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llvm-mirror/unittests/IR/DominatorTreeBatchUpdatesTest.cpp

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//===- llvm/unittests/IR/DominatorTreeBatchUpdatesTest.cpp ----------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include <random>
#include "CFGBuilder.h"
#include "gtest/gtest.h"
#include "llvm/Analysis/PostDominators.h"
#include "llvm/IR/Dominators.h"
#include "llvm/Support/GenericDomTreeConstruction.h"
#define DEBUG_TYPE "batch-update-tests"
using namespace llvm;
namespace {
const auto CFGInsert = CFGBuilder::ActionKind::Insert;
const auto CFGDelete = CFGBuilder::ActionKind::Delete;
using DomUpdate = DominatorTree::UpdateType;
static_assert(
std::is_same<DomUpdate, PostDominatorTree::UpdateType>::value,
"Trees differing only in IsPostDom should have the same update types");
using DomSNCA = DomTreeBuilder::SemiNCAInfo<DomTreeBuilder::BBDomTree>;
using PostDomSNCA = DomTreeBuilder::SemiNCAInfo<DomTreeBuilder::BBPostDomTree>;
const auto Insert = DominatorTree::Insert;
const auto Delete = DominatorTree::Delete;
std::vector<DomUpdate> ToDomUpdates(CFGBuilder &B,
std::vector<CFGBuilder::Update> &In) {
std::vector<DomUpdate> Res;
Res.reserve(In.size());
for (const auto &CFGU : In)
Res.push_back({CFGU.Action == CFGInsert ? Insert : Delete,
B.getOrAddBlock(CFGU.Edge.From),
B.getOrAddBlock(CFGU.Edge.To)});
return Res;
}
} // namespace
TEST(DominatorTreeBatchUpdates, LegalizeDomUpdates) {
CFGHolder Holder;
CFGBuilder Builder(Holder.F, {{"A", "B"}}, {});
BasicBlock *A = Builder.getOrAddBlock("A");
BasicBlock *B = Builder.getOrAddBlock("B");
BasicBlock *C = Builder.getOrAddBlock("C");
BasicBlock *D = Builder.getOrAddBlock("D");
std::vector<DomUpdate> Updates = {
{Insert, B, C}, {Insert, C, D}, {Delete, B, C}, {Insert, B, C},
{Insert, B, D}, {Delete, C, D}, {Delete, A, B}};
SmallVector<DomUpdate, 4> Legalized;
DomSNCA::LegalizeUpdates(Updates, Legalized);
LLVM_DEBUG(dbgs() << "Legalized updates:\t");
LLVM_DEBUG(for (auto &U : Legalized) dbgs() << U << ", ");
LLVM_DEBUG(dbgs() << "\n");
EXPECT_EQ(Legalized.size(), 3UL);
EXPECT_NE(llvm::find(Legalized, DomUpdate{Insert, B, C}), Legalized.end());
EXPECT_NE(llvm::find(Legalized, DomUpdate{Insert, B, D}), Legalized.end());
EXPECT_NE(llvm::find(Legalized, DomUpdate{Delete, A, B}), Legalized.end());
}
TEST(DominatorTreeBatchUpdates, LegalizePostDomUpdates) {
CFGHolder Holder;
CFGBuilder Builder(Holder.F, {{"A", "B"}}, {});
BasicBlock *A = Builder.getOrAddBlock("A");
BasicBlock *B = Builder.getOrAddBlock("B");
BasicBlock *C = Builder.getOrAddBlock("C");
BasicBlock *D = Builder.getOrAddBlock("D");
std::vector<DomUpdate> Updates = {
{Insert, B, C}, {Insert, C, D}, {Delete, B, C}, {Insert, B, C},
{Insert, B, D}, {Delete, C, D}, {Delete, A, B}};
SmallVector<DomUpdate, 4> Legalized;
PostDomSNCA::LegalizeUpdates(Updates, Legalized);
LLVM_DEBUG(dbgs() << "Legalized postdom updates:\t");
LLVM_DEBUG(for (auto &U : Legalized) dbgs() << U << ", ");
LLVM_DEBUG(dbgs() << "\n");
EXPECT_EQ(Legalized.size(), 3UL);
EXPECT_NE(llvm::find(Legalized, DomUpdate{Insert, C, B}), Legalized.end());
EXPECT_NE(llvm::find(Legalized, DomUpdate{Insert, D, B}), Legalized.end());
EXPECT_NE(llvm::find(Legalized, DomUpdate{Delete, B, A}), Legalized.end());
}
TEST(DominatorTreeBatchUpdates, SingleInsertion) {
CFGHolder Holder;
CFGBuilder Builder(Holder.F, {{"A", "B"}}, {{CFGInsert, {"B", "C"}}});
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
BasicBlock *B = Builder.getOrAddBlock("B");
BasicBlock *C = Builder.getOrAddBlock("C");
std::vector<DomUpdate> Updates = {{Insert, B, C}};
ASSERT_TRUE(Builder.applyUpdate());
DT.applyUpdates(Updates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(Updates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, SingleDeletion) {
