forked from OSchip/llvm-project
796 lines
27 KiB
C++
796 lines
27 KiB
C++
//===-- DexTests.cpp ---------------------------------*- C++ -*-----------===//
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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 "FuzzyMatch.h"
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#include "TestFS.h"
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#include "TestIndex.h"
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#include "index/Index.h"
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#include "index/Merge.h"
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#include "index/SymbolID.h"
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#include "index/dex/Dex.h"
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#include "index/dex/Iterator.h"
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#include "index/dex/Token.h"
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#include "index/dex/Trigram.h"
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#include "llvm/Support/ScopedPrinter.h"
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#include "llvm/Support/raw_ostream.h"
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#include "gmock/gmock.h"
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#include "gtest/gtest.h"
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#include <string>
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#include <vector>
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using ::testing::AnyOf;
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using ::testing::ElementsAre;
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using ::testing::IsEmpty;
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using ::testing::UnorderedElementsAre;
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namespace clang {
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namespace clangd {
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namespace dex {
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namespace {
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//===----------------------------------------------------------------------===//
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// Query iterator tests.
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//===----------------------------------------------------------------------===//
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std::vector<DocID> consumeIDs(Iterator &It) {
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auto IDAndScore = consume(It);
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std::vector<DocID> IDs(IDAndScore.size());
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for (size_t I = 0; I < IDAndScore.size(); ++I)
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IDs[I] = IDAndScore[I].first;
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return IDs;
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}
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TEST(DexIterators, DocumentIterator) {
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const PostingList L({4, 7, 8, 20, 42, 100});
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auto DocIterator = L.iterator();
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EXPECT_EQ(DocIterator->peek(), 4U);
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EXPECT_FALSE(DocIterator->reachedEnd());
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DocIterator->advance();
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EXPECT_EQ(DocIterator->peek(), 7U);
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EXPECT_FALSE(DocIterator->reachedEnd());
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DocIterator->advanceTo(20);
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EXPECT_EQ(DocIterator->peek(), 20U);
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EXPECT_FALSE(DocIterator->reachedEnd());
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DocIterator->advanceTo(65);
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EXPECT_EQ(DocIterator->peek(), 100U);
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EXPECT_FALSE(DocIterator->reachedEnd());
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DocIterator->advanceTo(420);
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EXPECT_TRUE(DocIterator->reachedEnd());
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}
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TEST(DexIterators, AndTwoLists) {
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Corpus C{10000};
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const PostingList L0({0, 5, 7, 10, 42, 320, 9000});
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const PostingList L1({0, 4, 7, 10, 30, 60, 320, 9000});
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auto And = C.intersect(L1.iterator(), L0.iterator());
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EXPECT_FALSE(And->reachedEnd());
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EXPECT_THAT(consumeIDs(*And), ElementsAre(0U, 7U, 10U, 320U, 9000U));
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And = C.intersect(L0.iterator(), L1.iterator());
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And->advanceTo(0);
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EXPECT_EQ(And->peek(), 0U);
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And->advanceTo(5);
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EXPECT_EQ(And->peek(), 7U);
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And->advanceTo(10);
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EXPECT_EQ(And->peek(), 10U);
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And->advanceTo(42);
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EXPECT_EQ(And->peek(), 320U);
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And->advanceTo(8999);
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EXPECT_EQ(And->peek(), 9000U);
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And->advanceTo(9001);
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}
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TEST(DexIterators, AndThreeLists) {
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Corpus C{10000};
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const PostingList L0({0, 5, 7, 10, 42, 320, 9000});
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const PostingList L1({0, 4, 7, 10, 30, 60, 320, 9000});
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const PostingList L2({1, 4, 7, 11, 30, 60, 320, 9000});
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auto And = C.intersect(L0.iterator(), L1.iterator(), L2.iterator());
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EXPECT_EQ(And->peek(), 7U);
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And->advanceTo(300);
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EXPECT_EQ(And->peek(), 320U);
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And->advanceTo(100000);
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EXPECT_TRUE(And->reachedEnd());
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}
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TEST(DexIterators, AndEmpty) {
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Corpus C{10000};
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const PostingList L1{1};
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const PostingList L2{2};
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// These iterators are empty, but the optimizer can't tell.
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auto Empty1 = C.intersect(L1.iterator(), L2.iterator());
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auto Empty2 = C.intersect(L1.iterator(), L2.iterator());
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// And syncs iterators on construction, and used to fail on empty children.
