type property. This is required
because we don't want to mark placeholder types
with type variable originators as themselves having
type variables, as it's not part of their structural
type. Also update ErrorType to use this bit, though
I don't believe we currently create ErrorTypes
with type variable originators.
The request returns the expanded buffer ID even if it failed to
typecheck the expanded buffer.
This makes refactoring 'Expand Macro' work regardless of the
typechecking results.
rdar://108530760
`coerceCallArguments` has to be `ParameterList::getOrigParamIndex`
to determine "original" parameter version which could be used with
un-substituted parameter list.
For variadic generic declarations we need to compute a substituted
version of bindings because all of the packs are exploded in the
substituted function type.
```swift
func fn<each T>(_: repeat each T) {}
fn("", 42)
```
The type of `fn` in the call is `(String, Int) -> Void` but bindings
have only one parameter at index `0` with two argument positions: 0, 1.
Sometimes we build a `MacroExpansionDecl` from a `MacroExpansionExpr`.
Sometimes we do it the other way. In both cases, we risk the two
copies of must-by-shared data (macro arguments, resolved macro
reference, etc.) getting out-of-sync.
Instead, share the storage between the two representations when we
create one from the other, so that they cannot get out-of-sync. This
allows us to eliminate the extremely-dodgy `cacheOutput` call earlier.
Instead of trying to work around a double-type-check of macro expansion
declaration arguments, avoid type checking them twice in the first
place. We're caching the `ResolveMacroRequest` output in a somewhat
dodgy manner to account for the
`MacroExpansionDecl`/`MacroExpansionExpr` cloning.
Substitution of a pack expansion type may now produce a pack type.
We immediately expand that pack when transforming a tuple, a function
parameter, or a pack.
I had to duplicate the component-wise transformation logic in the
simplifyType transform, which I'm not pleased about, but a little
code duplication seemed a lot better than trying to unify the code
in two very different places.
I think we're very close to being able to assert that pack expansion
shapes are either pack archetypes or pack parameters; unfortunately,
the pack matchers intentionally produce expansions of packs, and I
didn't want to add that to an already-large patch.
This simplifies the representation and allows clients to handle fewer
cases. It also removes an ambiguity in the representation which could
lead us to have two canonical types for the same type.
This is definitely not working yet, but I'm not making progress on
it quickly enough to unblock what we need to unblock; it'll have to
be fixed in parallel.