CFGHolder Holder;
CFGBuilder Builder(Holder.F, {{"A", "B"}, {"B", "C"}},
{{CFGDelete, {"B", "C"}}});
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
BasicBlock *B = Builder.getOrAddBlock("B");
BasicBlock *C = Builder.getOrAddBlock("C");
std::vector<DomUpdate> Updates = {{Delete, B, C}};
ASSERT_TRUE(Builder.applyUpdate());
DT.applyUpdates(Updates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(Updates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, FewInsertion) {
std::vector<CFGBuilder::Update> CFGUpdates = {{CFGInsert, {"B", "C"}},
{CFGInsert, {"C", "B"}},
{CFGInsert, {"C", "D"}},
{CFGInsert, {"D", "E"}}};
CFGHolder Holder;
CFGBuilder Builder(Holder.F, {{"A", "B"}}, CFGUpdates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
BasicBlock *B = Builder.getOrAddBlock("B");
BasicBlock *C = Builder.getOrAddBlock("C");
BasicBlock *D = Builder.getOrAddBlock("D");
BasicBlock *E = Builder.getOrAddBlock("E");
std::vector<DomUpdate> Updates = {
{Insert, B, C}, {Insert, C, B}, {Insert, C, D}, {Insert, D, E}};
while (Builder.applyUpdate())
;
DT.applyUpdates(Updates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(Updates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, FewDeletions) {
std::vector<CFGBuilder::Update> CFGUpdates = {{CFGDelete, {"B", "C"}},
{CFGDelete, {"C", "B"}},
{CFGDelete, {"B", "D"}},
{CFGDelete, {"D", "E"}}};
CFGHolder Holder;
CFGBuilder Builder(
Holder.F, {{"A", "B"}, {"B", "C"}, {"B", "D"}, {"D", "E"}, {"C", "B"}},
CFGUpdates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
auto Updates = ToDomUpdates(Builder, CFGUpdates);
while (Builder.applyUpdate())
;
DT.applyUpdates(Updates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(Updates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, InsertDelete) {
std::vector<CFGBuilder::Arc> Arcs = {
{"1", "2"}, {"2", "3"}, {"3", "4"}, {"4", "5"}, {"5", "6"}, {"5", "7"},
{"3", "8"}, {"8", "9"}, {"9", "10"}, {"8", "11"}, {"11", "12"}};
std::vector<CFGBuilder::Update> Updates = {
{CFGInsert, {"2", "4"}}, {CFGInsert, {"12", "10"}},
{CFGInsert, {"10", "9"}}, {CFGInsert, {"7", "6"}},
{CFGInsert, {"7", "5"}}, {CFGDelete, {"3", "8"}},
{CFGInsert, {"10", "7"}}, {CFGInsert, {"2", "8"}},
{CFGDelete, {"3", "4"}}, {CFGDelete, {"8", "9"}},
{CFGDelete, {"11", "12"}}};
CFGHolder Holder;
CFGBuilder B(Holder.F, Arcs, Updates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
while (B.applyUpdate())
;
auto DomUpdates = ToDomUpdates(B, Updates);
DT.applyUpdates(DomUpdates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(DomUpdates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, InsertDeleteExhaustive) {
std::vector<CFGBuilder::Arc> Arcs = {
{"1", "2"}, {"2", "3"}, {"3", "4"}, {"4", "5"}, {"5", "6"}, {"5", "7"},
{"3", "8"}, {"8", "9"}, {"9", "10"}, {"8", "11"}, {"11", "12"}};
std::vector<CFGBuilder::Update> Updates = {
{CFGInsert, {"2", "4"}}, {CFGInsert, {"12", "10"}},
{CFGInsert, {"10", "9"}}, {CFGInsert, {"7", "6"}},
{CFGInsert, {"7", "5"}}, {CFGDelete, {"3", "8"}},
{CFGInsert, {"10", "7"}}, {CFGInsert, {"2", "8"}},
{CFGDelete, {"3", "4"}}, {CFGDelete, {"8", "9"}},
{CFGDelete, {"11", "12"}}};
std::mt19937 Generator(0);
for (unsigned i = 0; i < 16; ++i) {
std::shuffle(Updates.begin(), Updates.end(), Generator);
CFGHolder Holder;
CFGBuilder B(Holder.F, Arcs, Updates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
while (B.applyUpdate())
;
auto DomUpdates = ToDomUpdates(B, Updates);
DT.applyUpdates(DomUpdates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(DomUpdates);
EXPECT_TRUE(PDT.verify());
}
}
// These are some odd flowgraphs, usually generated from csmith cases,
// which are difficult on post dom trees.
