We can just !SILFunction::hasQualifiedOwnership(). Plus as Andy pointed out,
even ignoring the functional aspects, having APIs with names this close can
create confusion.
introduce a common superclass, SILNode.
This is in preparation for allowing instructions to have multiple
results. It is also a somewhat more elegant representation for
instructions that have zero results. Instructions that are known
to have exactly one result inherit from a class, SingleValueInstruction,
that subclasses both ValueBase and SILInstruction. Some care must be
taken when working with SILNode pointers and testing for equality;
please see the comment on SILNode for more information.
A number of SIL passes needed to be updated in order to handle this
new distinction between SIL values and SIL instructions.
Note that the SIL parser is now stricter about not trying to assign
a result value from an instruction (like 'return' or 'strong_retain')
that does not produce any.
The issue here is that we know that the given value is already borrowed, so
technically, we do not need a copy. The problem is that there is still
potentially a destroy of the value that will be cloned by the closure cloner.
This results in use-after-frees.
This commit fixes the problem by inserting the relevant copy_value and changing
the borrowed value into a +1 copy.
This is a bug that would have been caught by the Ownership verifier since a
borrowed value can not be destroyed (so the verifier would have tripped).
rdar://32625475
I found this bug by inspection.
This is an important bug to fix since this pass runs at -Onone and the bug
results in the compiler hitting an unreachable.
The way the unreachable is triggered is that when we detect that we are going to
promote a box, if we see a (struct_element_addr (project_box box)), we don't map
the struct_element_addr to a cloned value. If we have a load, this is not an
issue, since we are mapping the load to the struct_extract. But if we have /any/
other non-load users of the struct_element_addr, the cloner will attempt to look
up the struct_element_addr and will be unable to find it, hitting an
unreachable.
rdar://32776202
Till now createApply, createTryApply, createPartialApply were taking some arguments like SubstCalleeType or ResultType. But these arguments are redundant and can be easily derived from other arguments of these functions. There is no need to put the burden of their computation on the clients of these APIs.
The removal of these redundant parameters simplifies the APIs and reduces the possibility of providing mismatched types by clients, which often happened in the past.
The assert should have been checking for both guaranteed and trivial, not just
guaranteed.
This also uncovered a hole in the testing for capture promotion. I added the
missing test.
<rdar://problem/32027013>
Replace `NameOfType foo = dyn_cast<NameOfType>(bar)` with DRY version `auto foo = dyn_cast<NameOfType>(bar)`.
The DRY auto version is by far the dominant form already used in the repo, so this PR merely brings the exceptional cases (redundant repetition form) in line with the dominant form (auto form).
See the [C++ Core Guidelines](https://github.com/isocpp/CppCoreGuidelines/blob/master/CppCoreGuidelines.md#es11-use-auto-to-avoid-redundant-repetition-of-type-names) for a general discussion on why to use `auto` to avoid redundant repetition of type names.
At some point, pass definitions were heavily macro-ized. Pass
descriptive names were added in two places. This is not only redundant
but a source of confusion. You could waste a lot of time grepping for
the wrong string. I removed all the getName() overrides which, at
around 90 passes, was a fairly significant amount of code bloat.
Any pass that we want to be able to invoke by name from a tool
(sil-opt) or pipeline plan *should* have unique type name, enum value,
commend-line string, and name string. I removed a comment about the
various inliner passes that contradicted that.
Side note: We should be consistent with the policy that a pass is
identified by its type. We have a couple passes, LICM and CSE, which
currently violate that convention.
- Use SILFunction::getTypeLowering, because it knows how to handle generic contexts properly
- Map interface types into context
- Fix a use-after-release runtime bug, uncovered by recent Erik's changes.
Fixes rdar://31309883.
Also, add a third [serializable] state for functions whose bodies we
*can* serialize, but only do so if they're referenced from another
serialized function.
This will be used for bodies synthesized for imported definitions,
such as init(rawValue:), etc, and various thunks, but for now this
change is NFC.
There are now separate functions for function addition and deletion instead of InvalidationKind::Function.
Also, there is a new function for witness/vtable invalidations.
rdar://problem/29311657
Previously this pass would bail out if the closure had any
parameters or results of generic type.
First of all, this was a workaround for an old SILGen limitation,
where closures in generic context would inherit a generic
signature even if they did not capture generic types, which
inhibited optimizations.
