Special DeclNames represent names that do not have an identifier in the
surface language. This implies serializing the information about whether
a name is special together with its identifier (if it is not special)
in both the module file and the swift lookup table.
With the introduction of special decl names, `Identifier getName()` on
`ValueDecl` will be removed and pushed down to nominal declarations
whose name is guaranteed not to be special. Prepare for this by calling
to `DeclBaseName getBaseName()` instead where appropriate.
Make generic environment deserialization lazy, which eliminates a
significant amount of up-front work. Most clients only need the
generic signature, not the full generic environment.
Deserializing a witness record in a conformance may fail if either of the requirement or witness changed name or type, most likely due to SDK modernization changes across Swift versions. When this happens, leave an opaque placeholder in the conformance to indicate that the witness exists but we don't get to see it. For expedience, right now this just witnesses the requirement to itself, so that code in the type checker or elsewhere that tries to ad-hoc devirtualize references to the requirement just gets the requirement back. Arguably, we shouldn't include the witness at all in imported conformances, since they should be an implementation detail, but that's a bigger, riskier change. This patch as is should be enough to address rdar://problem/31185053.
Proof-of-concept for the above. This shouldn't be common---renames are
far more likely, and those we can track---but occurs when the
swift_wrapper attribute (the implementation of NS_STRING_ENUM) is
active in Swift 4 but not in Swift 3.
Note that this only checks the canonical interface type of the
declaration, because the non-canonical type may contain references to
the declaration's generic parameters.
Module files store all of the Objective-C method entrypoints in a
central table indexed by selector, then filter the results based on
the specific class being requested. Rather than storing the class as
a TypeID---which requires a bunch of deserialization---store its
mangled name. This allows us to deserialize less, and causes circular
deserialization in rdar://problem/31615640.
That is, a Swift 3 target imported into a Swift 4 context or vice
versa. This requires serializing the compatibility mode explicitly,
instead of including it in the textual version string that's only
for debugging.
Back in December DougG added code to delay the formation of generic
environments until all declarations from a particular module had been
deserialized, to avoid circular dependencies caused by too-eager
deserialization of protocol members. This worked great for fully-built
modules, but still had some problems with module merging, the phase of
multi-file compilation where the "partial" swiftmodules that
correspond to each source file in a target are loaded and remitted as
a single swiftmodule. Fix this by picking one of the partial
swiftmodules as the representative one for delayed actions, and wait
until deserialization is complete for /all/ of the serialized ASTs in
the same target to form the generic environments.
rdar://problem/30984417
A lot of files transitively include Expr.h, because it was
included from SILInstruction.h, SILLocation.h and SILDeclRef.h.
However in reality most of these files don't do anything
with Exprs, especially not anything in IRGen or the SILOptimizer.
Now we're down to 171 files in the frontend which depend on
Expr.h, which is still a lot but much better than before.
This has the effect of propagating the search path to the clang importer as '-iframework'.
It doesn't affect whether a swift module is treated as system or not, this can be done as follow-up enhancement.
Previously looking up an extension would result in all extensions for
types with the same name (nested or not) being deserialized; this
could even bring in base types that had not been deserialized yet. Add
in a string to distinguish an extension's base type; in the top-level
case this is just a module name, but for nested types it's a full
mangled name.
This is a little heavier than I'd like it to be, since it means we
mangle names and then throw them away, and since it means there's a
whole bunch of extra string data in the module just for uniquely
identifying a declaration. But it's correct, and does less work than
before, and fixes a circularity issue with a nested type A.B.A that
apparently used to work.
https://bugs.swift.org/browse/SR-3915
We would previously get an error for an unexpected EOF. However, we no
longer were checking that case, and would fall through to the end of the
function, without a return value. Return the proper failure indicator.
There's a class of errors in Serialization called "circularity
issues", where declaration A in file A.swift depends on declaration B
in file B.swift, and B also depends on A. In some cases we can manage
to type-check each of these files individually due to the laziness of
'validateDecl', but then fail to merge the "partial modules" generated
from A.swift and B.swift to form a single swiftmodule for the library
(because deserialization is a little less lazy for some things). A
common case of this is when at least one of the declarations is
nested, in which case a lookup to find that declaration needs to load
all the members of the parent type. This gets even worse when the
nested type is defined in an extension.