TEST(DominatorTreeBatchUpdates, InfiniteLoop) {
std::vector<CFGBuilder::Arc> Arcs = {
{"1", "2"},
{"2", "3"},
{"3", "6"}, {"3", "5"},
{"4", "5"},
{"5", "2"},
{"6", "3"}, {"6", "4"}};
// SplitBlock on 3 -> 5
std::vector<CFGBuilder::Update> Updates = {
{CFGInsert, {"N", "5"}}, {CFGInsert, {"3", "N"}}, {CFGDelete, {"3", "5"}}};
CFGHolder Holder;
CFGBuilder B(Holder.F, Arcs, Updates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
while (B.applyUpdate())
;
auto DomUpdates = ToDomUpdates(B, Updates);
DT.applyUpdates(DomUpdates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(DomUpdates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, DeadBlocks) {
std::vector<CFGBuilder::Arc> Arcs = {
{"1", "2"},
{"2", "3"},
{"3", "4"}, {"3", "7"},
{"4", "4"},
{"5", "6"}, {"5", "7"},
{"6", "7"},
{"7", "2"}, {"7", "8"}};
// Remove dead 5 and 7,
// plus SplitBlock on 7 -> 8
std::vector<CFGBuilder::Update> Updates = {
{CFGDelete, {"6", "7"}}, {CFGDelete, {"5", "7"}}, {CFGDelete, {"5", "6"}},
{CFGInsert, {"N", "8"}}, {CFGInsert, {"7", "N"}}, {CFGDelete, {"7", "8"}}};
CFGHolder Holder;
CFGBuilder B(Holder.F, Arcs, Updates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
while (B.applyUpdate())
;
auto DomUpdates = ToDomUpdates(B, Updates);
DT.applyUpdates(DomUpdates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(DomUpdates);
EXPECT_TRUE(PDT.verify());
}
TEST(DominatorTreeBatchUpdates, InfiniteLoop2) {
std::vector<CFGBuilder::Arc> Arcs = {
{"1", "2"},
{"2", "6"}, {"2", "3"},
{"3", "4"},
{"4", "5"}, {"4", "6"},
{"5", "4"},
{"6", "2"}};
// SplitBlock on 4 -> 6
std::vector<CFGBuilder::Update> Updates = {
{CFGInsert, {"N", "6"}}, {CFGInsert, {"4", "N"}}, {CFGDelete, {"4", "6"}}};
CFGHolder Holder;
CFGBuilder B(Holder.F, Arcs, Updates);
DominatorTree DT(*Holder.F);
EXPECT_TRUE(DT.verify());
PostDominatorTree PDT(*Holder.F);
EXPECT_TRUE(PDT.verify());
while (B.applyUpdate())
;
auto DomUpdates = ToDomUpdates(B, Updates);
DT.applyUpdates(DomUpdates);
EXPECT_TRUE(DT.verify());
PDT.applyUpdates(DomUpdates);
EXPECT_TRUE(PDT.verify());
}