third_party/llvm-7.0/llvm/unittests/IR/DeferredDominanceTest.cpp - SwiftShader - Git at Google

 //===- llvm/unittests/IR/DeferredDominanceTest.cpp - DDT unit tests -------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/AsmParser/Parser.h"
 #include "llvm/IR/Constants.h"
 #include "llvm/IR/Dominators.h"
 #include "llvm/IR/Instructions.h"
 #include "llvm/IR/LLVMContext.h"
 #include "llvm/IR/Module.h"
 #include "llvm/Support/SourceMgr.h"
 #include "gtest/gtest.h"

 using namespace llvm;

 static std::unique_ptr<Module> makeLLVMModule(LLVMContext &Context,
                                               StringRef ModuleStr) {
   SMDiagnostic Err;
   std::unique_ptr<Module> M = parseAssemblyString(ModuleStr, Err, Context);
   assert(M && "Bad LLVM IR?");
   return M;
 }

 TEST(DeferredDominance, BasicOperations) {
   StringRef FuncName = "f";
   StringRef ModuleString =
       "define i32 @f(i32 %i, i32 *%p) {\n"
       " bb0:\n"
       "   store i32 %i, i32 *%p\n"
       "   switch i32 %i, label %bb1 [\n"
       "     i32 0, label %bb2\n"
       "     i32 1, label %bb2\n"
       "     i32 2, label %bb3\n"
       "   ]\n"
       " bb1:\n"
       "   ret i32 1\n"
       " bb2:\n"
       "   ret i32 2\n"
       " bb3:\n"
       "   ret i32 3\n"
       "}\n";
   // Make the module.
   LLVMContext Context;
   std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
   Function *F = M->getFunction(FuncName);
   ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

   // Make the DDT.
   DominatorTree DT(*F);
   DeferredDominance DDT(DT);
   ASSERT_TRUE(DDT.flush().verify());

   Function::iterator FI = F->begin();
   BasicBlock *BB0 = &*FI++;
   BasicBlock *BB1 = &*FI++;
   BasicBlock *BB2 = &*FI++;
   BasicBlock *BB3 = &*FI++;

   // Test discards of invalid self-domination updates. These use the single
   // short-hand interface but are still queued inside DDT.
   DDT.deleteEdge(BB0, BB0);
   DDT.insertEdge(BB1, BB1);

   // Delete edge bb0 -> bb3 and push the update twice to verify duplicate
   // entries are discarded.
   std::vector<DominatorTree::UpdateType> Updates;
   Updates.reserve(4);
   Updates.push_back({DominatorTree::Delete, BB0, BB3});
   Updates.push_back({DominatorTree::Delete, BB0, BB3});

   // Unnecessary Insert: no edge bb1 -> bb2 after change to bb0.
   Updates.push_back({DominatorTree::Insert, BB1, BB2});
   // Unnecessary Delete: edge exists bb0 -> bb1 after change to bb0.
   Updates.push_back({DominatorTree::Delete, BB0, BB1});

   // CFG Change: remove edge bb0 -> bb3 and one duplicate edge bb0 -> bb2.
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 4u);
   BB0->getTerminator()->eraseFromParent();
   BranchInst::Create(BB1, BB2, ConstantInt::getTrue(F->getContext()), BB0);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

   // Deletion of a BasicBlock is an immediate event. We remove all uses to the
   // contained Instructions and change the Terminator to "unreachable" when
   // queued for deletion. Its parent is still F until DDT.flush() is called. We
   // don't defer this action because it can cause problems for other transforms
   // or analysis as it's part of the actual CFG. We only defer updates to the
   // DominatorTree. This code will crash if it is placed before the
   // BranchInst::Create() call above.
   ASSERT_FALSE(isa<UnreachableInst>(BB3->getTerminator()));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB3));
   DDT.deleteBB(BB3);
   EXPECT_TRUE(DDT.pendingDeletedBB(BB3));
   ASSERT_TRUE(isa<UnreachableInst>(BB3->getTerminator()));
   EXPECT_EQ(BB3->getParent(), F);