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auto And = C.intersect(std::move(Empty1), std::move(Empty2));
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EXPECT_TRUE(And->reachedEnd());
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}
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TEST(DexIterators, OrTwoLists) {
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Corpus C{10000};
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const PostingList L0({0, 5, 7, 10, 42, 320, 9000});
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const PostingList L1({0, 4, 7, 10, 30, 60, 320, 9000});
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auto Or = C.unionOf(L0.iterator(), L1.iterator());
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EXPECT_FALSE(Or->reachedEnd());
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EXPECT_EQ(Or->peek(), 0U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 4U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 5U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 7U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 10U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 30U);
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Or->advanceTo(42);
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EXPECT_EQ(Or->peek(), 42U);
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Or->advanceTo(300);
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EXPECT_EQ(Or->peek(), 320U);
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Or->advanceTo(9000);
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EXPECT_EQ(Or->peek(), 9000U);
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Or->advanceTo(9001);
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EXPECT_TRUE(Or->reachedEnd());
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Or = C.unionOf(L0.iterator(), L1.iterator());
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EXPECT_THAT(consumeIDs(*Or),
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ElementsAre(0U, 4U, 5U, 7U, 10U, 30U, 42U, 60U, 320U, 9000U));
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}
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TEST(DexIterators, OrThreeLists) {
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Corpus C{10000};
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const PostingList L0({0, 5, 7, 10, 42, 320, 9000});
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const PostingList L1({0, 4, 7, 10, 30, 60, 320, 9000});
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const PostingList L2({1, 4, 7, 11, 30, 60, 320, 9000});
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auto Or = C.unionOf(L0.iterator(), L1.iterator(), L2.iterator());
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EXPECT_FALSE(Or->reachedEnd());
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EXPECT_EQ(Or->peek(), 0U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 1U);
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Or->advance();
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EXPECT_EQ(Or->peek(), 4U);
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Or->advanceTo(7);
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Or->advanceTo(59);
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EXPECT_EQ(Or->peek(), 60U);
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Or->advanceTo(9001);
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EXPECT_TRUE(Or->reachedEnd());
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}
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// FIXME(kbobyrev): The testcase below is similar to what is expected in real
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// queries. It should be updated once new iterators (such as boosting, limiting,
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// etc iterators) appear. However, it is not exhaustive and it would be
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// beneficial to implement automatic generation (e.g. fuzzing) of query trees
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// for more comprehensive testing.
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TEST(DexIterators, QueryTree) {
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//
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// +-----------------+
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// |And Iterator:1, 5|
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// +--------+--------+
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// |
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// |
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// +-------------+----------------------+
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// | |
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// | |
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// +----------v----------+ +----------v------------+
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// |And Iterator: 1, 5, 9| |Or Iterator: 0, 1, 3, 5|
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// +----------+----------+ +----------+------------+
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// | |
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// +------+-----+ ------------+
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// | | | |
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// +-------v-----+ +----+---+ +---v----+ +----v---+
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// |1, 3, 5, 8, 9| |Boost: 2| |Boost: 3| |Boost: 4|
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// +-------------+ +----+---+ +---+----+ +----+---+
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// | | |
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// +----v-----+ +-v--+ +---v---+
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// |1, 5, 7, 9| |1, 5| |0, 3, 5|
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// +----------+ +----+ +-------+
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//
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Corpus C{10};
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const PostingList L0({1, 3, 5, 8, 9});
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const PostingList L1({1, 5, 7, 9});
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const PostingList L2({1, 5});
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const PostingList L3({0, 3, 5});
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// Root of the query tree: [1, 5]
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auto Root = C.intersect(
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// Lower And Iterator: [1, 5, 9]
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C.intersect(L0.iterator(), C.boost(L1.iterator(), 2U)),
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// Lower Or Iterator: [0, 1, 5]
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C.unionOf(C.boost(L2.iterator(), 3U), C.boost(L3.iterator(), 4U)));
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EXPECT_FALSE(Root->reachedEnd());
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EXPECT_EQ(Root->peek(), 1U);
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Root->advanceTo(0);
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// Advance multiple times. Shouldn't do anything.
