This more cleanly groups together the initialization steps needed to warm up the conformance cache, so redundant work doesn't need to be done by other interested parties (such as the type-by-name lookup @lhoward's working on).
of associated types in protocol witness tables.
We use the global access functions when the result isn't
dependent, and a simple accessor when the result can be cheaply
recovered from the conforming metadata. Otherwise, we add a
cache slot to a private section of the witness table, forcing
an instantiation per conformance. Like generic type metadata,
concrete instantiations of generic conformances are memoized.
There's a fair amount of code in this patch that can't be
dynamically tested at the moment because of the widespread
reliance on recursive expansion of archetypes / dependent
types. That's something we're now theoretically in a position
to change, and as we do so, we'll test more of this code.
This speculatively re-applies 7576a91009,
i.e. reverts commit 11ab3d537f.
We have not been able to duplicate the build failure in
independent testing; it might have been spurious or unrelated.
When I originally added this I did not understand how dtrace worked well enough.
Turns out we do not need any of this runtime instrumentation and we can just
dynamically instrument the calls.
This commit rips out the all of the static calls and replaces the old
runtime_statistics dtrace file with a new one that does the dynamic
instrumentation for you. To do this one does the following:
sudo dtrace -s ./swift/utils/runtime_statistics.d -c "$CMD"
The statistics are currently focused around dynamic retain/release counts.
of associated types in protocol witness tables.
We use the global access functions when the result isn't
dependent, and a simple accessor when the result can be cheaply
recovered from the conforming metadata. Otherwise, we add a
cache slot to a private section of the witness table, forcing
an instantiation per conformance. Like generic type metadata,
concrete instantiations of generic conformances are memoized.
There's a fair amount of code in this patch that can't be
dynamically tested at the moment because of the widespread
reliance on recursive expansion of archetypes / dependent
types. That's something we're now theoretically in a position
to change, and as we do so, we'll test more of this code.
This reverts commit 6528ec2887, i.e.
it reapplies b1e3120a28, with a fix
to unbreak release builds.
We're not currently doing it, but we will soon be able to use
swift_initializeSuperclass() for class layouts which are not
dependent on generic parameters. In this case, we still need
to set the Objective-C class name.
On the other hand, if we're doing resilient layout for a
non-generic class, we don't need to set the Objective-C class
name.
NFC since this isn't hooked up completely yet.
The runtime entry doesn't just report the error, unlike the other report* functions, it also does the crashing.
Reapplying independent of unrelated reverted patches.
This reverts commit b1e3120a28.
Reverting because this patch uses WitnessTableBuilder::PI in NDEBUG code.
That field only exists when NDEBUG is not defined, but now NextCacheIndex, a
field that exists regardless, is being updated based on information from PI.
This problem means that Release builds do not work.
Getting a superclass, instance extents, and whether a class is native-refcounted are all useful type API. De-underscore these functions and give them a consistent `swift[_objc]_class*` naming scheme.
of associated types in protocol witness tables.
We use the global access functions when the result isn't
dependent, and a simple accessor when the result can be cheaply
recovered from the conforming metadata. Otherwise, we add a
cache slot to a private section of the witness table, forcing
an instantiation per conformance. Like generic type metadata,
concrete instantiations of generic conformances are memoized.
There's a fair amount of code in this patch that can't be
dynamically tested at the moment because of the widespread
reliance on recursive expansion of archetypes / dependent
types. That's something we're now theoretically in a position
to change, and as we do so, we'll test more of this code.
Many of the report* entry points are specific to the stdlib assert implementation, so belong in the stdlib. Keep a single `reportError` entry point in the runtime to handle the CrashReporter/ASL interface, and call down to it from the assert implementation functions.
Now, such classes will emit a metadata pattern and use the
generic metadata instantiation logic.
This was all wired up to handle the case of no generic
parameters previously, to support resilient struct layout
in the runtime.
The swift_initializeSuperclass() entry point still exists,
providing a fast path for when there's no field layout to
do, which is currently always true if we have a concrete
class.
This entry point no longer needs the global lock, since
now we get a per-class lock from the metadata cache.
Also, previously we would call the superclass accessor
function on every access of class metadata for a concrete
subclass of a generic class. Now that we re-use the
existing metadata cache logic, this extra call only occurs
during initialization.
Both swift_initializeSuperclass() and
swift_initClassMetadata_UniversalStrategy() used to take
the superclass as a parameter, but this isn't really
necessary, since it was loaded out of the class metadata
immediately prior to the call by the caller. Removing
this parameter makes the ABI a little simpler.
Once class layout supports resilient types, we will also
use swift_initClassMetadata_UniversalStrategy() to lay
out classes with resilient types as fields.
Singleton metadata caches will still allocate a copy of
the template, which is a slight performance regression
from the previous implementation of concrete subclasses
of generic classes. This will be optimized soon.
Right now, the template can always be modified in place;
in the future, it will be possible to modify in place as
long as the superclass is fixed-layout; a resilient superclass
might add or remove fields, thus we cannot leave room for
it in the metadata of the subclass, and will need to grow
the metadata and slide field offsets at runtime using a
new entry point.
Also, the representation of the cache itself could be
optimized to handle the singleton case, since all we
really need here is a lock without any kind of mapping
table.
Move the following from IRGen to runtime:
- Copying generic parameters from superclass to subclass
- Copying field offsets from superclass to subclass
- Initializing the Objective-C runtime name of the subclass
This eliminates some duplication between the generic subclass and
concrete subclass of a generic class cases.
Also this should reduce generated code size and have no impact on
performance (the instantiation logic only runs once per substituted
type).
This lets us remove `swift_fixLifetime` as a real runtime entry point. Also, avoid generating the marker at all if the LLVM ARC optimizer won't be run, as in -Onone or -disable-llvm-arc-optimizer mode.
class B<T> : NSFoo {}
class A : B<Int> {}
IRGen computes the ivar layout starting from offset zero, since
the size of the 'NSFoo' is unknown and we rely on the Objective-C
runtime to slide the ivar offsets.
The instantiated metadata for B<Int> would contain a field offset
vector with the correct offsets, because of how
swift_initClassMetadata_UniversalStrategy() works.
However, A's metadata is emitted statically, and this includes a
copy of the field offset vector from the superclass. A's metadata
was initialized by swift_initializeSuperclass(), which did not
copy the field offset vector over from A<Int>. And since the
Objective-C runtime only slides the immediate ivars of a class,
the field offsets corresponding to A<Int>'s fields in B's type
metadata were never slid, resulting in problems when an instance
of B was passed to a function operating on an A<T> generically.
Fixes <rdar://problem/23200051>.