   // Verify. Updates to DDT must be applied *after* all changes to the CFG
   // (including block deletion).
   DDT.applyUpdates(Updates);
   ASSERT_TRUE(DDT.flush().verify());
 }

 TEST(DeferredDominance, PairedUpdate) {
   StringRef FuncName = "f";
   StringRef ModuleString =
       "define i32 @f(i32 %i, i32 *%p) {\n"
       " bb0:\n"
       "   store i32 %i, i32 *%p\n"
       "   switch i32 %i, label %bb1 [\n"
       "     i32 0, label %bb2\n"
       "     i32 1, label %bb2\n"
       "   ]\n"
       " bb1:\n"
       "   ret i32 1\n"
       " bb2:\n"
       "   ret i32 2\n"
       "}\n";
   // Make the module.
   LLVMContext Context;
   std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
   Function *F = M->getFunction(FuncName);
   ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

   // Make the DDT.
   DominatorTree DT(*F);
   DeferredDominance DDT(DT);
   ASSERT_TRUE(DDT.flush().verify());

   Function::iterator FI = F->begin();
   BasicBlock *BB0 = &*FI++;
   BasicBlock *BB1 = &*FI++;
   BasicBlock *BB2 = &*FI++;

   // CFG Change: only edge from bb0 is bb0 -> bb1.
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 3u);
   BB0->getTerminator()->eraseFromParent();
   BranchInst::Create(BB1, BB0);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

   // Must be done after the CFG change. The applyUpdate() routine analyzes the
   // current state of the CFG.
   DDT.deleteEdge(BB0, BB2);

   // CFG Change: bb0 now has bb0 -> bb1 and bb0 -> bb2.
   // With this change no dominance has been altered from the original IR. DT
   // doesn't care if the type of TerminatorInstruction changed, only if the
   // unique edges have.
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);
   BB0->getTerminator()->eraseFromParent();
   BranchInst::Create(BB1, BB2, ConstantInt::getTrue(F->getContext()), BB0);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

   // Must be done after the CFG change. The applyUpdate() routine analyzes the
   // current state of the CFG. This DDT update pairs with the previous one and
   // is cancelled out before ever applying updates to DT.
   DDT.insertEdge(BB0, BB2);

   // Test the empty DeletedBB list.
   EXPECT_FALSE(DDT.pendingDeletedBB(BB0));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB1));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB2));

   // The DT has no changes, this flush() simply returns a reference to the
   // internal DT calculated at the beginning of this test.
   ASSERT_TRUE(DDT.flush().verify());
 }

 TEST(DeferredDominance, ReplaceEntryBB) {
   StringRef FuncName = "f";
   StringRef ModuleString =
       "define i32 @f() {\n"
       "bb0:\n"
       "   br label %bb1\n"
       " bb1:\n"
       "   ret i32 1\n"
       "}\n";
   // Make the module.
   LLVMContext Context;
   std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
   Function *F = M->getFunction(FuncName);
   ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

   // Make the DDT.
   DominatorTree DT(*F);
   DeferredDominance DDT(DT);
   ASSERT_TRUE(DDT.flush().verify());

   Function::iterator FI = F->begin();
   BasicBlock *BB0 = &*FI++;
   BasicBlock *BB1 = &*FI++;

   // Add a block as the new function entry BB. We also link it to BB0.
   BasicBlock *NewEntry =
       BasicBlock::Create(F->getContext(), "new_entry", F, BB0);
   BranchInst::Create(BB0, NewEntry);
   EXPECT_EQ(F->begin()->getName(), NewEntry->getName());
   EXPECT_TRUE(&F->getEntryBlock() == NewEntry);

