lib/SILGen/Condition.cpp - third_party/swift - Git at Google

 //===--- Condition.cpp - Implements the SILGen Condition class ------------===//
 //
 // This source file is part of the Swift.org open source project
 //
 // Copyright (c) 2014 - 2017 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
 //
 //===----------------------------------------------------------------------===//

 #include "Condition.h"
 #include "Initialization.h"
 #include "ManagedValue.h"
 #include "RValue.h"
 #include "swift/SIL/SILArgument.h"
 #include "swift/SIL/SILFunction.h"
 using namespace swift;
 using namespace Lowering;

 void Condition::enterTrue(SILGenFunction &SGF) {
   assert(TrueBB && "Cannot call enterTrue without a True block!");

   // TrueBB has already been inserted somewhere unless there's a
   // continuation block.
   if (!ContBB) return;

   SGF.B.emitBlock(TrueBB);
 }

 /// Extract the last SILLocation used in BB.
 static SILLocation getContinuationLoc(SILBasicBlock &BB, SILLocation Fallback) {
   for (auto I = BB.rbegin(); I != BB.rend(); ++I)
     if (auto L = I->getLoc())
       return L;
   return Fallback;
 }
 void Condition::exitTrue(SILGenFunction &SGF, ArrayRef<SILValue> Args) {
   // If there's no continuation block, it's because the condition was
   // folded to true.  In that case, we just continue emitting code as
   // if we were still in the true case, and we're unreachable iff the
   // end of the true case is unreachable.  In other words, there's
   // nothing to do.
   if (!ContBB) {
     assert(!FalseBB && "no continuation");
     return;
   }

   // If there is a continuation block, we should branch to it if the
   // current point is reachable.
   if (!SGF.B.hasValidInsertionPoint()) {
     // If there is no false code, the continuation block has a use
     // because the main condition jumps directly to it.
     assert(ContBB->pred_empty() || !FalseBB);
     return;
   }

   // Otherwise, resume into the continuation block.  This branch might
   // be folded by exitFalse if it turns out that that point is
   // unreachable.
   SGF.B.createBranch(getContinuationLoc(*SGF.B.getInsertionBB(), Loc),
                      ContBB, Args);

   // Coming out of exitTrue, we can be in one of three states:
   //   - a valid non-terminal IP, but only if there is no continuation
   //     block, which is only possible if there is no false block;
   //   - a valid terminal IP, if the end of the true block was reachable; or
   //   - a cleared IP, if the end of the true block was not reachable.
 }

 void Condition::enterFalse(SILGenFunction &SGF) {
   assert(FalseBB && "entering the false branch when it was not valid");

   // FalseBB has already been inserted somewhere unless there's a
   // continuation block.
   if (!ContBB) return;

   // It's possible to have no insertion point here if the end of the
   // true case was unreachable.
   SGF.B.emitBlock(FalseBB);
 }

 void Condition::exitFalse(SILGenFunction &SGF, ArrayRef<SILValue> Args) {
   // If there's no continuation block, it's because the condition was
   // folded to false.  In that case, we just continue emitting code as
   // if we were still in the false case, and we're unreachable iff the
   // end of the false case is unreachable.  In other words, there's
   // nothing to do.
   if (!ContBB) return;

   if (ContBB->pred_empty()) {
     // If the true case didn't need the continuation block, then
     // we don't either, regardless of whether the current location
     // is reachable.  Just keep inserting / being unreachable
     // right where we are.
   } else if (!SGF.B.hasValidInsertionPoint()) {
     // If the true case did need the continuation block, but the false
     // case doesn't, just merge the continuation block back into its
     // single predecessor and move the IP there.
     //
     // Note that doing this tends to strand the false code after
     // everything else in the function, so maybe it's not a great idea.
     auto PI = ContBB->pred_begin();
     SILBasicBlock *ContPred = *PI;

     // Verify there was only a single predecessor to ContBB.
     ++PI;
     assert(PI == ContBB->pred_end() && "Only expect one branch to the ContBB");

