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 allows SIL transformations to describe one source variable with more
than one debug_value instruction.
rdar://problem/22705966
(cherry picked from commit fd6e8a9bef)
This just runs a transform range on getSuccessor()'s ArrayRef<SILSuccessor> so
one does not need to always call Successor.getBB() when iterating over successor
blocks. Instead the transform range does that call for you.
I also updated some loops to use this new SILBasicBlock method to make sure that
the code is tested out by tests that are already in tree. All these places
should be functionally the same albeit a bit cleaner.
Debug variable info may be attached to debug_value, debug_value_addr,
alloc_box, and alloc_stack instructions.
In order to write textual SIL -> SIL testcases that exercise the handling
of debug information by SIL passes, we need to make a couple of additions
to the textual SIL language. In memory, the debug information attached to
SIL instructions references information from the AST. If we want to create
debug info from parsing a textual .sil file, these bits need to be made
explicit.
Performance Notes: This is memory neutral for compilations from Swift
source code, because the variable name is still stored in the AST. For
compilations from textual source the variable name is stored in tail-
allocated memory following the SIL instruction that introduces the
variable.
<rdar://problem/22707128>
There's a buggy SIL verifier check that was previously tautological,
and it turns out that it's violated, apparently harmlessly. Since it
was already doing nothing, I've commented it out temporarily while
I figure out the right way to fix SILGen to get the invariant right.
when working with autoreleased result conventions, and stop
emitting autorelease_return and strong_retain_autoreleased in
SILGen.
The previous representation, in which strong_retain_autoreleased
was divorced from the call site, allowed it to "wander off" and
be cloned. This would at best would break the optimization, but
it could also lead to broken IR due to some heroic but perhaps
misguided efforts in IRGen to produce the exact required code
pattern despite the representational flaws.
The SIL pattern for an autoreleased result now looks exactly
like the pattern for an owned result in both the caller and
the callee. This should be fine as long as interprocedural
optimizations are conservative about convention mismatches.
Optimizations that don't wish to be conservative here should
treat a convention mismatch as an autorelease (if the callee
has an autoreleased result) or a retain (if the formal type
of the call has an autoreleased result).
Fixes rdar://23810212, which is an IRGen miscompile after the
optimizer cloned a strong_retain_autoreleased. There's no
point in adding this test case because the new SIL pattern
inherently prevents this transformation by construction.
The 'autorelease_return' and 'strong_retain_autoreleased'
instructions are now dead, and I will remove them in a
follow-up commit.
This is a bit of a hodge-podge of related changes that I decided
weren't quite worth teasing apart:
First, rename the weak{Retain,Release} entrypoints to
unowned{Retain,Release} to better reflect their actual use
from generated code.
Second, standardize the names of the rest of the entrypoints around
unowned{operation}.
Third, standardize IRGen's internal naming scheme and API for
reference-counting so that (1) there are generic functions for
emitting operations using a given reference-counting style and
(2) all operations explicitly call out the kind and style of
reference counting.
Finally, implement a number of new entrypoints for unknown unowned
reference-counting. These entrypoints use a completely different
and incompatible scheme for working with ObjC references. The
primary difference is that the new scheme abandons the flawed idea
(which I take responsibility for) that we can simulate an unowned
reference count for ObjC references, and instead moves towards an
address-only scheme when the reference might store an ObjC reference.
(The current implementation is still trivially takable, but that is
not something we should be relying on.) These will be tested in a
follow-up commit. For now, we still rely on the bad assumption of
reference-countability.
Converted the check that the DebugScope `DS` exists and that the
DebugScope's `SILFn` is the same as the `IGF`'s to an assertion
based on the FIXME's suggestion on line 831.
This commit adds a DebugVariable field that is shared by
- AllocBoxInst
- AllocStackInst
- DebugValueInst
- DebugValueAddrInst
Currently DebugVariable only holds the Swift argument number.
This allows us to retire several expensive heuristics in IRGen that
attempted to identify which local variables actually where arguments
and recover their relative order.
Memory footprint notes:
This commit adds a 4-byte field to 4 SILInstructin subclasses.
This was offset by 8ab1e2dd50
which removed 20 bytes from *every* SILInstruction.
Caveats:
This commit surfaces a known bug in FunctionSigantureOpts, tracked in
rdar://problem/23727705 — debug info for exploded function arguments
cannot be expressed until this is fixed.
This reapplies ed2b16dc5a with a bugfix for
generic function arrguments and an additional testcase.
<rdar://problem/21185379&22705926>
This commit adds a DebugVariable field that is shared by
- AllocBoxInst
- AllocStackInst
- DebugValueInst
- DebugValueAddrInst
Currently DebugVariable only holds the Swift argument number.
This allows us to retire several expensive heuristics in IRGen that
attempted to identify which local variables actually where arguments
and recover their relative order.
Memory footprint notes:
This commit adds a 4-byte field to 4 SILInstructin subclasses.
This was offset by 8ab1e2dd50
which removed 20 bytes from *every* SILInstruction.
Caveats:
This commit surfaces a known bug in FunctionSigantureOpts, tracked in
rdar://problem/23727705 — debug info for exploded function arguments
cannot be expressed until this is fixed.