   // Insert the new edge between new_eentry -> bb0. Without this the
   // recalculate() call below will not actually recalculate the DT as there
   // are no changes pending and no blocks deleted.
   DDT.insertEdge(NewEntry, BB0);

   // Changing the Entry BB requires a full recalulation.
   DDT.recalculate(*F);
   ASSERT_TRUE(DDT.flush().verify());

   // CFG Change: remove new_edge -> bb0 and redirect to new_edge -> bb1.
   EXPECT_EQ(NewEntry->getTerminator()->getNumSuccessors(), 1u);
   NewEntry->getTerminator()->eraseFromParent();
   BranchInst::Create(BB1, NewEntry);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

   // Update the DDT. At this point bb0 now has no predecessors but is still a
   // Child of F.
   DDT.applyUpdates({{DominatorTree::Delete, NewEntry, BB0},
                     {DominatorTree::Insert, NewEntry, BB1}});
   ASSERT_TRUE(DDT.flush().verify());

   // Now remove bb0 from F.
   ASSERT_FALSE(isa<UnreachableInst>(BB0->getTerminator()));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB0));
   DDT.deleteBB(BB0);
   EXPECT_TRUE(DDT.pendingDeletedBB(BB0));
   ASSERT_TRUE(isa<UnreachableInst>(BB0->getTerminator()));
   EXPECT_EQ(BB0->getParent(), F);

   // Perform a full recalculation of the DDT. It is not necessary here but we
   // do this to test the case when there are no pending DT updates but there are
   // pending deleted BBs.
   DDT.recalculate(*F);
   ASSERT_TRUE(DDT.flush().verify());
 }

 TEST(DeferredDominance, InheritedPreds) {
   StringRef FuncName = "f";
   StringRef ModuleString =
       "define i32 @f(i32 %i, i32 *%p) {\n"
       " bb0:\n"
       "   store i32 %i, i32 *%p\n"
       "   switch i32 %i, label %bb1 [\n"
       "     i32 2, label %bb2\n"
       "     i32 3, label %bb3\n"
       "   ]\n"
       " bb1:\n"
       "   br label %bb3\n"
       " bb2:\n"
       "   br label %bb3\n"
       " bb3:\n"
       "   ret i32 3\n"
       "}\n";
   // Make the module.
   LLVMContext Context;
   std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
   Function *F = M->getFunction(FuncName);
   ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

   // Make the DDT.
   DominatorTree DT(*F);
   DeferredDominance DDT(DT);
   ASSERT_TRUE(DDT.flush().verify());

   Function::iterator FI = F->begin();
   BasicBlock *BB0 = &*FI++;
   BasicBlock *BB1 = &*FI++;
   BasicBlock *BB2 = &*FI++;
   BasicBlock *BB3 = &*FI++;

   // There are several CFG locations where we have:
   //
   //   pred1..predN
   //    |        |
   //    +> curr <+    converted into:   pred1..predN curr
   //        |                            |        |
   //        v                            +> succ <+
   //       succ
   //
   // There is a specific shape of this we have to be careful of:
   //
   //   pred1..predN
   //   ||        |
   //   |+> curr <+    converted into:   pred1..predN curr
   //   |    |                            |        |
   //   |    v                            +> succ <+
   //   +-> succ
   //
   // While the final CFG form is functionally identical the updates to
   // DDT are not. In the first case we must have DDT.insertEdge(Pred1, Succ)
   // while in the latter case we must *NOT* have DDT.insertEdge(Pred1, Succ).