     // Insert before the uncond branch and zap it.
     auto *Br = cast<BranchInst>(ContPred->getTerminator());
     SGF.B.setInsertionPoint(Br->getParent());

     Br->eraseFromParent();
     assert(ContBB->pred_empty() &&
            "Zapping the branch should make ContBB dead");
   } else {
     // Otherwise, branch to the continuation block and start inserting there.
     SGF.B.createBranch(getContinuationLoc(*SGF.B.getInsertionBB(), Loc),
                        ContBB, Args);
   }
 }

 SILBasicBlock *Condition::complete(SILGenFunction &SGF) {
   // If there is no continuation block, it's because we
   // constant-folded the branch.  The case-exit will have left us in a
   // normal insertion state (i.e. not a post-terminator IP) with
   // nothing to clean up after.
   if (!ContBB) {
     return SGF.B.getInsertionBB();
   }

   // Kill the continuation block if it's not being used.  Case-exits
   // only leave themselves post-terminator if they use the
   // continuation block, so we're in an acceptable insertion state.
   if (ContBB->pred_empty() && ContBB->args_empty()) {
     SGF.eraseBasicBlock(ContBB);
     return SGF.B.hasValidInsertionPoint() ? SGF.B.getInsertionBB() : nullptr;
   }

   // Okay, we need to insert the continuation block.
   SGF.B.emitBlock(ContBB);
   return ContBB;
 }

 ConditionalValue::ConditionalValue(SILGenFunction &SGF, SGFContext C,
                                    SILLocation loc,
                                    const TypeLowering &valueTL)
   : SGF(SGF), tl(valueTL), contBB(SGF.createBasicBlock()), loc(loc)
 {
   if (tl.isAddressOnly()) {
     // If the result type is address-only, get a result buffer for it.
     result = SGF.getBufferForExprResult(loc, tl.getLoweredType(), C);
   } else {
     // Otherwise, add a BB arg to the continuation block to receive loadable
     // result.
     result = contBB->createPHIArgument(tl.getLoweredType(),
                                        ValueOwnershipKind::Owned);
   }
 }

 SGFContext ConditionalValue::enterBranch(SILBasicBlock *bb) {
   if (bb) {
     assert(!SGF.B.hasValidInsertionPoint() && "already in a branch");
     SGF.B.emitBlock(bb);
   }

   assert(!scope.hasValue() && "already have a scope");
   // Start a scope for the current branch.
   scope.emplace(SGF.Cleanups, CleanupLocation::get(loc));

   // Code emitted in the branch can emit into our buffer for address-only
   // conditionals.
   if (tl.isAddressOnly()) {
     assert(!currentInitialization && "already have an initialization?!");
     currentInitialization = SGF.useBufferAsTemporary(result, tl);
     return SGFContext(currentInitialization.get());
   }

   /// TODO: We might be able to coordinate AllowPlusZero across conditionals
   /// if all branches of the conditional can actually produce a +0 result.
   return SGFContext();
 }

 void ConditionalValue::exitBranch(RValue &&condResult) {
   assert(scope.hasValue() && "no current scope?!");
   if (tl.isAddressOnly()) {
     // Transfer the result into our buffer if it wasn't emitted in-place
     // already.
     assert(currentInitialization && "no current initialization?!");
     std::move(condResult).forwardInto(SGF, loc,
                                       currentInitialization.release());
     scope.reset();
     SGF.B.createBranch(loc, contBB);
   } else {
     SILValue resultVal = std::move(condResult).forwardAsSingleValue(SGF, loc);
     // Branch with the result as a BB argument.
     scope.reset();
     SGF.B.createBranch(loc, contBB, resultVal);
   }
 }

