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56264ae675
This nicely handles the most common case of virtual register sets, but also handles anticipated cases where we will map pointers to IDs. The goal is not to develop a completely generic SparseSet template. Instead we want to handle the expected uses within llvm without any template antics in the client code. I'm adding a bit of template nastiness here, and some assumption about expected usage in order to make the client code very clean. The expected common uses cases I'm designing for: - integer keys that need to be reindexed, and may map to additional data - densely numbered objects where we want pointer keys because no number->object map exists. llvm-svn: 155227
187 lines
4.3 KiB
C++
187 lines
4.3 KiB
C++
//===------ ADT/SparseSetTest.cpp - SparseSet unit tests - -----*- C++ -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/ADT/SparseSet.h"
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#include "gtest/gtest.h"
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using namespace llvm;
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namespace {
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typedef SparseSet<unsigned> USet;
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// Empty set tests.
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TEST(SparseSetTest, EmptySet) {
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USet Set;
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EXPECT_TRUE(Set.empty());
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EXPECT_TRUE(Set.begin() == Set.end());
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EXPECT_EQ(0u, Set.size());
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Set.setUniverse(10);
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// Lookups on empty set.
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EXPECT_TRUE(Set.find(0) == Set.end());
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EXPECT_TRUE(Set.find(9) == Set.end());
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// Same thing on a const reference.
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const USet &CSet = Set;
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EXPECT_TRUE(CSet.empty());
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EXPECT_TRUE(CSet.begin() == CSet.end());
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EXPECT_EQ(0u, CSet.size());
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EXPECT_TRUE(CSet.find(0) == CSet.end());
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USet::const_iterator I = CSet.find(5);
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EXPECT_TRUE(I == CSet.end());
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}
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// Single entry set tests.
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TEST(SparseSetTest, SingleEntrySet) {
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USet Set;
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Set.setUniverse(10);
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std::pair<USet::iterator, bool> IP = Set.insert(5);
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EXPECT_TRUE(IP.second);
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EXPECT_TRUE(IP.first == Set.begin());
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EXPECT_FALSE(Set.empty());
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EXPECT_FALSE(Set.begin() == Set.end());
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EXPECT_TRUE(Set.begin() + 1 == Set.end());
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EXPECT_EQ(1u, Set.size());
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EXPECT_TRUE(Set.find(0) == Set.end());
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EXPECT_TRUE(Set.find(9) == Set.end());
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EXPECT_FALSE(Set.count(0));
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EXPECT_TRUE(Set.count(5));
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// Redundant insert.
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IP = Set.insert(5);
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EXPECT_FALSE(IP.second);
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EXPECT_TRUE(IP.first == Set.begin());
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// Erase non-existent element.
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EXPECT_FALSE(Set.erase(1));
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EXPECT_EQ(1u, Set.size());
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EXPECT_EQ(5u, *Set.begin());
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// Erase iterator.
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USet::iterator I = Set.find(5);
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EXPECT_TRUE(I == Set.begin());
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I = Set.erase(I);
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EXPECT_TRUE(I == Set.end());
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EXPECT_TRUE(Set.empty());
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}
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// Multiple entry set tests.
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TEST(SparseSetTest, MultipleEntrySet) {
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USet Set;
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Set.setUniverse(10);
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Set.insert(5);
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Set.insert(3);
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Set.insert(2);
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Set.insert(1);
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Set.insert(4);
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EXPECT_EQ(5u, Set.size());
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// Without deletions, iteration order == insertion order.
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USet::const_iterator I = Set.begin();
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EXPECT_EQ(5u, *I);
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++I;
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EXPECT_EQ(3u, *I);
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++I;
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EXPECT_EQ(2u, *I);
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++I;
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EXPECT_EQ(1u, *I);
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++I;
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EXPECT_EQ(4u, *I);
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++I;
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EXPECT_TRUE(I == Set.end());
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// Redundant insert.
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std::pair<USet::iterator, bool> IP = Set.insert(3);
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EXPECT_FALSE(IP.second);
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EXPECT_TRUE(IP.first == Set.begin() + 1);
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// Erase last element by key.
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EXPECT_TRUE(Set.erase(4));
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EXPECT_EQ(4u, Set.size());
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EXPECT_FALSE(Set.count(4));
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EXPECT_FALSE(Set.erase(4));
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EXPECT_EQ(4u, Set.size());
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EXPECT_FALSE(Set.count(4));
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// Erase first element by key.
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EXPECT_TRUE(Set.count(5));
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EXPECT_TRUE(Set.find(5) == Set.begin());
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EXPECT_TRUE(Set.erase(5));
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EXPECT_EQ(3u, Set.size());
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EXPECT_FALSE(Set.count(5));
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EXPECT_FALSE(Set.erase(5));
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EXPECT_EQ(3u, Set.size());
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EXPECT_FALSE(Set.count(5));
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Set.insert(6);
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Set.insert(7);
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EXPECT_EQ(5u, Set.size());
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// Erase last element by iterator.
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I = Set.erase(Set.end() - 1);
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EXPECT_TRUE(I == Set.end());
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EXPECT_EQ(4u, Set.size());
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// Erase second element by iterator.
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I = Set.erase(Set.begin() + 1);
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EXPECT_TRUE(I == Set.begin() + 1);
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// Clear and resize the universe.
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Set.clear();
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EXPECT_FALSE(Set.count(5));
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Set.setUniverse(1000);
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// Add more than 256 elements.
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for (unsigned i = 100; i != 800; ++i)
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Set.insert(i);
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for (unsigned i = 0; i != 10; ++i)
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Set.erase(i);
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for (unsigned i = 100; i != 800; ++i)
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EXPECT_TRUE(Set.count(i));
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EXPECT_FALSE(Set.count(99));
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EXPECT_FALSE(Set.count(800));
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EXPECT_EQ(700u, Set.size());
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}
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struct Alt {
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unsigned Value;
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explicit Alt(unsigned x) : Value(x) {}
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unsigned getSparseSetIndex() const { return Value - 1000; }
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};
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TEST(SparseSetTest, AltStructSet) {
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typedef SparseSet<Alt> ASet;
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ASet Set;
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Set.setUniverse(10);
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Set.insert(Alt(1005));
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ASet::iterator I = Set.find(5);
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ASSERT_TRUE(I == Set.begin());
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EXPECT_EQ(1005u, I->Value);
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Set.insert(Alt(1006));
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Set.insert(Alt(1006));
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I = Set.erase(Set.begin());
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ASSERT_TRUE(I == Set.begin());
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EXPECT_EQ(1006u, I->Value);
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EXPECT_FALSE(Set.erase(5));
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EXPECT_TRUE(Set.erase(6));
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}
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} // namespace
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