This provides a singular instruction for convert an unmanaged value to a ref,
then strong_retain it. I expanded the definition of UNCHECKED_REF_STORAGE to
include these copy like instructions. This instruction is valid in all SIL.
The reason why I am adding this instruction is that currently when we emit an
access to an unowned (unsafe) ivar, we use an unmanaged_to_ref and a strong
retain. This can look to the optimizer like a strong retain that can potentially
be optimized. By combining the two together into a new instruction, we can avoid
this potential problem since the pattern matching will break.
In too many places, we were calling into `emitDynamicTypeOfOpaqueHeapObject` even when we had
more specific type information about the heap object we were querying. Replace all calls with
`emitDynamicTypeOfHeapObject`, which uses the best available access path and completely avoids
runtime calls for pure Swift classes and heap objects. When targeting non-ObjC-interop platforms,
we also know we never need to call `swift_getObjectType`, so avoid doing so altogether.
This indicates that the "self" argument to the current function is always dynamically of the exact
static base class type, allowing metadata accesses in IRGen to use the local self metadata to answer
metadata requests for the class type. Set this attribute on allocating entry points of designated
inits, which is one of the most common places where we emit redundant metadata accesses.
Class methods always have a "self" argument that can be used to get the metadata of the dynamic
Self type, which in final classes is always the same as the statically-known base class. Use this
to avoid reconstructing the static base class type.
If we're allowed to know at IRGen time what the underlying type of an opaque type is, we can
satisfy references to the opaque type's metadata or protocol witness tables by directly referencing
the underlying type instead.
To display a failure message in the debugger, create a function in the debug info which has the name of the failure message.
The debug location of the trap/cond_fail is then wrapped into this function and the function is declared as "inlined".
In case the debugger stops at the trap instruction, it displays the inline function, which looks like the failure message.
For example:
* thread #1, queue = 'com.apple.main-thread', stop reason = EXC_BAD_INSTRUCTION (code=EXC_I386_INVOP, subcode=0x0)
frame #0: 0x0000000100000cbf a.out`testit3(_:) [inlined] Unexpectedly found nil while unwrapping an Optional value at test.swift:14:11 [opt]
11
12 @inline(never)
13 func testit(_ a: Int?) -> Int {
-> 14 return a!
15 }
16
This change is currently not enabled by default, but can be enabled with the option "-Xllvm -enable-trap-debug-info".
Enabling this feature needs some changes in lldb. When the lldb part is done, this option can be removed and the feature enabled by default.
To display a failure message in the debugger, create a function in the debug info which has the name of the failure message.
The debug location of the trap/cond_fail is then wrapped into this function and the function is declared as "inlined".
In case the debugger stops at the trap instruction, it displays the inline function, which looks like the failure message.
For example:
* thread #1, queue = 'com.apple.main-thread', stop reason = EXC_BAD_INSTRUCTION (code=EXC_I386_INVOP, subcode=0x0)
frame #0: 0x0000000100000cbf a.out`testit3(_:) [inlined] Unexpectedly found nil while unwrapping an Optional value at test.swift:14:11 [opt]
11
12 @inline(never)
13 func testit(_ a: Int?) -> Int {
-> 14 return a!
15 }
16
This change is currently not enabled by default, but can be enabled with the option "-Xllvm -enable-trap-debug-info".
Enabling this feature needs some changes in lldb. When the lldb part is done, this option can be removed and the feature enabled by default.
With the option -Xllvm -basic-dynamic-replacement the runtime functions are not called (so it works with an old swift library).
But calling the original of a replaced function is not supported in this case.
Instead of a thunk insert the dispatch into the original function.
If the original function should be executed the prolog just jumps to the "real" code in the function. Otherwise the replacement function is called.
There is one little complication here: when the replacement function calls the original function, the original function should not dispatch to the replacement again.
To pass this information, we use a flag in thread local storage.
The setting and reading of the flag is done in two new runtime functions.
rdar://problem/51043781
With the advent of dynamic_function_ref the actual callee of such a ref
my vary. Optimizations should not assume to know the content of a
function referenced by dynamic_function_ref. Introduce
getReferencedFunctionOrNull which will return null for such function
refs. And getInitialReferencedFunction to return the referenced
function.
Use as appropriate.
rdar://50959798
This is no longer needed because we now make sure to run the coroutine lowering pass before ASan/TSan instrumentation passes.
Also fixes a typo in the test.
Currently LLDB calls into ide::getDeclFromMangledSymbolName() to get
to this information and we would like to get rid of this call.
rdar://problem/47798056
I found the corresponding code in LLDB that depended on this hack and
am now removing both. This makes it possible to share the same code
path for top-level archetypes and member types.
rdar://problem/45462765
Previously we would always calculate these instructions ownership dynamically
when asked and rely on the ownership verifier to catch if we made any
mistakes. Instead with this commit we move to a more static model where the
ownership that these instructions can take are frozen on construction. This is a
more static model that simplifies the ownership model.
I also eliminated a few asserts that are enforced in other places that caused
problems when parsing since we may not have a Function while Parsing (it was
generally asserts if a type was trivial).
A dynamically replaceable function calls through a global variable that
holds the function pointer.
struct ChainEntry {
void *(funPtr)();
struct ChainEntry *next;
}
ChainEntry dynamicallyReplaceableVar;
void dynamicallyReplaceableFunction() {
dynamicallyReplaceableVar.funPtr()
}
dynamic replacements will be chainable so the global variable also
functions as the root entry in the chain of replacements.
A dynamic replacement functions can call the previous implementation by
going through its chain entry.
ChainEntry chainEntryOf_dynamic_replacement_for_foo;
void dynamic_replacement_for_foo() {
// call the previous (original) implementation.
chainEntryOf_dynamic_replacement_for_foo.funPtr();
}
Remove the compiler support for exclusivity warnings.
Leave runtime support for exclusivity warnings in non-release builds
only for unit testing convenience.
Remove a test case that checked the warning log output.
Modify test cases that relied on successful compilation in the
presence of exclusivity violations.
Fixes: <rdar://problem/45146046> Remaining -swift-version 3 tests for exclusivity
A few utility methods would bypass computing the TypeInfo for a tuple,
but they were only used in assertions or used in places where I can't
imagine tuples coming up often enough for it to matter.
I believe that these were in SILInstruction for historic reasons. This is a
separate API on top of SILInstruction so it makes sense to pull it out into its
own header.
I changed all of the places that used end_borrow_argument to use end_borrow.
NOTE: I discovered in the process of this patch that we are not verifying
guaranteed block arguments completely. I disabled the tests here that show this
bad behavior and am going to re-enable them with more tests in a separate PR.
This has not been a problem since SILGen does not emit any such arguments as
guaranteed today. But once I do the SILGenPattern work this will change.
rdar://33440767
SIL will not generate calls to protocol requirements that override
other protocol requirements, so all of the witness table entries for
the overriding arguments are dynamically dead. Remove them from the
witness tables entirely.
Implements rdar://problem/43870489, reducing the size of the standard
library binary by 196k.