 ManagedValue ConditionalValue::complete() {
   assert(!SGF.B.hasValidInsertionPoint() && "still in a branch");
   assert(!scope && "still in a branch scope");
   assert(!currentInitialization && "still in a branch initialization");
   SGF.B.emitBlock(contBB);
   return SGF.emitManagedRValueWithCleanup(result);
 }
	//===--- Condition.cpp - Implements the SILGen Condition class ------------===//
	//
	// This source file is part of the Swift.org open source project
	//
	// Copyright (c) 2014 - 2017 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
	//
	//===----------------------------------------------------------------------===//

	#include "Condition.h"
	#include "Initialization.h"
	#include "ManagedValue.h"
	#include "RValue.h"
	#include "swift/SIL/SILArgument.h"
	#include "swift/SIL/SILFunction.h"
	using namespace swift;
	using namespace Lowering;

	void Condition::enterTrue(SILGenFunction &SGF) {
	assert(TrueBB && "Cannot call enterTrue without a True block!");

	// TrueBB has already been inserted somewhere unless there's a
	// continuation block.
	if (!ContBB) return;

	SGF.B.emitBlock(TrueBB);
	}

	/// Extract the last SILLocation used in BB.
	static SILLocation getContinuationLoc(SILBasicBlock &BB, SILLocation Fallback) {
	for (auto I = BB.rbegin(); I != BB.rend(); ++I)
	if (auto L = I->getLoc())
	return L;
	return Fallback;
	}
	void Condition::exitTrue(SILGenFunction &SGF, ArrayRef<SILValue> Args) {
	// If there's no continuation block, it's because the condition was
	// folded to true. In that case, we just continue emitting code as
	// if we were still in the true case, and we're unreachable iff the
	// end of the true case is unreachable. In other words, there's
	// nothing to do.
	if (!ContBB) {
	assert(!FalseBB && "no continuation");
	return;
	}

	// If there is a continuation block, we should branch to it if the
	// current point is reachable.
	if (!SGF.B.hasValidInsertionPoint()) {
	// If there is no false code, the continuation block has a use
	// because the main condition jumps directly to it.
	assert(ContBB->pred_empty() \|\| !FalseBB);
	return;
	}

	// Otherwise, resume into the continuation block. This branch might
	// be folded by exitFalse if it turns out that that point is
	// unreachable.
	SGF.B.createBranch(getContinuationLoc(*SGF.B.getInsertionBB(), Loc),
	ContBB, Args);

	// Coming out of exitTrue, we can be in one of three states:
	// - a valid non-terminal IP, but only if there is no continuation
	// block, which is only possible if there is no false block;
	// - a valid terminal IP, if the end of the true block was reachable; or
	// - a cleared IP, if the end of the true block was not reachable.
	}

	void Condition::enterFalse(SILGenFunction &SGF) {
	assert(FalseBB && "entering the false branch when it was not valid");

	// FalseBB has already been inserted somewhere unless there's a
	// continuation block.
	if (!ContBB) return;

	// It's possible to have no insertion point here if the end of the
	// true case was unreachable.
	SGF.B.emitBlock(FalseBB);
	}

	void Condition::exitFalse(SILGenFunction &SGF, ArrayRef<SILValue> Args) {
	// If there's no continuation block, it's because the condition was
	// folded to false. In that case, we just continue emitting code as
	// if we were still in the false case, and we're unreachable iff the
	// end of the false case is unreachable. In other words, there's
	// nothing to do.
	if (!ContBB) return;

	if (ContBB->pred_empty()) {
	// If the true case didn't need the continuation block, then
	// we don't either, regardless of whether the current location
	// is reachable. Just keep inserting / being unreachable
	// right where we are.
	} else if (!SGF.B.hasValidInsertionPoint()) {
	// If the true case did need the continuation block, but the false
	// case doesn't, just merge the continuation block back into its
	// single predecessor and move the IP there.
	//
	// Note that doing this tends to strand the false code after
	// everything else in the function, so maybe it's not a great idea.
	auto PI = ContBB->pred_begin();
	SILBasicBlock ContPred = PI;

	// Verify there was only a single predecessor to ContBB.
	++PI;
	assert(PI == ContBB->pred_end() && "Only expect one branch to the ContBB");