   // CFG Change: bb0 now only has bb0 -> bb1 and bb0 -> bb3. We are preparing to
   // remove bb2.
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 3u);
   BB0->getTerminator()->eraseFromParent();
   BranchInst::Create(BB1, BB3, ConstantInt::getTrue(F->getContext()), BB0);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

   // Remove bb2 from F. This has to happen before the call to applyUpdates() for
   // DDT to detect there is no longer an edge between bb2 -> bb3. The deleteBB()
   // method converts bb2's TI into "unreachable".
   ASSERT_FALSE(isa<UnreachableInst>(BB2->getTerminator()));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB2));
   DDT.deleteBB(BB2);
   EXPECT_TRUE(DDT.pendingDeletedBB(BB2));
   ASSERT_TRUE(isa<UnreachableInst>(BB2->getTerminator()));
   EXPECT_EQ(BB2->getParent(), F);

   // Queue up the DDT updates.
   std::vector<DominatorTree::UpdateType> Updates;
   Updates.reserve(4);
   Updates.push_back({DominatorTree::Delete, BB0, BB2});
   Updates.push_back({DominatorTree::Delete, BB2, BB3});

   // Handle the specific shape case next.
   // CFG Change: bb0 now only branches to bb3. We are preparing to remove bb1.
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);
   BB0->getTerminator()->eraseFromParent();
   BranchInst::Create(BB3, BB0);
   EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

   // Remove bb1 from F. This has to happen before the call to applyUpdates() for
   // DDT to detect there is no longer an edge between bb1 -> bb3. The deleteBB()
   // method converts bb1's TI into "unreachable".
   ASSERT_FALSE(isa<UnreachableInst>(BB1->getTerminator()));
   EXPECT_FALSE(DDT.pendingDeletedBB(BB1));
   DDT.deleteBB(BB1);
   EXPECT_TRUE(DDT.pendingDeletedBB(BB1));
   ASSERT_TRUE(isa<UnreachableInst>(BB1->getTerminator()));
   EXPECT_EQ(BB1->getParent(), F);

   // Update the DDT. In this case we don't call DDT.insertEdge(BB0, BB3) because
   // the edge previously existed at the start of this test when DT was first
   // created.
   Updates.push_back({DominatorTree::Delete, BB0, BB1});
   Updates.push_back({DominatorTree::Delete, BB1, BB3});

   // Verify everything.
   DDT.applyUpdates(Updates);
   ASSERT_TRUE(DDT.flush().verify());
 }
	//===- llvm/unittests/IR/DeferredDominanceTest.cpp - DDT unit tests -------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/AsmParser/Parser.h"
	#include "llvm/IR/Constants.h"
	#include "llvm/IR/Dominators.h"
	#include "llvm/IR/Instructions.h"
	#include "llvm/IR/LLVMContext.h"
	#include "llvm/IR/Module.h"
	#include "llvm/Support/SourceMgr.h"
	#include "gtest/gtest.h"

	using namespace llvm;

	static std::unique_ptr<Module> makeLLVMModule(LLVMContext &Context,
	StringRef ModuleStr) {
	SMDiagnostic Err;
	std::unique_ptr<Module> M = parseAssemblyString(ModuleStr, Err, Context);
	assert(M && "Bad LLVM IR?");
	return M;
	}

	TEST(DeferredDominance, BasicOperations) {
	StringRef FuncName = "f";
	StringRef ModuleString =
	"define i32 @f(i32 %i, i32 *%p) {\n"
	" bb0:\n"
	" store i32 %i, i32 *%p\n"
	" switch i32 %i, label %bb1 [\n"
	" i32 0, label %bb2\n"
	" i32 1, label %bb2\n"
	" i32 2, label %bb3\n"
	" ]\n"
	" bb1:\n"
	" ret i32 1\n"
	" bb2:\n"
	" ret i32 2\n"
	" bb3:\n"
	" ret i32 3\n"
	"}\n";
	// Make the module.
	LLVMContext Context;
	std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
	Function *F = M->getFunction(FuncName);
	ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

	// Make the DDT.
	DominatorTree DT(*F);
	DeferredDominance DDT(DT);
	ASSERT_TRUE(DDT.flush().verify());

	Function::iterator FI = F->begin();
	BasicBlock BB0 = &FI++;
	BasicBlock BB1 = &FI++;
	BasicBlock BB2 = &FI++;
	BasicBlock BB3 = &FI++;

