`PointerType::getElementType` has been removed entirely as part of the
opaque pointers migration. Update to `getPointerElementType` for now
until we've also migrated.
Since these types have an implicit stored property, this requires
adding an abstraction over fields to IRGen, at least throughout
the class code. In some ways I think this significantly improves
the code, especially in how we approach missing members.
Fixes rdar://72202671.
of adding a property.
This better matches what the actual implementation expects,
and it avoids some possibilities of weird mismatches. However,
it also requires special-case initialization, destruction, and
dynamic-layout support, none of which I've added yet.
In order to get NSObject default actor subclasses to use Swift
refcounting (and thus avoid the need for the default actor runtime
to generally use ObjC refcounting), I've had to introduce a
SwiftNativeNSObject which we substitute as the superclass when
inheriting directly from NSObject. This is something we could
do in all NSObject subclasses; for now, I'm just doing it in
actors, although it's all actors and not just default actors.
We are not yet taking advantage of our special knowledge of this
class anywhere except the reference-counting code.
I went around in circles exploring a number of alternatives for
doing this; at one point I basically had a completely parallel
"ForImplementation" superclass query. That proved to be a lot
of added complexity and created more problems than it solved.
We also don't *really* get any benefit from this subclassing
because there still wouldn't be a consistent superclass for all
actors. So instead it's very ad-hoc.
When the first element in the heap layout was non fixed we would use the
mininum size of the total heap layout for the initial offset. This would
create unneccessary large heap layouts.
rdar://61716736
This change modifies spare bit masks so that they are arranged in
the byte order of the target platform. It also modifies and
consolidates the code that gathers and scatters bits into enum
values.
All enum-related validation tests are now passing on IBM Z (s390x)
which is a big-endian platform.
Wait until we know the full size of the SpareBitVector before we
construct it from the spare bit masks of the individual elements
in the struct. This process mirrors the way we construct the rest
of the struct type.
This should reduce the number of short-lived allocations required
to build small struct types (especially after #25240). It also
provides a convenient place to insert code to handle the
construction of big-endian bit masks on when targeting big-endian
machines, assuming we decide to go down that route.
Field offset vectors are always filled out with either zero or the static layout's offset, depending on the metadata initialization strategy. This change means that the static layout's offset will only be non-zero for properties with a statically-known layout. Existing runtimes doing dynamic class layout assign class properties a zero offset if the field offset vector entry is zero and the property is zero-sized. So this effectively brings the compiler into accord with the runtime (for all newly-compiled Swift code, which will eventually be all Swift code because the current public releases of Swift 5 are not yet considered ABI-stable) and guarantees a zero value for the offset everywhere.
Since the runtime will agree with the compiler about the zero value of the offset, the compiler can continue to emit such offset variables as constant. The exception to this rule is if the class has non-fragile ObjC ancestry, in which case the ObjC runtime (which is not aware of this special rule for empty fields) will attempt to slide it along with everything else.
Fixes rdar://48031465, in which the `FixedClassMetadataBuilder` for a class with a legacy-fixed layout was writing a non-zero offset for an empty field into the field offset vector, causing the runtime to not apply the special case and thus to compute a non-zero offset, which it then attempted to copy into the global field offset variable, which the compiler had emitted as a true-constant zero.
The type info for a class described its layout using a combination of a
StructLayout and ClassLayout, with different information stored in both.
Since we never use a class as a struct, it's simpler to add the relevant
bits to ClassLayout, and not build a StructLayout at all.
Also, drop inherited properties from the ClassLayout -- they're no
longer needed.
This is an error introduced as the result of a refactoring a while ago
and means that we will store dependently typed stored properties at the
wrong offset in a generic struct if it has stored properties of empty
types before said property.
rdar://36384871
We would lay out all classes starting with a Swift-style two-word header, even classes that inherit NSObject and therefore don't have Swift refcounting. The ObjC runtime would slide our ivars down for us at realization time, but it's nice to avoid unnecessarily dirtying memory in the not-uncommon case of direct NSObject subclasses.
Give empty fields a notional byte offset so we can still use the offset of the first field as an approximation of the instanceStart of a class.
Fixes SR-1055.
In a few places, we have to be careful about the distinction between
"empty in this resilience domain" versus "empty in all resilience
domains". Make callers think about this by adding a parameter instead
of relying on them to check isFixedSize() as necessary first.
While making this change I noticed that the code for checking if
types are empty when computing extra inhabitants of structs and enums
might be slightly wrong in the face of resilience; I will revisit
this later.