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Root->advanceTo(1);
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Root->advanceTo(0);
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EXPECT_EQ(Root->peek(), 1U);
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auto ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 6);
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Root->advance();
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EXPECT_EQ(Root->peek(), 5U);
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Root->advanceTo(5);
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EXPECT_EQ(Root->peek(), 5U);
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ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 8);
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Root->advanceTo(9000);
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EXPECT_TRUE(Root->reachedEnd());
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}
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TEST(DexIterators, StringRepresentation) {
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Corpus C{10};
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const PostingList L1({1, 3, 5});
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const PostingList L2({1, 7, 9});
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// No token given, prints full posting list.
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auto I1 = L1.iterator();
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EXPECT_EQ(llvm::to_string(*I1), "[1 3 5]");
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// Token given, uses token's string representation.
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Token Tok(Token::Kind::Trigram, "L2");
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auto I2 = L1.iterator(&Tok);
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EXPECT_EQ(llvm::to_string(*I2), "T=L2");
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auto Tree = C.limit(C.intersect(move(I1), move(I2)), 10);
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// AND reorders its children, we don't care which order it prints.
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EXPECT_THAT(llvm::to_string(*Tree), AnyOf("(LIMIT 10 (& [1 3 5] T=L2))",
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"(LIMIT 10 (& T=L2 [1 3 5]))"));
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}
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TEST(DexIterators, Limit) {
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Corpus C{10000};
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const PostingList L0({3, 6, 7, 20, 42, 100});
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const PostingList L1({1, 3, 5, 6, 7, 30, 100});
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const PostingList L2({0, 3, 5, 7, 8, 100});
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auto DocIterator = C.limit(L0.iterator(), 42);
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EXPECT_THAT(consumeIDs(*DocIterator), ElementsAre(3, 6, 7, 20, 42, 100));
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DocIterator = C.limit(L0.iterator(), 3);
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EXPECT_THAT(consumeIDs(*DocIterator), ElementsAre(3, 6, 7));
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DocIterator = C.limit(L0.iterator(), 0);
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EXPECT_THAT(consumeIDs(*DocIterator), ElementsAre());
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auto AndIterator =
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C.intersect(C.limit(C.all(), 343), C.limit(L0.iterator(), 2),
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C.limit(L1.iterator(), 3), C.limit(L2.iterator(), 42));
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EXPECT_THAT(consumeIDs(*AndIterator), ElementsAre(3, 7));
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}
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TEST(DexIterators, True) {
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EXPECT_TRUE(Corpus{0}.all()->reachedEnd());
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EXPECT_THAT(consumeIDs(*Corpus{4}.all()), ElementsAre(0, 1, 2, 3));
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}
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TEST(DexIterators, Boost) {
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Corpus C{5};
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auto BoostIterator = C.boost(C.all(), 42U);
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EXPECT_FALSE(BoostIterator->reachedEnd());
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auto ElementBoost = BoostIterator->consume();
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EXPECT_THAT(ElementBoost, 42U);
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const PostingList L0({2, 4});
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const PostingList L1({1, 4});
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auto Root = C.unionOf(C.all(), C.boost(L0.iterator(), 2U),
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C.boost(L1.iterator(), 3U));
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ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 1);
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Root->advance();
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EXPECT_THAT(Root->peek(), 1U);
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ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 3);
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Root->advance();
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EXPECT_THAT(Root->peek(), 2U);
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ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 2);
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Root->advanceTo(4);
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ElementBoost = Root->consume();
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EXPECT_THAT(ElementBoost, 3);
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}
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TEST(DexIterators, Optimizations) {
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Corpus C{5};
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const PostingList L1{1};
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const PostingList L2{2};
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const PostingList L3{3};
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// empty and/or yield true/false
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EXPECT_EQ(llvm::to_string(*C.intersect()), "true");
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EXPECT_EQ(llvm::to_string(*C.unionOf()), "false");
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// true/false inside and/or short-circuit
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EXPECT_EQ(llvm::to_string(*C.intersect(L1.iterator(), C.all())), "[1]");
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EXPECT_EQ(llvm::to_string(*C.intersect(L1.iterator(), C.none())), "false");
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// Not optimized to avoid breaking boosts.