	// Test discards of invalid self-domination updates. These use the single
	// short-hand interface but are still queued inside DDT.
	DDT.deleteEdge(BB0, BB0);
	DDT.insertEdge(BB1, BB1);

	// Delete edge bb0 -> bb3 and push the update twice to verify duplicate
	// entries are discarded.
	std::vector<DominatorTree::UpdateType> Updates;
	Updates.reserve(4);
	Updates.push_back({DominatorTree::Delete, BB0, BB3});
	Updates.push_back({DominatorTree::Delete, BB0, BB3});

	// Unnecessary Insert: no edge bb1 -> bb2 after change to bb0.
	Updates.push_back({DominatorTree::Insert, BB1, BB2});
	// Unnecessary Delete: edge exists bb0 -> bb1 after change to bb0.
	Updates.push_back({DominatorTree::Delete, BB0, BB1});

	// CFG Change: remove edge bb0 -> bb3 and one duplicate edge bb0 -> bb2.
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 4u);
	BB0->getTerminator()->eraseFromParent();
	BranchInst::Create(BB1, BB2, ConstantInt::getTrue(F->getContext()), BB0);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

	// Deletion of a BasicBlock is an immediate event. We remove all uses to the
	// contained Instructions and change the Terminator to "unreachable" when
	// queued for deletion. Its parent is still F until DDT.flush() is called. We
	// don't defer this action because it can cause problems for other transforms
	// or analysis as it's part of the actual CFG. We only defer updates to the
	// DominatorTree. This code will crash if it is placed before the
	// BranchInst::Create() call above.
	ASSERT_FALSE(isa<UnreachableInst>(BB3->getTerminator()));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB3));
	DDT.deleteBB(BB3);
	EXPECT_TRUE(DDT.pendingDeletedBB(BB3));
	ASSERT_TRUE(isa<UnreachableInst>(BB3->getTerminator()));
	EXPECT_EQ(BB3->getParent(), F);

	// Verify. Updates to DDT must be applied after all changes to the CFG
	// (including block deletion).
	DDT.applyUpdates(Updates);
	ASSERT_TRUE(DDT.flush().verify());
	}

	TEST(DeferredDominance, PairedUpdate) {
	StringRef FuncName = "f";
	StringRef ModuleString =
	"define i32 @f(i32 %i, i32 *%p) {\n"
	" bb0:\n"
	" store i32 %i, i32 *%p\n"
	" switch i32 %i, label %bb1 [\n"
	" i32 0, label %bb2\n"
	" i32 1, label %bb2\n"
	" ]\n"
	" bb1:\n"
	" ret i32 1\n"
	" bb2:\n"
	" ret i32 2\n"
	"}\n";
	// Make the module.
	LLVMContext Context;
	std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
	Function *F = M->getFunction(FuncName);
	ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

	// Make the DDT.
	DominatorTree DT(*F);
	DeferredDominance DDT(DT);
	ASSERT_TRUE(DDT.flush().verify());

	Function::iterator FI = F->begin();
	BasicBlock BB0 = &FI++;
	BasicBlock BB1 = &FI++;
	BasicBlock BB2 = &FI++;

	// CFG Change: only edge from bb0 is bb0 -> bb1.
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 3u);
	BB0->getTerminator()->eraseFromParent();
	BranchInst::Create(BB1, BB0);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

	// Must be done after the CFG change. The applyUpdate() routine analyzes the
	// current state of the CFG.
	DDT.deleteEdge(BB0, BB2);

	// CFG Change: bb0 now has bb0 -> bb1 and bb0 -> bb2.
	// With this change no dominance has been altered from the original IR. DT
	// doesn't care if the type of TerminatorInstruction changed, only if the
	// unique edges have.
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);
	BB0->getTerminator()->eraseFromParent();
	BranchInst::Create(BB1, BB2, ConstantInt::getTrue(F->getContext()), BB0);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