<rdar://problem/21185379&22705926>
Handle such cases like partial applications of witness methods and applications of witness methods with substitutions.
Some of these uses-cases occur when there is a protocol defining an operator, a generic struct conforming to this protocol, and the operator conformance of this struct is expressed as a global function.
This is the first part of making class method dispatch resilient.
If we have the following class hierarchy:
// Module A
class Parent {
func foo() {}
}
class Child : Parent {}
// Module B
class Grandchild : Child {
override func foo() {
super.foo()
}
}
dispatch to `Parent.foo` will be static via a `function_ref`, so if
someone adds a `foo()` to `Child` later on, `Grandchild` won't know
about it without recompiling.
Stage in the IRGen portion of dynamic dispatch when calling methods on
`super`:
- Don't assert in IRGen if we see a native super_method instruction.
- Perform virtual lookup on superclass's metadata. If we see a
`super_method` instruction for a native class:
- Get the address of the superclass's metadata at offset 1
- Load the superclass's metadata
- Perform virtual lookup on this metadata instead
TODO: SILGen super_method instructions for native classes.
TODO: Devirtualize back down to static dispatch with a reslience lookup
mechanism.
rdar://problem/22749732
The drivers for this change are providing a simpler API to SIL pass
authors, having a more efficient of the in-memory representation,
and ruling out an entire class of common bugs that usually result
in hard-to-debug backend crashes.
Summary
-------
SILInstruction
Old New
+---------------+ +------------------+ +-----------------+
|SILInstruction | |SILInstruction | |SILDebugLocation |
+---------------+ +------------------+ +-----------------+
| ... | | ... | | ... |
|SILLocation | |SILDebugLocation *| -> |SILLocation |
|SILDebugScope *| +------------------+ |SILDebugScope * |
+---------------+ +-----------------+
We’re introducing a new class SILDebugLocation which represents the
combination of a SILLocation and a SILDebugScope.
Instead of storing an inline SILLocation and a SILDebugScope pointer,
SILInstruction now only has one SILDebugLocation pointer. The APIs of
SILBuilder and SILDebugLocation guarantees that every SILInstruction
has a nonempty SILDebugScope.
Developer-visible changes include:
SILBuilder
----------
In the old design SILBuilder populated the InsertedInstrs list to
allow setting the debug scopes of all built instructions in bulk
at the very end (as the responsibility of the user). In the new design,
SILBuilder now carries a "current debug scope" state and immediately
sets the debug scope when an instruction is inserted.
This fixes a use-after-free issue with with SIL passes that delete
instructions before destroying the SILBuilder that created them.
Because of this, SILBuilderWithScopes no longer needs to be a template,
which simplifies its call sites.
SILInstruction
--------------
It is neither possible or necessary to manually call setDebugScope()
on a SILInstruction any more. The function still exists as a private
method, but is only used when splicing instructions from one function
to another.
Efficiency
----------
In addition to dropping 20 bytes from each SILInstruction,
SILDebugLocations are now allocated in the SILModule's bump pointer
allocator and are uniqued by SILBuilder. Unfortunately repeat compiles
of the standard library already vary by about 5% so I couldn’t yet
produce reliable numbers for how much this saves overall.
rdar://problem/22017421
This means: handling of alloc_ref [stack].
It can be configured with two new options. See Option/FrontendOptions.td.
As the [stack] attribute is not generated yet, there should be NFC.
Swift SVN r32929
prologue is handled in the line table.
We now mark the first instruction after the stack setup as end_prologue and
any further initilizations (which may include function calls to metadata
accessors) with line 0 which lldb will skip. This allows swiftc to emit
debug info for compiler-generated functions such as metadata accessors.
Mixing debug and non-debug functions is not very well supported by LLVM
and the resulting line table makes it impossible for LLDB to determine
where a function with debug info ends and a nondebug function starts.
rdar://problem/23042642
Swift SVN r32816
This improves support for promoting to and generating
unchecked_ref_cast so we no longer need unchecked_ref_bit_cast, which
will just go away in the next commit.
Swift SVN r32597
- GenProto.cpp for protocols and protocol conformances
- GenExistential.cpp for existential type layout and operations
- GenArchetype.cpp for archetype type layout and operations
Swift SVN r32493
capture list arguments like "[weak self]". The better solution
would be to require all variables to be described with a
SILDebugValue(Addr) and then not describe capture list
arguments (tracked in rdar://21185379).
rdar://problem/22702122
Swift SVN r31963
rdar://22666588
This change removes a comparison and a branch on every virtual call. Before this
change we were generating code for comparing the metadata to figure out if the
incoming instance is an 'exact' cast, and then we checked if the result of the
cast was zero. This is unnecessary because we can simply reuse the result of the
exact metadata comparison. Moreover, we know that the metadata instance can't be
zero because we've emitted a load to that address that did not trap.
%1 = getelementptr inbounds %C4main1X, %C4main1X* %0 ...
%.metadata = load %swift.type*, %swift.type** %1 // Loading %0
%2 = icmp eq %swift.type* %.metadata, bitcast (...)
%3 = icmp ne %C4main1X* %0, null ; <----------- %0 can't be null.
%4 = and i1 %3, %2
br i1 %4, label %5, label %7
Swift SVN r31920