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EXPECT_EQ(llvm::to_string(*C.unionOf(L1.iterator(), C.all())),
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"(| [1] true)");
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EXPECT_EQ(llvm::to_string(*C.unionOf(L1.iterator(), C.none())), "[1]");
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// and/or nested inside and/or are flattened
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EXPECT_EQ(llvm::to_string(*C.intersect(
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L1.iterator(), C.intersect(L1.iterator(), L1.iterator()))),
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"(& [1] [1] [1])");
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EXPECT_EQ(llvm::to_string(*C.unionOf(
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L1.iterator(), C.unionOf(L2.iterator(), L3.iterator()))),
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"(| [1] [2] [3])");
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// optimizations combine over multiple levels
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EXPECT_EQ(llvm::to_string(*C.intersect(
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C.intersect(L1.iterator(), C.intersect()), C.unionOf(C.all()))),
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"[1]");
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}
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//===----------------------------------------------------------------------===//
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// Search token tests.
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//===----------------------------------------------------------------------===//
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::testing::Matcher<std::vector<Token>>
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tokensAre(std::initializer_list<std::string> Strings, Token::Kind Kind) {
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std::vector<Token> Tokens;
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for (const auto &TokenData : Strings) {
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Tokens.push_back(Token(Kind, TokenData));
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}
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return ::testing::UnorderedElementsAreArray(Tokens);
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}
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::testing::Matcher<std::vector<Token>>
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trigramsAre(std::initializer_list<std::string> Trigrams) {
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return tokensAre(Trigrams, Token::Kind::Trigram);
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}
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std::vector<Token> identifierTrigramTokens(llvm::StringRef S) {
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std::vector<Trigram> Trigrams;
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generateIdentifierTrigrams(S, Trigrams);
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std::vector<Token> Tokens;
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for (Trigram T : Trigrams)
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Tokens.emplace_back(Token::Kind::Trigram, T.str());
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return Tokens;
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}
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TEST(DexTrigrams, IdentifierTrigrams) {
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EXPECT_THAT(identifierTrigramTokens("X86"), trigramsAre({"x86", "x", "x8"}));
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EXPECT_THAT(identifierTrigramTokens("nl"), trigramsAre({"nl", "n"}));
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EXPECT_THAT(identifierTrigramTokens("n"), trigramsAre({"n"}));
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EXPECT_THAT(identifierTrigramTokens("clangd"),
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trigramsAre({"c", "cl", "cla", "lan", "ang", "ngd"}));
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EXPECT_THAT(identifierTrigramTokens("abc_def"),
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trigramsAre({"a", "ab", "ad", "abc", "abd", "ade", "bcd", "bde",
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"cde", "def"}));
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EXPECT_THAT(identifierTrigramTokens("a_b_c_d_e_"),
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trigramsAre({"a", "a_", "ab", "abc", "bcd", "cde"}));
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EXPECT_THAT(identifierTrigramTokens("unique_ptr"),