	// Must be done after the CFG change. The applyUpdate() routine analyzes the
	// current state of the CFG. This DDT update pairs with the previous one and
	// is cancelled out before ever applying updates to DT.
	DDT.insertEdge(BB0, BB2);

	// Test the empty DeletedBB list.
	EXPECT_FALSE(DDT.pendingDeletedBB(BB0));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB1));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB2));

	// The DT has no changes, this flush() simply returns a reference to the
	// internal DT calculated at the beginning of this test.
	ASSERT_TRUE(DDT.flush().verify());
	}

	TEST(DeferredDominance, ReplaceEntryBB) {
	StringRef FuncName = "f";
	StringRef ModuleString =
	"define i32 @f() {\n"
	"bb0:\n"
	" br label %bb1\n"
	" bb1:\n"
	" ret i32 1\n"
	"}\n";
	// Make the module.
	LLVMContext Context;
	std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
	Function *F = M->getFunction(FuncName);
	ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

	// Make the DDT.
	DominatorTree DT(*F);
	DeferredDominance DDT(DT);
	ASSERT_TRUE(DDT.flush().verify());

	Function::iterator FI = F->begin();
	BasicBlock BB0 = &FI++;
	BasicBlock BB1 = &FI++;

	// Add a block as the new function entry BB. We also link it to BB0.
	BasicBlock *NewEntry =
	BasicBlock::Create(F->getContext(), "new_entry", F, BB0);
	BranchInst::Create(BB0, NewEntry);
	EXPECT_EQ(F->begin()->getName(), NewEntry->getName());
	EXPECT_TRUE(&F->getEntryBlock() == NewEntry);

	// Insert the new edge between new_eentry -> bb0. Without this the
	// recalculate() call below will not actually recalculate the DT as there
	// are no changes pending and no blocks deleted.
	DDT.insertEdge(NewEntry, BB0);

	// Changing the Entry BB requires a full recalulation.
	DDT.recalculate(*F);
	ASSERT_TRUE(DDT.flush().verify());

	// CFG Change: remove new_edge -> bb0 and redirect to new_edge -> bb1.
	EXPECT_EQ(NewEntry->getTerminator()->getNumSuccessors(), 1u);
	NewEntry->getTerminator()->eraseFromParent();
	BranchInst::Create(BB1, NewEntry);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

	// Update the DDT. At this point bb0 now has no predecessors but is still a
	// Child of F.
	DDT.applyUpdates({{DominatorTree::Delete, NewEntry, BB0},
	{DominatorTree::Insert, NewEntry, BB1}});
	ASSERT_TRUE(DDT.flush().verify());

	// Now remove bb0 from F.
	ASSERT_FALSE(isa<UnreachableInst>(BB0->getTerminator()));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB0));
	DDT.deleteBB(BB0);
	EXPECT_TRUE(DDT.pendingDeletedBB(BB0));
	ASSERT_TRUE(isa<UnreachableInst>(BB0->getTerminator()));
	EXPECT_EQ(BB0->getParent(), F);

	// Perform a full recalculation of the DDT. It is not necessary here but we
	// do this to test the case when there are no pending DT updates but there are
	// pending deleted BBs.
	DDT.recalculate(*F);
	ASSERT_TRUE(DDT.flush().verify());
	}

	TEST(DeferredDominance, InheritedPreds) {
	StringRef FuncName = "f";
	StringRef ModuleString =
	"define i32 @f(i32 %i, i32 *%p) {\n"
	" bb0:\n"
	" store i32 %i, i32 *%p\n"
	" switch i32 %i, label %bb1 [\n"
	" i32 2, label %bb2\n"
	" i32 3, label %bb3\n"
	" ]\n"
	" bb1:\n"
	" br label %bb3\n"
	" bb2:\n"
	" br label %bb3\n"
	" bb3:\n"
	" ret i32 3\n"
	"}\n";
	// Make the module.
	LLVMContext Context;
	std::unique_ptr<Module> M = makeLLVMModule(Context, ModuleString);
	Function *F = M->getFunction(FuncName);
	ASSERT_NE(F, nullptr) << "Couldn't get function " << FuncName << ".";

