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swift-mirror/lib/SILOptimizer/Mandatory/DiagnoseLifetimeIssues.cpp
Andrew Trick e705a6d7c3 Temporarily introduce AnyInteriorPointer operand ownership. 
This is necessary to fix a recent OSSA bug that breaks common occurrences on
mark_dependence [nonescaping]. Rather than reverting that change above, we make
forward progress toward implicit borrows scopes, as was the original intention.

In the near future, all InteriorPointer instructions will create an implicit
borrow scope. This means we have the option of not emitting extraneous
begin/end_borrow instructions around intructions like ref_element_addr,
open_existential, and project_box. After that, we can also migrate
GuaranteedForwarding instructions like tuple_extract and struct_extract.
2025-02-05 16:23:02 -08:00

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//==-------- DiagnoseLifetimeIssues.cpp - Diagnose lifetime issues ---------==//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2021 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
//
// This file implements a diagnostic pass that prints a warning if an object is
// stored to a weak property (or is weakly captured) and destroyed before the
// property (or captured reference) is ever used again.
// This can happen if the programmer relies on the lexical scope to keep an
// object alive, but copy-propagation can shrink the object's lifetime to its
// last use.
// For example:
//
// func test() {
// let k = Klass()
// // k is deallocated immediately after the closure capture (a store_weak).
// functionWithClosure({ [weak k] in
// // crash!
// k!.foo()
// })
// }
//
//===----------------------------------------------------------------------===//
#define DEBUG_TYPE "diagnose-lifetime-issues"
#include "swift/AST/DiagnosticsSIL.h"
#include "swift/Basic/Assertions.h"
#include "swift/Demangling/Demangler.h"
#include "swift/SIL/ApplySite.h"
#include "swift/SIL/BasicBlockBits.h"
#include "swift/SIL/OwnershipUtils.h"
#include "swift/SIL/PrunedLiveness.h"
#include "swift/SILOptimizer/PassManager/Transforms.h"
#include "clang/AST/DeclObjC.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/Support/Debug.h"
using namespace swift;
namespace {
/// Performs the analysis and prints the warnings.
class DiagnoseLifetimeIssues {
enum State {
/// There are no hidden uses which could keep the object alive.
DoesNotEscape,
/// For example, in case the object is stored somewhere.
CanEscape,
/// The object is stored to a weak reference field.
/// Implies ``DoesNotEscape``.
IsStoredWeakly
};
/// To avoid quadratic complexity in the rare corener case of very deep
/// callgraphs, with pass down references.
static constexpr int maxCallDepth = 8;
SILFunction *function = nullptr;
/// The liveness of the object in question, computed in visitUses.
BitfieldRef<SSAPrunedLiveness> liveness;
/// All weak stores of the object, which are found in visitUses.
llvm::SmallVector<SILInstruction *, 8> weakStores;
/// A cache for function argument states of called functions.
///
/// We could also cache this information in an Analysis, so that it persists
/// over runs of this pass for different functions. But computing the state
/// is very cheap and we avoid worst case scenarios with maxCallDepth. So it's
/// probably not worth doing it.
llvm::DenseMap<SILFunctionArgument *, State> argumentStates;
State visitUses(SILValue def, bool updateLivenessAndWeakStores, int callDepth);
State getArgumentState(ApplySite ai, Operand *applyOperand, int callDepth);
void reportDeadStore(SILInstruction *allocationInst);
public:
DiagnoseLifetimeIssues(SILFunction *function) : function(function) {}
void diagnose();
};
/// Returns true if def is an owned value resulting from an object allocation.
static bool isAllocation(SILInstruction *inst) {
auto *svi = dyn_cast<SingleValueInstruction>(inst);
if (!svi)
return false;
if (svi->getOwnershipKind() != OwnershipKind::Owned)
return false;
if (isa<AllocRefInst>(svi))
return true;
// Check if it's a call to an allocating initializer.
if (auto *applyInst = dyn_cast<ApplyInst>(svi)) {
SILFunction *callee = applyInst->getReferencedFunctionOrNull();
if (!callee)
return false;
Demangle::StackAllocatedDemangler<1024> demangler;
Demangle::Node *root = demangler.demangleSymbol(callee->getName());
return root && root->getKind() == Demangle::Node::Kind::Global &&
root->getFirstChild()->getKind() == Demangle::Node::Kind::Allocator;
}
return false;
}
/// Returns true if \p inst is a call of an ObjC setter to a weak property.