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trigramsAre({"u", "un", "up", "uni", "unp", "upt", "niq", "nip",
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"npt", "iqu", "iqp", "ipt", "que", "qup", "qpt",
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"uep", "ept", "ptr"}));
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EXPECT_THAT(
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identifierTrigramTokens("TUDecl"),
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trigramsAre({"t", "tu", "td", "tud", "tde", "ude", "dec", "ecl"}));
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EXPECT_THAT(identifierTrigramTokens("IsOK"),
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trigramsAre({"i", "is", "io", "iso", "iok", "sok"}));
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EXPECT_THAT(
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identifierTrigramTokens("abc_defGhij__klm"),
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trigramsAre({"a", "ab", "ad", "abc", "abd", "ade", "adg", "bcd",
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"bde", "bdg", "cde", "cdg", "def", "deg", "dgh", "dgk",
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"efg", "egh", "egk", "fgh", "fgk", "ghi", "ghk", "gkl",
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"hij", "hik", "hkl", "ijk", "ikl", "jkl", "klm"}));
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}
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TEST(DexTrigrams, QueryTrigrams) {
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EXPECT_THAT(generateQueryTrigrams("c"), trigramsAre({"c"}));
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EXPECT_THAT(generateQueryTrigrams("cl"), trigramsAre({"cl"}));
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EXPECT_THAT(generateQueryTrigrams("cla"), trigramsAre({"cla"}));
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EXPECT_THAT(generateQueryTrigrams(""), trigramsAre({}));
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EXPECT_THAT(generateQueryTrigrams("_"), trigramsAre({"_"}));
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EXPECT_THAT(generateQueryTrigrams("__"), trigramsAre({"__"}));
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EXPECT_THAT(generateQueryTrigrams("___"), trigramsAre({}));
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EXPECT_THAT(generateQueryTrigrams("X86"), trigramsAre({"x86"}));
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EXPECT_THAT(generateQueryTrigrams("clangd"),
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trigramsAre({"cla", "lan", "ang", "ngd"}));
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EXPECT_THAT(generateQueryTrigrams("abc_def"),
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trigramsAre({"abc", "bcd", "cde", "def"}));
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EXPECT_THAT(generateQueryTrigrams("a_b_c_d_e_"),
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trigramsAre({"abc", "bcd", "cde"}));
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EXPECT_THAT(generateQueryTrigrams("unique_ptr"),
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trigramsAre({"uni", "niq", "iqu", "que", "uep", "ept", "ptr"}));
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EXPECT_THAT(generateQueryTrigrams("TUDecl"),
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trigramsAre({"tud", "ude", "dec", "ecl"}));
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EXPECT_THAT(generateQueryTrigrams("IsOK"), trigramsAre({"iso", "sok"}));
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EXPECT_THAT(generateQueryTrigrams("abc_defGhij__klm"),
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trigramsAre({"abc", "bcd", "cde", "def", "efg", "fgh", "ghi",
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"hij", "ijk", "jkl", "klm"}));
|
|
}
|
|
|
|
TEST(DexSearchTokens, SymbolPath) {
|
|
EXPECT_THAT(generateProximityURIs(
|
|
"unittest:///clang-tools-extra/clangd/index/Token.h"),
|
|
ElementsAre("unittest:///clang-tools-extra/clangd/index/Token.h",
|
|
"unittest:///clang-tools-extra/clangd/index",
|
|
"unittest:///clang-tools-extra/clangd",
|
|
"unittest:///clang-tools-extra", "unittest:///"));
|
|
|
|
EXPECT_THAT(generateProximityURIs("unittest:///a/b/c.h"),
|
|
ElementsAre("unittest:///a/b/c.h", "unittest:///a/b",
|
|
"unittest:///a", "unittest:///"));
|
|
}
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Index tests.
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
TEST(Dex, Lookup) {
|
|
auto I = Dex::build(generateSymbols({"ns::abc", "ns::xyz"}), RefSlab(),
|
|
RelationSlab());
|
|
EXPECT_THAT(lookup(*I, SymbolID("ns::abc")), UnorderedElementsAre("ns::abc"));
|
|
EXPECT_THAT(lookup(*I, {SymbolID("ns::abc"), SymbolID("ns::xyz")}),