	// Make the DDT.
	DominatorTree DT(*F);
	DeferredDominance DDT(DT);
	ASSERT_TRUE(DDT.flush().verify());

	Function::iterator FI = F->begin();
	BasicBlock BB0 = &FI++;
	BasicBlock BB1 = &FI++;
	BasicBlock BB2 = &FI++;
	BasicBlock BB3 = &FI++;

	// There are several CFG locations where we have:
	//
	// pred1..predN
	// \| \|
	// +> curr <+ converted into: pred1..predN curr
	// \| \| \|
	// v +> succ <+
	// succ
	//
	// There is a specific shape of this we have to be careful of:
	//
	// pred1..predN
	// \|\| \|
	// \|+> curr <+ converted into: pred1..predN curr
	// \| \| \| \|
	// \| v +> succ <+
	// +-> succ
	//
	// While the final CFG form is functionally identical the updates to
	// DDT are not. In the first case we must have DDT.insertEdge(Pred1, Succ)
	// while in the latter case we must NOT have DDT.insertEdge(Pred1, Succ).

	// CFG Change: bb0 now only has bb0 -> bb1 and bb0 -> bb3. We are preparing to
	// remove bb2.
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 3u);
	BB0->getTerminator()->eraseFromParent();
	BranchInst::Create(BB1, BB3, ConstantInt::getTrue(F->getContext()), BB0);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);

	// Remove bb2 from F. This has to happen before the call to applyUpdates() for
	// DDT to detect there is no longer an edge between bb2 -> bb3. The deleteBB()
	// method converts bb2's TI into "unreachable".
	ASSERT_FALSE(isa<UnreachableInst>(BB2->getTerminator()));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB2));
	DDT.deleteBB(BB2);
	EXPECT_TRUE(DDT.pendingDeletedBB(BB2));
	ASSERT_TRUE(isa<UnreachableInst>(BB2->getTerminator()));
	EXPECT_EQ(BB2->getParent(), F);

	// Queue up the DDT updates.
	std::vector<DominatorTree::UpdateType> Updates;
	Updates.reserve(4);
	Updates.push_back({DominatorTree::Delete, BB0, BB2});
	Updates.push_back({DominatorTree::Delete, BB2, BB3});

	// Handle the specific shape case next.
	// CFG Change: bb0 now only branches to bb3. We are preparing to remove bb1.
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 2u);
	BB0->getTerminator()->eraseFromParent();
	BranchInst::Create(BB3, BB0);
	EXPECT_EQ(BB0->getTerminator()->getNumSuccessors(), 1u);

	// Remove bb1 from F. This has to happen before the call to applyUpdates() for
	// DDT to detect there is no longer an edge between bb1 -> bb3. The deleteBB()
	// method converts bb1's TI into "unreachable".
	ASSERT_FALSE(isa<UnreachableInst>(BB1->getTerminator()));
	EXPECT_FALSE(DDT.pendingDeletedBB(BB1));
	DDT.deleteBB(BB1);
	EXPECT_TRUE(DDT.pendingDeletedBB(BB1));
	ASSERT_TRUE(isa<UnreachableInst>(BB1->getTerminator()));
	EXPECT_EQ(BB1->getParent(), F);

	// Update the DDT. In this case we don't call DDT.insertEdge(BB0, BB3) because
	// the edge previously existed at the start of this test when DT was first
	// created.
	Updates.push_back({DominatorTree::Delete, BB0, BB1});
	Updates.push_back({DominatorTree::Delete, BB1, BB3});

	// Verify everything.
	DDT.applyUpdates(Updates);
	ASSERT_TRUE(DDT.flush().verify());
	}