static bool isStoreObjcWeak(SILInstruction *inst, Operand *op) {
auto *apply = dyn_cast<ApplyInst>(inst);
if (!apply || apply->getNumArguments() < 1)
return false;
if (&apply->getArgumentOperands()[0] != op)
return false;
auto *method = dyn_cast<ObjCMethodInst>(apply->getCallee());
if (!method)
return false;
Decl *decl = method->getMember().getDecl();
auto *accessor = dyn_cast<AccessorDecl>(decl);
if (!accessor)
return false;
auto *var = dyn_cast<VarDecl>(accessor->getStorage());
if (!var)
return false;
ClangNode clangNode = var->getClangNode();
if (!clangNode)
return false;
auto *objcDecl = dyn_cast_or_null<clang::ObjCPropertyDecl>(clangNode.getAsDecl());
if (!objcDecl)
return false;
return objcDecl->getSetterKind() == clang::ObjCPropertyDecl::Weak;
}
/// Transitively iterates over all uses of \p def and - if \p
/// updateLivenessAndWeakStores is true - adds them to self.liveness.
/// If any weak stores are seen, add them to self.weakStores (also only if
/// \p updateLivenessAndWeakStores is true).
///
/// Returns the state of \p def. See DiagnoseLifetimeIssues::State.
DiagnoseLifetimeIssues::State DiagnoseLifetimeIssues::
visitUses(SILValue def, bool updateLivenessAndWeakStores, int callDepth) {
SmallPtrSet<SILValue, 32> defUseVisited;
SmallVector<SILValue, 32> defUseVector;
auto pushDef = [&](SILValue value) {
if (defUseVisited.insert(value).second)
defUseVector.push_back(value);
};
pushDef(def);
bool foundWeakStore = false;
while (!defUseVector.empty()) {
SILValue value = defUseVector.pop_back_val();
for (Operand *use : value->getUses()) {
auto *user = use->getUser();
// Recurse through copies and enums. Enums are important because the
// operand of a store_weak is always an Optional.
if (isa<CopyValueInst>(user)) {
pushDef(cast<SingleValueInstruction>(user));
continue;
}
if (isa<StoreWeakInst>(user) || isStoreObjcWeak(user, use)) {
if (updateLivenessAndWeakStores)
weakStores.push_back(user);
foundWeakStore = true;
continue;
}
if (ApplySite ai = ApplySite::isa(user)) {
// Try to get information from the called function.
switch (getArgumentState(ai, use, callDepth)) {
case DoesNotEscape:
if (updateLivenessAndWeakStores)
liveness->updateForUse(user, /*lifetimeEnding*/ false);
break;
case CanEscape:
return CanEscape;
case IsStoredWeakly:
if (updateLivenessAndWeakStores)
weakStores.push_back(user);
foundWeakStore = true;
}
continue;
}
switch (use->getOperandOwnership()) {
case OperandOwnership::NonUse:
break;
case OperandOwnership::TrivialUse:
llvm_unreachable("this operand cannot handle ownership");
// Conservatively treat a conversion to an unowned value as a pointer
// escape. Is it legal to canonicalize ForwardingUnowned?
case OperandOwnership::ForwardingUnowned:
case OperandOwnership::PointerEscape:
return CanEscape;
case OperandOwnership::InstantaneousUse:
case OperandOwnership::UnownedInstantaneousUse:
case OperandOwnership::BitwiseEscape:
if (updateLivenessAndWeakStores)
liveness->updateForUse(user, /*lifetimeEnding*/ false);
break;
case OperandOwnership::GuaranteedForwarding:
case OperandOwnership::ForwardingConsume:
// TermInst includes ReturnInst, which is generally an escape.
// If this is called as part of getArgumentState, then it is not really
// an escape, but we don't currently follow returned values.
if (isa<TermInst>(user))
return CanEscape;
for (SILValue result : user->getResults()) {
// This assumes that forwarding to a trivial value cannot extend the
// lifetime. This way, simply projecting a trivial value out of an
// aggregate isn't considered an escape.
if (result->getOwnershipKind() == OwnershipKind::None)
continue;
pushDef(result);
}
continue;
case OperandOwnership::DestroyingConsume:
// destroy_value does not force pruned liveness (but store etc. does).
if (!isa<DestroyValueInst>(user))
return CanEscape;
break;
case OperandOwnership::Borrow: {
if (updateLivenessAndWeakStores &&
(liveness->updateForBorrowingOperand(use) !=
InnerBorrowKind::Contained)) {
return CanEscape;
}
BorrowingOperand borrowOper(use);
if (borrowOper.hasBorrowIntroducingUser()) {
if (auto *beginBorrow = dyn_cast<BeginBorrowInst>(user))
pushDef(beginBorrow);
else
return CanEscape;
}
break;
}
case OperandOwnership::EndBorrow:
continue;
case OperandOwnership::InteriorPointer:
case OperandOwnership::AnyInteriorPointer:
// Treat most interior pointers as escapes until they can be audited.