This commit sidesteps that issue specifically for nested types by
creating a top-level, per-file table of nested types in the "partial
modules". When a type is in the same module, we can then look it up
/without/ importing all other members of the parent type.
The long-term solution is to allow accessing any members of a type
without having to load them all, something we should support not just
for module-merging while building a single target but when reading
from imported modules as well. This should improve both compile time
and memory usage, though I'm not sure to what extent. (Unfortunately,
too many things still depend on the whole members list being loaded.)
Because this is a new code path, I put in a switch to turn it off:
frontend flag -disable-serialization-nested-type-lookup-table
https://bugs.swift.org/browse/SR-3707 (and possibly others)
The typedef `swift::Module` was a temporary solution that allowed
`swift::Module` to be renamed to `swift::ModuleDecl` without requiring
every single callsite to be modified.
Modify all the callsites, and get rid of the typedef.
Changes:
* Terminate all namespaces with the correct closing comment.
* Make sure argument names in comments match the corresponding parameter name.
* Remove redundant get() calls on smart pointers.
* Prefer using "override" or "final" instead of "virtual". Remove "virtual" where appropriate.
Serialize generic environments via a generic environment ID with a
separte offset table, so we have identity for the generic environments
and will share generic environments on deserialization.
The more important fix here is to remove a duplicated call to advance the
cursor, which led to module import being completely broken. I also added
back the AF_DontPopBlockAtEnd flags that were dropped. I am not certain
if they are needed but without clear indication otherwise, we should keep
them.
The behavior of std::minmax with rvalue arguments is undefined after the
end of the expression that contains the call to minmax. This code to
special-case the comparisons for ARM vs. Thumb and macOS vs. Darwin was a
little overly clever anyway. Rewrite it to use straightforward comparisons.
This fixes a test failure in Serialization/target-incompatible.swift when
building with a recent version of clang, because these checks were completely
optimized away due to the undefined behavior. rdar://problem/28700005
This would have allowed us to triage rdar://problem/28305755 much
sooner. The actual problem is pretty bad: if you have too many methods
with the same selector, serialization just falls over. "Too many" is
in the thousands, which seems unlikely, but 'dealloc' can actually get
there if there are a lot of little classes, and 'init' might as well,
so we really should do better here.
What I've implemented here deviates from the current proposal text
in the following ways:
- I had to introduce a FunctionArrowPrecedence to capture the parsing
of -> in expression contexts.
- I found it convenient to continue to model the assignment property
explicitly.
- The comparison and casting operators have historically been
non-associative; I have chosen to preserve that, since I don't
think this proposal intended to change it.
- This uses the precedence group names and higherThan/lowerThan
as agreed in discussion.
My earlier patch started serializing SIL basic blocks using the RPOT order. While it works, changing the existing order of BBs during the serialization may be very surprising for users. After all, serialization is not supposed to transform the code.
Therefore, this patch follows a different approach. It uses the existing order of BBs during the serialization. When it deserializes/parses SIL and detects a use of an opened archetype before its definition, it basically introduced a forward definition of this opened archetype. Later on, when the actual definition of the opened archetype is found, it replaces the forward definition. There is a correctness check at the end of a SIL function deserialization, which verifies that there are no forward definitions of opened archetypes left unresolved.
...with a better message than the generic "older version of the
compiler" one, when we know it's actually a different version of
Swift proper.
This still uses the same internal module version numbers to check
if the module is compatible; the presentation of language versions
is a diagnostic thing only.
Speaking of module version numbers, this deliberately does NOT
increment VERSION_MINOR; it's implemented in a backwards-compatible
way.
This will only work going forwards, of course; all existing modules
don't have a short version string, and I don't feel comfortable
assuming all older modules we might encounter are "Swift 2.2".
rdar://problem/25680392
We want to distinguish the special case of a library built with
-sil-serialize-all, from a SIL function that is [fragile] because
of an explicitly @_transparent or @inline(__always).
For now, NFC.
We did not serialize them because getting USR for extensions is tricky (USRs are
usually for value decls). This commit starts to make up an USR for an extension by combining
the extended nominal's USR with the USR of the first value member of the extension. We use
this made-up USR to associate doc comments when (de)serializing them.