Second, capture promotion doesn't really do anything special with
generics at all, but it used a TypeSubstCloner and would apply
substitutions from the call site to the cloned function; this is
not the behavior we want here. Simply switching the pass to use a
SILCloner instead of a TypeSubstCloner appears to be sufficient
in order to allow generic boxes to be promoted too.
Fixes <rdar://problem/28948735>.
SubstitutionList is going to be a more compact representation of
a SubstitutionMap, suitable for inline allocation inside another
object.
For now, it's just a typedef for ArrayRef<Substitution>.
In all cases the DeclCtx field was supposed to be initialized from the
SILLocation of the function, so we can save one pointer per
SILFunction.
There is one test case change where a different (more precise)
diagnostic is being generated after this change.
Formal types are defined by the language's type system. SIL types are
lowered. They are no longer part of that type system.
The important distinction here is between the SIL storage type and the SIL value
type. To make this distinction clear, I refer to the SILFunctionTypes "formal"
conventions. These conventions dictate the SIL storage type but *not* the SIL
value type. I call them "formal" conventions because they are an immutable
characteristic of the function's type and made explicit via qualifiers on the
function type's parameters and results. This is in contrast to to SIL
conventions which depend on the SIL stage, and in the short term whether the
opaque values flag is enabled.
Pass correct argument indices to the mangler for function specialization. This
has probably always been broken. The demangler doesn't support these manglings
anyway. It doesn't seem to have mattered in practice yet (aside from the
confusion of devs) like me. It will matter once we begin exposing public
specializations.
Separate formal lowered types from SIL types.
The SIL type of an argument will depend on the SIL module's conventions.
The module conventions are determined by the SIL stage and LangOpts.
Almost NFC, but specialized manglings are broken incidentally as a result of
fixes to the way passes handle book-keeping of aruments. The mangler is fixed in
the subsequent commit.
Otherwise, NFC is intended, but quite possible do to rewriting the logic in many
places.
This means using a struct so we can put methods on the struct and using an
anonymous enum to create namespaced values. Specifically:
struct SILArgumentConvention {
enum : uint8_t {
Indirect_In,
Indirect_In_Guaranteed,
Indirect_Inout,
Indirect_InoutAliasable,
Indirect_Out,
Direct_Owned,
Direct_Unowned,
Direct_Deallocating,
Direct_Guaranteed,
} Value;
SILArgumentConvention(decltype(Value) NewValue)
: Value(NewValue) {}
operator decltype(Value)() const {
return Value;
}
ParameterConvention getParameterConvention() const {
switch (Value) {
...
}
}
bool isIndirectConvention() const {
...
}
};
This allows for:
1. Avoiding abstraction leakage via the enum type. If someone wants to use
decltype as well, I think that is enough work that the leakage is acceptable.
2. Still refer to enum cases like we are working with an enum class
(e.g. SILArgumentConvention::Direct_Owned).
3. Avoid using the anonymous type in function arguments due to an implicit
conversion.
4. And most importantly... *drum roll* add methods to our enums!
We preserve the current behavior of assuming Any ownership always and use
default arguments to hide this change most of the time. There are asserts now in
the SILBasicBlock::{create,replace,insert}{PHI,Function}Argument to ensure that
the people can only create SILFunctionArguments in entry blocks and
SILPHIArguments in non-entry blocks. This will ensure that the code in tree
maintains the API distinction even if we are not using the full distinction in
between the two.
Once the verifier is finished being upstreamed, I am going to audit the
createPHIArgument cases for the proper ownership. This is b/c I will be able to
use the verifier to properly debug the code. At that point, I will also start
serializing/printing/parsing the ownershipkind of SILPHIArguments, but lets take
things one step at a time and move incrementally.
In the process, I also discovered a CSE bug. I am not sure how it ever worked.
Basically we replace an argument with a new argument type but return the uses of
the old argument to refer to the old argument instead of a new argument.
rdar://29671437
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.
This simplifies the SILType substitution APIs and brings them in line with Doug and Slava's refactorings to improve AST-level type substitution. NFC intended.
Applying nontrivial generic arguments to a nontrivial SIL layout requires lowered SILType substitution, which requires a SILModule. NFC yet, just an API change.
The purpose of this change is to test if the new mangling is equivalent to the old mangling.
Both mangling strings are created, de-mangled and checked if the de-mangle trees are equivalent.