	// Insert before the uncond branch and zap it.
	auto *Br = cast<BranchInst>(ContPred->getTerminator());
	SGF.B.setInsertionPoint(Br->getParent());

	Br->eraseFromParent();
	assert(ContBB->pred_empty() &&
	"Zapping the branch should make ContBB dead");
	} else {
	// Otherwise, branch to the continuation block and start inserting there.
	SGF.B.createBranch(getContinuationLoc(*SGF.B.getInsertionBB(), Loc),
	ContBB, Args);
	}
	}

	SILBasicBlock *Condition::complete(SILGenFunction &SGF) {
	// If there is no continuation block, it's because we
	// constant-folded the branch. The case-exit will have left us in a
	// normal insertion state (i.e. not a post-terminator IP) with
	// nothing to clean up after.
	if (!ContBB) {
	return SGF.B.getInsertionBB();
	}

	// Kill the continuation block if it's not being used. Case-exits
	// only leave themselves post-terminator if they use the
	// continuation block, so we're in an acceptable insertion state.
	if (ContBB->pred_empty() && ContBB->args_empty()) {
	SGF.eraseBasicBlock(ContBB);
	return SGF.B.hasValidInsertionPoint() ? SGF.B.getInsertionBB() : nullptr;
	}

	// Okay, we need to insert the continuation block.
	SGF.B.emitBlock(ContBB);
	return ContBB;
	}

	ConditionalValue::ConditionalValue(SILGenFunction &SGF, SGFContext C,
	SILLocation loc,
	const TypeLowering &valueTL)
	: SGF(SGF), tl(valueTL), contBB(SGF.createBasicBlock()), loc(loc)
	{
	if (tl.isAddressOnly()) {
	// If the result type is address-only, get a result buffer for it.
	result = SGF.getBufferForExprResult(loc, tl.getLoweredType(), C);
	} else {
	// Otherwise, add a BB arg to the continuation block to receive loadable
	// result.
	result = contBB->createPHIArgument(tl.getLoweredType(),
	ValueOwnershipKind::Owned);
	}
	}

	SGFContext ConditionalValue::enterBranch(SILBasicBlock *bb) {
	if (bb) {
	assert(!SGF.B.hasValidInsertionPoint() && "already in a branch");
	SGF.B.emitBlock(bb);
	}

	assert(!scope.hasValue() && "already have a scope");
	// Start a scope for the current branch.
	scope.emplace(SGF.Cleanups, CleanupLocation::get(loc));

	// Code emitted in the branch can emit into our buffer for address-only
	// conditionals.
	if (tl.isAddressOnly()) {
	assert(!currentInitialization && "already have an initialization?!");
	currentInitialization = SGF.useBufferAsTemporary(result, tl);
	return SGFContext(currentInitialization.get());
	}

	/// TODO: We might be able to coordinate AllowPlusZero across conditionals
	/// if all branches of the conditional can actually produce a +0 result.
	return SGFContext();
	}

	void ConditionalValue::exitBranch(RValue &&condResult) {
	assert(scope.hasValue() && "no current scope?!");
	if (tl.isAddressOnly()) {
	// Transfer the result into our buffer if it wasn't emitted in-place
	// already.
	assert(currentInitialization && "no current initialization?!");
	std::move(condResult).forwardInto(SGF, loc,
	currentInitialization.release());
	scope.reset();
	SGF.B.createBranch(loc, contBB);
	} else {
	SILValue resultVal = std::move(condResult).forwardAsSingleValue(SGF, loc);
	// Branch with the result as a BB argument.
	scope.reset();
	SGF.B.createBranch(loc, contBB, resultVal);
	}
	}

	ManagedValue ConditionalValue::complete() {
	assert(!SGF.B.hasValidInsertionPoint() && "still in a branch");
	assert(!scope && "still in a branch scope");
	assert(!currentInitialization && "still in a branch initialization");
	SGF.B.emitBlock(contBB);
	return SGF.emitManagedRValueWithCleanup(result);
	}