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70b8986c96
The traits object is only used by a few methods. Deserializing a hash table and walking it is possible without the traits object, so it shouldn't be required to build a dummy object for that use case. The TraitsT object used to be a function template parameter before r327647, this restores it to that state. This makes it clear that the traits object isn't needed at all in 1 of the current 3 uses of HashTable (and I am going to add another use that doesn't need it), and that the default PdbHashTraits isn't used outside of tests. While here, also re-enable 3 checks in the test that were commented out (which requires making HashTableInternals templated and giving FooBar an operator==). No intended behavior change. Differential Revision: https://reviews.llvm.org/D64640 llvm-svn: 365974
271 lines
8.1 KiB
C++
271 lines
8.1 KiB
C++
//===- llvm/unittest/DebugInfo/PDB/HashTableTest.cpp ----------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/DebugInfo/PDB/Native/HashTable.h"
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#include "llvm/DebugInfo/PDB/Native/Hash.h"
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#include "llvm/DebugInfo/PDB/Native/NamedStreamMap.h"
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#include "llvm/Support/Allocator.h"
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#include "llvm/Support/BinaryByteStream.h"
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#include "llvm/Support/BinaryStreamReader.h"
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#include "llvm/Support/BinaryStreamWriter.h"
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#include "llvm/Support/StringSaver.h"
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#include "llvm/Testing/Support/Error.h"
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#include "gtest/gtest.h"
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#include <vector>
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using namespace llvm;
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using namespace llvm::pdb;
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using namespace llvm::support;
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namespace {
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struct IdentityHashTraits {
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uint32_t hashLookupKey(uint32_t N) const { return N; }
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uint32_t storageKeyToLookupKey(uint32_t N) const { return N; }
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uint32_t lookupKeyToStorageKey(uint32_t N) { return N; }
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};
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template <class T = uint32_t>
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class HashTableInternals : public HashTable<T> {
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public:
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using HashTable<T>::Buckets;
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using HashTable<T>::Present;
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using HashTable<T>::Deleted;
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};
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}
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TEST(HashTableTest, TestSimple) {
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HashTableInternals<> Table;
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EXPECT_EQ(0u, Table.size());
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EXPECT_GT(Table.capacity(), 0u);
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IdentityHashTraits Traits;
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Table.set_as(3u, 7, Traits);
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EXPECT_EQ(1u, Table.size());
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ASSERT_NE(Table.end(), Table.find_as(3u, Traits));
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EXPECT_EQ(7u, Table.get(3u, Traits));
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}
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TEST(HashTableTest, TestCollision) {
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HashTableInternals<> Table;
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EXPECT_EQ(0u, Table.size());
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EXPECT_GT(Table.capacity(), 0u);
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// We use knowledge of the hash table's implementation details to make sure
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// to add another value that is the equivalent to the first value modulo the
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// hash table's capacity.
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uint32_t N1 = Table.capacity() + 1;
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uint32_t N2 = 2 * N1;
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IdentityHashTraits Traits;
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Table.set_as(N1, 7, Traits);
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Table.set_as(N2, 12, Traits);
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EXPECT_EQ(2u, Table.size());
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ASSERT_NE(Table.end(), Table.find_as(N1, Traits));
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ASSERT_NE(Table.end(), Table.find_as(N2, Traits));
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EXPECT_EQ(7u, Table.get(N1, Traits));
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EXPECT_EQ(12u, Table.get(N2, Traits));
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}
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TEST(HashTableTest, TestRemove) {
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HashTableInternals<> Table;
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EXPECT_EQ(0u, Table.size());
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EXPECT_GT(Table.capacity(), 0u);
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IdentityHashTraits Traits;
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Table.set_as(1u, 2, Traits);
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Table.set_as(3u, 4, Traits);
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EXPECT_EQ(2u, Table.size());
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ASSERT_NE(Table.end(), Table.find_as(1u, Traits));
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ASSERT_NE(Table.end(), Table.find_as(3u, Traits));
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EXPECT_EQ(2u, Table.get(1u, Traits));
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EXPECT_EQ(4u, Table.get(3u, Traits));
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}
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TEST(HashTableTest, TestCollisionAfterMultipleProbes) {
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HashTableInternals<> Table;
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EXPECT_EQ(0u, Table.size());
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EXPECT_GT(Table.capacity(), 0u);
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// Probing looks for the first available slot. A slot may already be filled
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// as a result of an item with a *different* hash value already being there.
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// Test that when this happens, the probe still finds the value.
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uint32_t N1 = Table.capacity() + 1;
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uint32_t N2 = N1 + 1;
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uint32_t N3 = 2 * N1;
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IdentityHashTraits Traits;
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Table.set_as(N1, 7, Traits);
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Table.set_as(N2, 11, Traits);
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Table.set_as(N3, 13, Traits);
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EXPECT_EQ(3u, Table.size());
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ASSERT_NE(Table.end(), Table.find_as(N1, Traits));
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ASSERT_NE(Table.end(), Table.find_as(N2, Traits));
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ASSERT_NE(Table.end(), Table.find_as(N3, Traits));
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EXPECT_EQ(7u, Table.get(N1, Traits));
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EXPECT_EQ(11u, Table.get(N2, Traits));
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EXPECT_EQ(13u, Table.get(N3, Traits));
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}
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TEST(HashTableTest, Grow) {
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// So that we are independent of the load factor, `capacity` items, which is
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// guaranteed to trigger a grow. Then verify that the size is the same, the
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// capacity is larger, and all the original items are still in the table.