|
|
UnorderedElementsAre("ns::abc", "ns::xyz"));
|
|
EXPECT_THAT(lookup(*I, {SymbolID("ns::nonono"), SymbolID("ns::xyz")}),
|
|
UnorderedElementsAre("ns::xyz"));
|
|
EXPECT_THAT(lookup(*I, SymbolID("ns::nonono")), UnorderedElementsAre());
|
|
}
|
|
|
|
TEST(Dex, FuzzyFind) {
|
|
auto Index =
|
|
Dex::build(generateSymbols({"ns::ABC", "ns::BCD", "::ABC",
|
|
"ns::nested::ABC", "other::ABC", "other::A"}),
|
|
RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "ABC";
|
|
Req.Scopes = {"ns::"};
|
|
EXPECT_THAT(match(*Index, Req), UnorderedElementsAre("ns::ABC"));
|
|
Req.Scopes = {"ns::", "ns::nested::"};
|
|
EXPECT_THAT(match(*Index, Req),
|
|
UnorderedElementsAre("ns::ABC", "ns::nested::ABC"));
|
|
Req.Query = "A";
|
|
Req.Scopes = {"other::"};
|
|
EXPECT_THAT(match(*Index, Req),
|
|
UnorderedElementsAre("other::A", "other::ABC"));
|
|
Req.Query = "";
|
|
Req.Scopes = {};
|
|
Req.AnyScope = true;
|
|
EXPECT_THAT(match(*Index, Req),
|
|
UnorderedElementsAre("ns::ABC", "ns::BCD", "::ABC",
|
|
"ns::nested::ABC", "other::ABC",
|
|
"other::A"));
|
|
}
|
|
|
|
TEST(DexTest, DexLimitedNumMatches) {
|
|
auto I = Dex::build(generateNumSymbols(0, 100), RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "5";
|
|
Req.AnyScope = true;
|
|
Req.Limit = 3;
|
|
bool Incomplete;
|
|
auto Matches = match(*I, Req, &Incomplete);
|
|
EXPECT_TRUE(Req.Limit);
|
|
EXPECT_EQ(Matches.size(), *Req.Limit);
|
|
EXPECT_TRUE(Incomplete);
|
|
}
|
|
|
|
TEST(DexTest, FuzzyMatch) {
|
|
auto I = Dex::build(
|
|
generateSymbols({"LaughingOutLoud", "LionPopulation", "LittleOldLady"}),
|
|
RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "lol";
|
|
Req.AnyScope = true;
|
|
Req.Limit = 2;
|
|
EXPECT_THAT(match(*I, Req),
|
|
UnorderedElementsAre("LaughingOutLoud", "LittleOldLady"));
|
|
}
|
|
|
|
TEST(DexTest, ShortQuery) {
|
|
auto I = Dex::build(generateSymbols({"OneTwoThreeFour"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
bool Incomplete;
|
|
|
|
EXPECT_THAT(match(*I, Req, &Incomplete), ElementsAre("OneTwoThreeFour"));
|
|
EXPECT_FALSE(Incomplete) << "Empty string is not a short query";
|
|
|
|
Req.Query = "t";
|
|
EXPECT_THAT(match(*I, Req, &Incomplete), ElementsAre());
|
|
EXPECT_TRUE(Incomplete) << "Short queries have different semantics";
|
|
|
|
Req.Query = "tt";
|
|
EXPECT_THAT(match(*I, Req, &Incomplete), ElementsAre());
|
|
EXPECT_TRUE(Incomplete) << "Short queries have different semantics";
|
|
|
|
Req.Query = "ttf";
|
|
EXPECT_THAT(match(*I, Req, &Incomplete), ElementsAre("OneTwoThreeFour"));
|
|
EXPECT_FALSE(Incomplete) << "3-char string is not a short query";
|
|
}
|
|
|
|
TEST(DexTest, MatchQualifiedNamesWithoutSpecificScope) {
|
|
auto I = Dex::build(generateSymbols({"a::y1", "b::y2", "y3"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
Req.Query = "y";
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("a::y1", "b::y2", "y3"));
|
|
}
|
|
|
|
TEST(DexTest, MatchQualifiedNamesWithGlobalScope) {
|
|
auto I = Dex::build(generateSymbols({"a::y1", "b::y2", "y3"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "y";
|
|
Req.Scopes = {""};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("y3"));
|
|
}
|
|
|
|
TEST(DexTest, MatchQualifiedNamesWithOneScope) {
|
|
auto I =
|
|
Dex::build(generateSymbols({"a::y1", "a::y2", "a::x", "b::y2", "y3"}),
|
|
RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "y";
|
|
Req.Scopes = {"a::"};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("a::y1", "a::y2"));
|
|
}
|
|
|
|
TEST(DexTest, MatchQualifiedNamesWithMultipleScopes) {
|
|
auto I =
|
|
Dex::build(generateSymbols({"a::y1", "a::y2", "a::x", "b::y3", "y3"}),
|
|
RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "y";
|
|
Req.Scopes = {"a::", "b::"};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("a::y1", "a::y2", "b::y3"));
|
|
}
|
|
|
|
TEST(DexTest, NoMatchNestedScopes) {
|
|
auto I = Dex::build(generateSymbols({"a::y1", "a::b::y2"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "y";
|
|
Req.Scopes = {"a::"};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("a::y1"));
|
|
}
|
|
|
|
TEST(DexTest, WildcardScope) {
|
|
auto I = Dex::build(generateSymbols({"a::y1", "a::b::y2", "c::y3"}),
|
|
RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
Req.Query = "y";
|
|
Req.Scopes = {"a::"};
|
|
EXPECT_THAT(match(*I, Req),
|
|
UnorderedElementsAre("a::y1", "a::b::y2", "c::y3"));
|
|
}
|
|
|
|
TEST(DexTest, IgnoreCases) {
|
|
auto I = Dex::build(generateSymbols({"ns::ABC", "ns::abc"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Query = "AB";
|
|
Req.Scopes = {"ns::"};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre("ns::ABC", "ns::abc"));
|
|
}
|
|
|
|
TEST(DexTest, UnknownPostingList) {
|
|
// Regression test: we used to ignore unknown scopes and accept any symbol.