// But if the interior pointer cannot be used to copy the parent
// reference, then it does not need to be considered an escape.
if (isa<RefElementAddrInst>(user)) {
continue;
}
return CanEscape;
case OperandOwnership::Reborrow:
return CanEscape;
}
}
}
return foundWeakStore ? IsStoredWeakly : DoesNotEscape;
}
/// Visits uses of an apply argument in the called function.
DiagnoseLifetimeIssues::State DiagnoseLifetimeIssues::
getArgumentState(ApplySite ai, Operand *applyOperand, int callDepth) {
if (callDepth >= maxCallDepth)
return CanEscape;
if (!FullApplySite::isa(ai.getInstruction()))
return CanEscape;
SILFunction *callee = ai.getReferencedFunctionOrNull();
if (!callee || callee->empty())
return CanEscape;
if (!ai.isArgumentOperand(*applyOperand))
return CanEscape;
SILBasicBlock *entryBlock = callee->getEntryBlock();
unsigned calleeIdx = ai.getCalleeArgIndex(*applyOperand);
auto *arg = cast<SILFunctionArgument>(entryBlock->getArgument(calleeIdx));
// Check if we already cached the analysis result.
auto iter = argumentStates.find(arg);
if (iter != argumentStates.end())
return iter->second;
// Before we continue with the recursion, already set a (conservative) state.
// This avoids infinite recursion in case of a cycle in the callgraph.
argumentStates[arg] = CanEscape;
State argState = visitUses(arg, /*updateLivenessAndWeakStores*/ false,
callDepth + 1);
argumentStates[arg] = argState;
return argState;
}
/// Returns true if \p inst is outside the pruned \p liveness.
static bool isOutOfLifetime(SILInstruction *inst, SSAPrunedLiveness &liveness) {
// Check if the lifetime of the stored object ends at the store_weak.
//
// A more sophisticated analysis would be to check if there are no
// (potential) loads from the store's destination address after the store,
// but within the object's liverange. But without a good alias analysis (and
// we don't want to use AliasAnalysis in a mandatory pass) it's practically
// impossible that a use of the object is not a potential load. So we would
// always see a potential load if the lifetime of the object goes beyond the
// store_weak.
return !liveness.isWithinBoundary(inst, /*deadEndBlocks=*/nullptr);
}
/// Reports a warning if the stored object \p storedObj is never loaded within
/// the lifetime of the stored object.
void DiagnoseLifetimeIssues::reportDeadStore(SILInstruction *allocationInst) {
BitfieldRef<SSAPrunedLiveness>::StackState livenessBitfieldContainer(
liveness, allocationInst->getFunction());
weakStores.clear();
SILValue storedDef = cast<SingleValueInstruction>(allocationInst);
liveness->initializeDef(storedDef);
// Compute the canonical lifetime of storedDef, like the copy-propagation pass
// would do.
State state = visitUses(storedDef, /*updateLivenessAndWeakStores*/ true,
/*callDepth*/ 0);
// If the allocation escapes (e.g. it is stored somewhere), we should not
// give a warning, because it can be a false alarm. The allocation could be
// kept alive by references we don't see.
if (state == CanEscape)
return;
assert((state == IsStoredWeakly) == !weakStores.empty());
for (SILInstruction *storeInst : weakStores) {
if (isOutOfLifetime(storeInst, *liveness)) {
// Issue the warning.
storeInst->getModule().getASTContext().Diags.diagnose(
storeInst->getLoc().getSourceLoc(), diag::warn_dead_weak_store);
}
}
}
/// Prints warnings for dead weak stores in \p function.
void DiagnoseLifetimeIssues::diagnose() {
for (SILBasicBlock &block : *function) {
for (SILInstruction &inst : block) {
// Only for allocations we know that a destroy will actually deallocate
// the object. Otherwise the object could be kept alive by other
// references and we would issue a false alarm.
if (isAllocation(&inst))
reportDeadStore(&inst);
}
}
}
//===----------------------------------------------------------------------===//
// The function pass
//===----------------------------------------------------------------------===//
class DiagnoseLifetimeIssuesPass : public SILFunctionTransform {
public:
DiagnoseLifetimeIssuesPass() {}
private:
void run() override {
SILFunction *function = getFunction();
// Don't rerun diagnostics on deserialized functions.
if (function->wasDeserializedCanonical())
return;
if (!function->hasOwnership())
return;
DiagnoseLifetimeIssues diagnoser(function);
diagnoser.diagnose();
}
};
} // end anonymous namespace
SILTransform *swift::createDiagnoseLifetimeIssues() {
return new DiagnoseLifetimeIssuesPass();
}
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