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HashTableInternals<> Table;
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IdentityHashTraits Traits;
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uint32_t OldCapacity = Table.capacity();
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for (uint32_t I = 0; I < OldCapacity; ++I) {
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Table.set_as(OldCapacity + I * 2 + 1, I * 2 + 3, Traits);
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}
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EXPECT_EQ(OldCapacity, Table.size());
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EXPECT_GT(Table.capacity(), OldCapacity);
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for (uint32_t I = 0; I < OldCapacity; ++I) {
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ASSERT_NE(Table.end(), Table.find_as(OldCapacity + I * 2 + 1, Traits));
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EXPECT_EQ(I * 2 + 3, Table.get(OldCapacity + I * 2 + 1, Traits));
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}
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}
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TEST(HashTableTest, Serialization) {
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HashTableInternals<> Table;
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IdentityHashTraits Traits;
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uint32_t Cap = Table.capacity();
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for (uint32_t I = 0; I < Cap; ++I) {
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Table.set_as(Cap + I * 2 + 1, I * 2 + 3, Traits);
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}
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std::vector<uint8_t> Buffer(Table.calculateSerializedLength());
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MutableBinaryByteStream Stream(Buffer, little);
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BinaryStreamWriter Writer(Stream);
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EXPECT_THAT_ERROR(Table.commit(Writer), Succeeded());
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// We should have written precisely the number of bytes we calculated earlier.
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EXPECT_EQ(Buffer.size(), Writer.getOffset());
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HashTableInternals<> Table2;
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BinaryStreamReader Reader(Stream);
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EXPECT_THAT_ERROR(Table2.load(Reader), Succeeded());
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// We should have read precisely the number of bytes we calculated earlier.
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EXPECT_EQ(Buffer.size(), Reader.getOffset());
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EXPECT_EQ(Table.size(), Table2.size());
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EXPECT_EQ(Table.capacity(), Table2.capacity());
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EXPECT_EQ(Table.Buckets, Table2.Buckets);
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EXPECT_EQ(Table.Present, Table2.Present);
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EXPECT_EQ(Table.Deleted, Table2.Deleted);
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}
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TEST(HashTableTest, NamedStreamMap) {
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std::vector<StringRef> Streams = {"One", "Two", "Three", "Four",
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"Five", "Six", "Seven"};
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StringMap<uint32_t> ExpectedIndices;
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for (uint32_t I = 0; I < Streams.size(); ++I)
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ExpectedIndices[Streams[I]] = I + 1;
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// To verify the hash table actually works, we want to verify that insertion
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// order doesn't matter. So try inserting in every possible order of 7 items.
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do {
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NamedStreamMap NSM;
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for (StringRef S : Streams)
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NSM.set(S, ExpectedIndices[S]);
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EXPECT_EQ(Streams.size(), NSM.size());
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uint32_t N;
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EXPECT_TRUE(NSM.get("One", N));
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EXPECT_EQ(1U, N);
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EXPECT_TRUE(NSM.get("Two", N));
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EXPECT_EQ(2U, N);
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EXPECT_TRUE(NSM.get("Three", N));
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EXPECT_EQ(3U, N);
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EXPECT_TRUE(NSM.get("Four", N));
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EXPECT_EQ(4U, N);
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EXPECT_TRUE(NSM.get("Five", N));
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EXPECT_EQ(5U, N);
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EXPECT_TRUE(NSM.get("Six", N));
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EXPECT_EQ(6U, N);
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EXPECT_TRUE(NSM.get("Seven", N));
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EXPECT_EQ(7U, N);
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} while (std::next_permutation(Streams.begin(), Streams.end()));
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}
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struct FooBar {
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uint32_t X;
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uint32_t Y;
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bool operator==(const FooBar &RHS) const {
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return X == RHS.X && Y == RHS.Y;
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}
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};
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struct FooBarHashTraits {
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std::vector<char> Buffer;
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FooBarHashTraits() { Buffer.push_back(0); }
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uint32_t hashLookupKey(StringRef S) const {
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return llvm::pdb::hashStringV1(S);
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}
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StringRef storageKeyToLookupKey(uint32_t N) const {
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if (N >= Buffer.size())
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return StringRef();
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return StringRef(Buffer.data() + N);
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}
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uint32_t lookupKeyToStorageKey(StringRef S) {
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uint32_t N = Buffer.size();
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Buffer.insert(Buffer.end(), S.begin(), S.end());
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Buffer.push_back('\0');
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return N;
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}
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};
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TEST(HashTableTest, NonTrivialValueType) {
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HashTableInternals<FooBar> Table;
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FooBarHashTraits Traits;
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uint32_t Cap = Table.capacity();
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for (uint32_t I = 0; I < Cap; ++I) {
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FooBar F;
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F.X = I;
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F.Y = I + 1;
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Table.set_as(utostr(I), F, Traits);
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}
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std::vector<uint8_t> Buffer(Table.calculateSerializedLength());
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MutableBinaryByteStream Stream(Buffer, little);
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BinaryStreamWriter Writer(Stream);
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EXPECT_THAT_ERROR(Table.commit(Writer), Succeeded());
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// We should have written precisely the number of bytes we calculated earlier.
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EXPECT_EQ(Buffer.size(), Writer.getOffset());
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HashTableInternals<FooBar> Table2;
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BinaryStreamReader Reader(Stream);
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EXPECT_THAT_ERROR(Table2.load(Reader), Succeeded());
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// We should have read precisely the number of bytes we calculated earlier.
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EXPECT_EQ(Buffer.size(), Reader.getOffset());
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EXPECT_EQ(Table.size(), Table2.size());
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EXPECT_EQ(Table.capacity(), Table2.capacity());
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EXPECT_EQ(Table.Buckets, Table2.Buckets);
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EXPECT_EQ(Table.Present, Table2.Present);
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EXPECT_EQ(Table.Deleted, Table2.Deleted);
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}
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