|
|
auto I = Dex::build(generateSymbols({"ns::ABC", "ns::abc"}), RefSlab(),
|
|
RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.Scopes = {"ns2::"};
|
|
EXPECT_THAT(match(*I, Req), UnorderedElementsAre());
|
|
}
|
|
|
|
TEST(DexTest, Lookup) {
|
|
auto I = Dex::build(generateSymbols({"ns::abc", "ns::xyz"}), RefSlab(),
|
|
RelationSlab());
|
|
EXPECT_THAT(lookup(*I, SymbolID("ns::abc")), UnorderedElementsAre("ns::abc"));
|
|
EXPECT_THAT(lookup(*I, {SymbolID("ns::abc"), SymbolID("ns::xyz")}),
|
|
UnorderedElementsAre("ns::abc", "ns::xyz"));
|
|
EXPECT_THAT(lookup(*I, {SymbolID("ns::nonono"), SymbolID("ns::xyz")}),
|
|
UnorderedElementsAre("ns::xyz"));
|
|
EXPECT_THAT(lookup(*I, SymbolID("ns::nonono")), UnorderedElementsAre());
|
|
}
|
|
|
|
TEST(DexTest, SymbolIndexOptionsFilter) {
|
|
auto CodeCompletionSymbol = symbol("Completion");
|
|
auto NonCodeCompletionSymbol = symbol("NoCompletion");
|
|
CodeCompletionSymbol.Flags = Symbol::SymbolFlag::IndexedForCodeCompletion;
|
|
NonCodeCompletionSymbol.Flags = Symbol::SymbolFlag::None;
|
|
std::vector<Symbol> Symbols{CodeCompletionSymbol, NonCodeCompletionSymbol};
|
|
Dex I(Symbols, RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
Req.RestrictForCodeCompletion = false;
|
|
EXPECT_THAT(match(I, Req), ElementsAre("Completion", "NoCompletion"));
|
|
Req.RestrictForCodeCompletion = true;
|
|
EXPECT_THAT(match(I, Req), ElementsAre("Completion"));
|
|
}
|
|
|
|
TEST(DexTest, ProximityPathsBoosting) {
|
|
auto RootSymbol = symbol("root::abc");
|
|
RootSymbol.CanonicalDeclaration.FileURI = "unittest:///file.h";
|
|
auto CloseSymbol = symbol("close::abc");
|
|
CloseSymbol.CanonicalDeclaration.FileURI = "unittest:///a/b/c/d/e/f/file.h";
|
|
|
|
std::vector<Symbol> Symbols{CloseSymbol, RootSymbol};
|
|
Dex I(Symbols, RefSlab(), RelationSlab());
|
|
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
Req.Query = "abc";
|
|
// The best candidate can change depending on the proximity paths.
|
|
Req.Limit = 1;
|
|
|
|
// FuzzyFind request comes from the file which is far from the root: expect
|
|
// CloseSymbol to come out.
|
|
Req.ProximityPaths = {testPath("a/b/c/d/e/f/file.h")};
|
|
EXPECT_THAT(match(I, Req), ElementsAre("close::abc"));
|
|
|
|
// FuzzyFind request comes from the file which is close to the root: expect
|
|
// RootSymbol to come out.
|
|
Req.ProximityPaths = {testPath("file.h")};
|
|
EXPECT_THAT(match(I, Req), ElementsAre("root::abc"));
|
|
}
|
|
|
|
TEST(DexTests, Refs) {
|
|
llvm::DenseMap<SymbolID, std::vector<Ref>> Refs;
|
|
auto AddRef = [&](const Symbol &Sym, const char *Filename, RefKind Kind) {
|
|
auto &SymbolRefs = Refs[Sym.ID];
|
|
SymbolRefs.emplace_back();
|
|
SymbolRefs.back().Kind = Kind;
|
|
SymbolRefs.back().Location.FileURI = Filename;
|
|
};
|
|
auto Foo = symbol("foo");
|
|
auto Bar = symbol("bar");
|
|
AddRef(Foo, "foo.h", RefKind::Declaration);
|
|
AddRef(Foo, "foo.cc", RefKind::Definition);
|
|
AddRef(Foo, "reffoo.h", RefKind::Reference);
|
|
AddRef(Bar, "bar.h", RefKind::Declaration);
|
|
|
|
RefsRequest Req;
|
|
Req.IDs.insert(Foo.ID);
|
|