For example, if a @_fixed_layout struct A contains a resilient struct B
from the same module M, then inside M, A can have a fixed size, but
outside, A has a dynamic size because B is opaque. In this case, A is
not "universally fixed-size". This impacts multi-payload enums, because
if A is placed inside a multi-payload enum E which is lowered inside X,
we would get a fixed layout with spare bits, but lowering E outside of
X would yield a dynamic layout. This is incorrect.
Fix this by plumbing through a new predicate IsAlwaysFixedSize, which
is similar to IsPOD and IsBitwiseTakable, where a compound type inherits
the property if all leaf types exhibit it, and only use spare bits if
the original and substituted types have this property.
John and I discussed this and agreed that we only need two cases here,
not four. In the future this may be merged with ResilienceExpansion,
and become a struct with additional availability information, but
we're definitely sure we don't need four levels here.
This is an internal-only affordance for the numerics team to be able to work on SIMD-compatible types. For now, it can only increase alignment of fixed-layout structs and enums; dynamic layout, classes, and other obvious extensions are left to another day when we can design a proper layout control design.
Swift SVN r27323
IRGen uses a typedef, SpareBitVector, for its principal
purpose of tracking spare bits. Other uses should not
use this typedef, and I've tried to follow that, but I
did this rewrite mostly with sed and may have missed
some fixups.
This should be almost completely NFC. There may be
some subtle changes in spare bits for witness tables
and other off-beat pointer types. I also fixed a bug
where IRGen thought that thin functions were two
pointers wide, but this wouldn't have affected anything
because we never store thin functions anyway, since
they're not a valid AST type.
This commit repplies r24305 with two fixes:
- It fixes the computation of spare bits for unusual
integer types to use the already-agreed-upon type
size instead of recomputing it. This fixes the
i386 stdlib build. Joe and I agreed that we should
also change the size to use the LLVM alloc size
instead of the next power of 2, but this patch
does not do that yet.
- It changes the spare bits in function types back
to the empty set. I'll be changing this in a
follow-up, but it needs to be tied to runtime
changes. This fixes the regression test failures.
Swift SVN r24324
IRGen uses a typedef, SpareBitVector, for its principal
purpose of tracking spare bits. Other uses should not
use this typedef, and I've tried to follow that, but I
did this rewrite mostly with sed and may have missed
some fixups.
This should be almost completely NFC. There may be
some subtle changes in spare bits for witness tables
and other off-beat pointer types. I also fixed a bug
where IRGen thought that thin functions were two
pointers wide, but this wouldn't have affected anything
because we never store thin functions anyway, since
they're not a valid AST type.
Swift SVN r24305
In value witness table generation, and probably other places, we're inappropriately assuming that 'initializeWithTake' is equivalent to a memcpy in all cases, which isn't true for types that carry weak references or for potentially other types in the future. Add an 'isBitwiseTakable' property to TypeInfos that can be checked to see whether a type is bitwise-takable.
Swift SVN r16799
When doing struct layout for fixed-layout structs or tuples, combine the spare bit masks of their elements to form the spare bit mask of the aggregate, treating padding between elements as spare bits as well.
For now, disable using these spare bits to form extra inhabitants for structs and tuples; we would need additional runtime work to expose these extra inhabitants for correct generic runtime behavior. This puts us in a weird situation where 'enum { case A(Struct), B, C }' spills a bit but 'enum { case A(Struct), B(Struct), C }' doesn't, but the work to make the former happen isn't immediately critical for String optimization.
Swift SVN r12165
We need these for dependent-layout generic classes so we know the allocation/deallocation size and alignment. When I figure out ObjC interop with generic subclasses these should move to the rodata so they get handled resiliently by the ObjC runtime, but for generic class bringup this is convenient.
Swift SVN r9249
LLVM's normal data layout doesn't jive with our own StructLayout's more aggressive use of padding space, and causes problems such as <rdar://problem/14336903>. Because we do our own alignment and stride management, we can safely use LLVM packed struct types with manual padding to get the level of control we need to accurately reflect our desired struct layout.
Swift SVN r9056
{ %swift.opaque } freaks out InstCombine and other optimization passes. Just leave opaque types out of the struct type, even if they appear first in the layout.
Swift SVN r5066
of a GEP.
LLVM does not permit GEPs over unsized types, even if the index
is a constant zero.
This makes simple code involving generic tuples work.
Swift SVN r4969
