//===--- SILBuilder.cpp - Class for creating SIL Constructs ---------------===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2014 - 2016 Apple Inc. and the Swift project authors // Licensed under Apache License v2.0 with Runtime Library Exception // // See http://swift.org/LICENSE.txt for license information // See http://swift.org/CONTRIBUTORS.txt for the list of Swift project authors // //===----------------------------------------------------------------------===// #include "swift/SIL/SILBuilder.h" using namespace swift; //===----------------------------------------------------------------------===// // SILBuilder Implementation //===----------------------------------------------------------------------===// TupleInst *SILBuilder::createTuple(SILLocation loc, ArrayRef elts) { // Derive the tuple type from the elements. SmallVector eltTypes; for (auto elt : elts) eltTypes.push_back(elt->getType().getSwiftRValueType()); auto tupleType = SILType::getPrimitiveObjectType( CanType(TupleType::get(eltTypes, F.getASTContext()))); return createTuple(loc, tupleType, elts); } SILType SILBuilder::getPartialApplyResultType(SILType origTy, unsigned argCount, SILModule &M, ArrayRef subs) { CanSILFunctionType FTI = origTy.castTo(); if (!subs.empty()) FTI = FTI->substGenericArgs(M, M.getSwiftModule(), subs); assert(!FTI->isPolymorphic() && "must provide substitutions for generic partial_apply"); auto params = FTI->getParameters(); auto newParams = params.slice(0, params.size() - argCount); auto extInfo = SILFunctionType::ExtInfo( SILFunctionType::Representation::Thick, /*noreturn*/ FTI->isNoReturn()); auto appliedFnType = SILFunctionType::get(nullptr, extInfo, ParameterConvention::Direct_Owned, newParams, FTI->getAllResults(), FTI->getOptionalErrorResult(), M.getASTContext()); return SILType::getPrimitiveObjectType(appliedFnType); } // If legal, create an unchecked_ref_cast from the given operand and result // type, otherwise return null. SILInstruction *SILBuilder::tryCreateUncheckedRefCast(SILLocation Loc, SILValue Op, SILType ResultTy) { auto &M = F.getModule(); if (!SILType::canRefCast(Op->getType(), ResultTy, M)) return nullptr; return insert( new (M) UncheckedRefCastInst(getSILDebugLocation(Loc), Op, ResultTy)); } // Create the appropriate cast instruction based on result type. SILInstruction *SILBuilder::createUncheckedBitCast(SILLocation Loc, SILValue Op, SILType Ty) { auto &M = F.getModule(); if (Ty.isTrivial(M)) return insert( new (M) UncheckedTrivialBitCastInst(getSILDebugLocation(Loc), Op, Ty)); if (auto refCast = tryCreateUncheckedRefCast(Loc, Op, Ty)) return refCast; // The destination type is nontrivial, and may be smaller than the source // type, so RC identity cannot be assumed. return insert( new (M) UncheckedBitwiseCastInst(getSILDebugLocation(Loc), Op, Ty)); } BranchInst *SILBuilder::createBranch(SILLocation Loc, SILBasicBlock *TargetBlock, OperandValueArrayRef Args) { SmallVector ArgsCopy; ArgsCopy.reserve(Args.size()); for (auto I = Args.begin(), E = Args.end(); I != E; ++I) ArgsCopy.push_back(*I); return createBranch(Loc, TargetBlock, ArgsCopy); } /// \brief Branch to the given block if there's an active insertion point, /// then move the insertion point to the end of that block. void SILBuilder::emitBlock(SILBasicBlock *BB, SILLocation BranchLoc) { if (!hasValidInsertionPoint()) { return emitBlock(BB); } // Fall though from the currently active block into the given block. assert(BB->bbarg_empty() && "cannot fall through to bb with args"); // This is a fall through into BB, emit the fall through branch. createBranch(BranchLoc, BB); // Start inserting into that block. setInsertionPoint(BB); } /// splitBlockForFallthrough - Prepare for the insertion of a terminator. If /// the builder's insertion point is at the end of the current block (as when /// SILGen is creating the initial code for a function), just create and /// return a new basic block that will be later used for the continue point. /// /// If the insertion point is valid (i.e., pointing to an existing /// instruction) then split the block at that instruction and return the /// continuation block. SILBasicBlock *SILBuilder::splitBlockForFallthrough() { // If we are concatenating, just create and return a new block. if (insertingAtEndOfBlock()) { return new (F.getModule()) SILBasicBlock(&F, BB); } // Otherwise we need to split the current block at the insertion point. auto *NewBB = BB->splitBasicBlock(InsertPt); InsertPt = BB->end(); return NewBB; } PointerUnion SILBuilder::emitDestroyAddr(SILLocation Loc, SILValue Operand) { // Check to see if the instruction immediately before the insertion point is a // copy_addr from the specified operand. If so, we can fold this into the // copy_addr as a take. auto I = getInsertionPoint(), BBStart = getInsertionBB()->begin(); while (I != BBStart) { auto *Inst = &*--I; if (auto CA = dyn_cast(Inst)) { if (CA->getSrc() == Operand && !CA->isTakeOfSrc()) { CA->setIsTakeOfSrc(IsTake); return CA; } } // destroy_addrs commonly exist in a block of dealloc_stack's, which don't // affect take-ability. if (isa(Inst)) continue; // This code doesn't try to prove tricky validity constraints about whether // it is safe to push the destroy_addr past interesting instructions. if (Inst->mayHaveSideEffects()) break; } // If we didn't find a copy_addr to fold this into, emit the destroy_addr. return createDestroyAddr(Loc, Operand); } static bool couldReduceStrongRefcount(SILInstruction *Inst) { // Simple memory accesses cannot reduce refcounts. if (isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst) || isa(Inst)) return false; // Assign and copyaddr of trivial types cannot drop refcounts, and 'inits' // never can either. Nontrivial ones can though, because the overwritten // value drops a retain. We would have to do more alias analysis to be able // to safely ignore one of those. if (auto AI = dyn_cast(Inst)) { auto StoredType = AI->getOperand(0)->getType(); if (StoredType.isTrivial(Inst->getModule()) || StoredType.is()) return false; } if (auto *CAI = dyn_cast(Inst)) { // Initializations can only increase refcounts. if (CAI->isInitializationOfDest()) return false; SILType StoredType = CAI->getOperand(0)->getType().getObjectType(); if (StoredType.isTrivial(Inst->getModule()) || StoredType.is()) return false; } // This code doesn't try to prove tricky validity constraints about whether // it is safe to push the release past interesting instructions. return Inst->mayHaveSideEffects(); } /// Perform a strong_release instruction at the current location, attempting /// to fold it locally into nearby retain instructions or emitting an explicit /// strong release if necessary. If this inserts a new instruction, it /// returns it, otherwise it returns null. PointerUnion SILBuilder::emitStrongRelease(SILLocation Loc, SILValue Operand) { // Release on a functionref is a noop. if (isa(Operand)) { return static_cast(nullptr); } // Check to see if the instruction immediately before the insertion point is a // strong_retain of the specified operand. If so, we can zap the pair. auto I = getInsertionPoint(), BBStart = getInsertionBB()->begin(); while (I != BBStart) { auto *Inst = &*--I; if (auto *SRA = dyn_cast(Inst)) { if (SRA->getOperand() == Operand) return SRA; // Skip past unrelated retains. continue; } // Scan past simple instructions that cannot reduce strong refcounts. if (couldReduceStrongRefcount(Inst)) break; } // If we didn't find a retain to fold this into, emit the release. return createStrongRelease(Loc, Operand); } /// Emit a release_value instruction at the current location, attempting to /// fold it locally into another nearby retain_value instruction. This /// returns the new instruction if it inserts one, otherwise it returns null. PointerUnion SILBuilder::emitReleaseValue(SILLocation Loc, SILValue Operand) { // Check to see if the instruction immediately before the insertion point is a // retain_value of the specified operand. If so, we can zap the pair. auto I = getInsertionPoint(), BBStart = getInsertionBB()->begin(); while (I != BBStart) { auto *Inst = &*--I; if (auto *SRA = dyn_cast(Inst)) { if (SRA->getOperand() == Operand) return SRA; // Skip past unrelated retains. continue; } // Scan past simple instructions that cannot reduce refcounts. if (couldReduceStrongRefcount(Inst)) break; } // If we didn't find a retain to fold this into, emit the release. return createReleaseValue(Loc, Operand); } SILValue SILBuilder::emitThickToObjCMetatype(SILLocation Loc, SILValue Op, SILType Ty) { // If the operand is an otherwise-unused 'metatype' instruction in the // same basic block, zap it and create a 'metatype' instruction that // directly produces an Objective-C metatype. if (auto metatypeInst = dyn_cast(Op)) { if (metatypeInst->use_empty() && metatypeInst->getParent() == getInsertionBB()) { auto origLoc = metatypeInst->getLoc(); metatypeInst->removeFromParent(); return createMetatype(origLoc, Ty); } } // Just create the thick_to_objc_metatype instruction. return createThickToObjCMetatype(Loc, Op, Ty); } SILValue SILBuilder::emitObjCToThickMetatype(SILLocation Loc, SILValue Op, SILType Ty) { // If the operand is an otherwise-unused 'metatype' instruction in the // same basic block, zap it and create a 'metatype' instruction that // directly produces a thick metatype. if (auto metatypeInst = dyn_cast(Op)) { if (metatypeInst->use_empty() && metatypeInst->getParent() == getInsertionBB()) { auto origLoc = metatypeInst->getLoc(); metatypeInst->removeFromParent(); return createMetatype(origLoc, Ty); } } // Just create the objc_to_thick_metatype instruction. return createObjCToThickMetatype(Loc, Op, Ty); }