Req.Filter = RefKind::Declaration | RefKind::Definition;
|
|
|
|
std::vector<std::string> Files;
|
|
EXPECT_FALSE(Dex(std::vector<Symbol>{Foo, Bar}, Refs, RelationSlab())
|
|
.refs(Req, [&](const Ref &R) {
|
|
Files.push_back(R.Location.FileURI);
|
|
}));
|
|
EXPECT_THAT(Files, UnorderedElementsAre("foo.h", "foo.cc"));
|
|
|
|
Req.Limit = 1;
|
|
Files.clear();
|
|
EXPECT_TRUE(Dex(std::vector<Symbol>{Foo, Bar}, Refs, RelationSlab())
|
|
.refs(Req, [&](const Ref &R) {
|
|
Files.push_back(R.Location.FileURI);
|
|
}));
|
|
EXPECT_THAT(Files, ElementsAre(AnyOf("foo.h", "foo.cc")));
|
|
}
|
|
|
|
TEST(DexTests, Relations) {
|
|
auto Parent = symbol("Parent");
|
|
auto Child1 = symbol("Child1");
|
|
auto Child2 = symbol("Child2");
|
|
|
|
std::vector<Symbol> Symbols{Parent, Child1, Child2};
|
|
|
|
std::vector<Relation> Relations{{Parent.ID, RelationKind::BaseOf, Child1.ID},
|
|
{Parent.ID, RelationKind::BaseOf, Child2.ID}};
|
|
|
|
Dex I{Symbols, RefSlab(), Relations};
|
|
|
|
std::vector<SymbolID> Results;
|
|
RelationsRequest Req;
|
|
Req.Subjects.insert(Parent.ID);
|
|
Req.Predicate = RelationKind::BaseOf;
|
|
I.relations(Req, [&](const SymbolID &Subject, const Symbol &Object) {
|
|
Results.push_back(Object.ID);
|
|
});
|
|
EXPECT_THAT(Results, UnorderedElementsAre(Child1.ID, Child2.ID));
|
|
}
|
|
|
|
TEST(DexTest, PreferredTypesBoosting) {
|
|
auto Sym1 = symbol("t1");
|
|
Sym1.Type = "T1";
|
|
auto Sym2 = symbol("t2");
|
|
Sym2.Type = "T2";
|
|
|
|
std::vector<Symbol> Symbols{Sym1, Sym2};
|
|
Dex I(Symbols, RefSlab(), RelationSlab());
|
|
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
Req.Query = "t";
|
|
// The best candidate can change depending on the preferred type.
|
|
Req.Limit = 1;
|
|
|
|
Req.PreferredTypes = {std::string(Sym1.Type)};
|
|
EXPECT_THAT(match(I, Req), ElementsAre("t1"));
|
|
|
|
Req.PreferredTypes = {std::string(Sym2.Type)};
|
|
EXPECT_THAT(match(I, Req), ElementsAre("t2"));
|
|
}
|
|
|
|
TEST(DexTest, TemplateSpecialization) {
|
|
SymbolSlab::Builder B;
|
|
|
|
Symbol S = symbol("TempSpec");
|
|
S.ID = SymbolID("0");
|
|
B.insert(S);
|
|
|
|
S = symbol("TempSpec");
|
|
S.ID = SymbolID("1");
|
|
S.TemplateSpecializationArgs = "<int, bool>";
|
|
S.SymInfo.Properties = static_cast<index::SymbolPropertySet>(
|
|
index::SymbolProperty::TemplateSpecialization);
|
|
B.insert(S);
|
|
|
|
S = symbol("TempSpec");
|
|
S.ID = SymbolID("2");
|
|
S.TemplateSpecializationArgs = "<int, U>";
|
|
S.SymInfo.Properties = static_cast<index::SymbolPropertySet>(
|
|
index::SymbolProperty::TemplatePartialSpecialization);
|
|
B.insert(S);
|
|
|
|
auto I = dex::Dex::build(std::move(B).build(), RefSlab(), RelationSlab());
|
|
FuzzyFindRequest Req;
|
|
Req.AnyScope = true;
|
|
|
|
Req.Query = "TempSpec";
|
|
EXPECT_THAT(match(*I, Req),
|
|
UnorderedElementsAre("TempSpec", "TempSpec<int, bool>",
|
|
"TempSpec<int, U>"));
|
|
|
|
// FIXME: Add filtering for template argument list.
|
|
Req.Query = "TempSpec<int";
|
|
EXPECT_THAT(match(*I, Req), IsEmpty());
|
|
}
|
|
|
|
} // namespace
|
|
} // namespace dex
|
|
} // namespace clangd
|
|
} // namespace clang
|