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0068f19cfd
r327219 added wrappers to std::sort which randomly shuffle the container before sorting. This will help in uncovering non-determinism caused due to undefined sorting order of objects having the same key. To make use of that infrastructure we need to invoke llvm::sort instead of std::sort. Note: This patch is one of a series of patches to replace *all* std::sort to llvm::sort. Refer the comments section in D44363 for a list of all the required patches. llvm-svn: 329475
368 lines
10 KiB
C++
368 lines
10 KiB
C++
//===- STLExtrasTest.cpp - Unit tests for STL extras ----------------------===//
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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/STLExtras.h"
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#include "gtest/gtest.h"
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#include <list>
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#include <vector>
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using namespace llvm;
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namespace {
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int f(rank<0>) { return 0; }
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int f(rank<1>) { return 1; }
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int f(rank<2>) { return 2; }
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int f(rank<4>) { return 4; }
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TEST(STLExtrasTest, Rank) {
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// We shouldn't get ambiguities and should select the overload of the same
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// rank as the argument.
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EXPECT_EQ(0, f(rank<0>()));
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EXPECT_EQ(1, f(rank<1>()));
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EXPECT_EQ(2, f(rank<2>()));
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// This overload is missing so we end up back at 2.
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EXPECT_EQ(2, f(rank<3>()));
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// But going past 3 should work fine.
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EXPECT_EQ(4, f(rank<4>()));
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// And we can even go higher and just fall back to the last overload.
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EXPECT_EQ(4, f(rank<5>()));
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EXPECT_EQ(4, f(rank<6>()));
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}
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TEST(STLExtrasTest, EnumerateLValue) {
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// Test that a simple LValue can be enumerated and gives correct results with
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// multiple types, including the empty container.
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std::vector<char> foo = {'a', 'b', 'c'};
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typedef std::pair<std::size_t, char> CharPairType;
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std::vector<CharPairType> CharResults;
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for (auto X : llvm::enumerate(foo)) {
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CharResults.emplace_back(X.index(), X.value());
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}
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ASSERT_EQ(3u, CharResults.size());
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EXPECT_EQ(CharPairType(0u, 'a'), CharResults[0]);
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EXPECT_EQ(CharPairType(1u, 'b'), CharResults[1]);
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EXPECT_EQ(CharPairType(2u, 'c'), CharResults[2]);
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// Test a const range of a different type.
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typedef std::pair<std::size_t, int> IntPairType;
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std::vector<IntPairType> IntResults;
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const std::vector<int> bar = {1, 2, 3};
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for (auto X : llvm::enumerate(bar)) {
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IntResults.emplace_back(X.index(), X.value());
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}
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ASSERT_EQ(3u, IntResults.size());
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EXPECT_EQ(IntPairType(0u, 1), IntResults[0]);
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EXPECT_EQ(IntPairType(1u, 2), IntResults[1]);
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EXPECT_EQ(IntPairType(2u, 3), IntResults[2]);
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// Test an empty range.
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IntResults.clear();
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const std::vector<int> baz{};
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for (auto X : llvm::enumerate(baz)) {
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IntResults.emplace_back(X.index(), X.value());
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}
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EXPECT_TRUE(IntResults.empty());
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}
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TEST(STLExtrasTest, EnumerateModifyLValue) {
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// Test that you can modify the underlying entries of an lvalue range through
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// the enumeration iterator.
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std::vector<char> foo = {'a', 'b', 'c'};
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for (auto X : llvm::enumerate(foo)) {
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++X.value();
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}
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EXPECT_EQ('b', foo[0]);
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EXPECT_EQ('c', foo[1]);
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EXPECT_EQ('d', foo[2]);
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}
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TEST(STLExtrasTest, EnumerateRValueRef) {
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// Test that an rvalue can be enumerated.
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typedef std::pair<std::size_t, int> PairType;
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std::vector<PairType> Results;
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auto Enumerator = llvm::enumerate(std::vector<int>{1, 2, 3});
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for (auto X : llvm::enumerate(std::vector<int>{1, 2, 3})) {
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Results.emplace_back(X.index(), X.value());
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}
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ASSERT_EQ(3u, Results.size());
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EXPECT_EQ(PairType(0u, 1), Results[0]);
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EXPECT_EQ(PairType(1u, 2), Results[1]);
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EXPECT_EQ(PairType(2u, 3), Results[2]);
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}
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TEST(STLExtrasTest, EnumerateModifyRValue) {
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// Test that when enumerating an rvalue, modification still works (even if
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// this isn't terribly useful, it at least shows that we haven't snuck an
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// extra const in there somewhere.
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typedef std::pair<std::size_t, char> PairType;
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std::vector<PairType> Results;
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for (auto X : llvm::enumerate(std::vector<char>{'1', '2', '3'})) {
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++X.value();
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Results.emplace_back(X.index(), X.value());
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}
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ASSERT_EQ(3u, Results.size());
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EXPECT_EQ(PairType(0u, '2'), Results[0]);
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EXPECT_EQ(PairType(1u, '3'), Results[1]);
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EXPECT_EQ(PairType(2u, '4'), Results[2]);
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}
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template <bool B> struct CanMove {};
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template <> struct CanMove<false> {
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CanMove(CanMove &&) = delete;
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CanMove() = default;
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CanMove(const CanMove &) = default;
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};
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template <bool B> struct CanCopy {};
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template <> struct CanCopy<false> {
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CanCopy(const CanCopy &) = delete;
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CanCopy() = default;
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CanCopy(CanCopy &&) = default;
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};
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template <bool Moveable, bool Copyable>
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struct Range : CanMove<Moveable>, CanCopy<Copyable> {
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explicit Range(int &C, int &M, int &D) : C(C), M(M), D(D) {}
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Range(const Range &R) : CanCopy<Copyable>(R), C(R.C), M(R.M), D(R.D) { ++C; }
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Range(Range &&R) : CanMove<Moveable>(std::move(R)), C(R.C), M(R.M), D(R.D) {
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++M;
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}
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~Range() { ++D; }
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int &C;
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int &M;
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int &D;
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int *begin() { return nullptr; }
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int *end() { return nullptr; }
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};
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TEST(STLExtrasTest, EnumerateLifetimeSemantics) {
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// Test that when enumerating lvalues and rvalues, there are no surprise
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// copies or moves.
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// With an rvalue, it should not be destroyed until the end of the scope.
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int Copies = 0;
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int Moves = 0;
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int Destructors = 0;
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{
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auto E1 = enumerate(Range<true, false>(Copies, Moves, Destructors));
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// Doesn't compile. rvalue ranges must be moveable.
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// auto E2 = enumerate(Range<false, true>(Copies, Moves, Destructors));
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EXPECT_EQ(0, Copies);
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EXPECT_EQ(1, Moves);
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EXPECT_EQ(1, Destructors);
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}
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EXPECT_EQ(0, Copies);
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EXPECT_EQ(1, Moves);
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EXPECT_EQ(2, Destructors);
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Copies = Moves = Destructors = 0;
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// With an lvalue, it should not be destroyed even after the end of the scope.
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// lvalue ranges need be neither copyable nor moveable.
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Range<false, false> R(Copies, Moves, Destructors);
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{
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auto Enumerator = enumerate(R);
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(void)Enumerator;
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EXPECT_EQ(0, Copies);
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EXPECT_EQ(0, Moves);
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EXPECT_EQ(0, Destructors);
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}
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EXPECT_EQ(0, Copies);
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EXPECT_EQ(0, Moves);
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EXPECT_EQ(0, Destructors);
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}
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TEST(STLExtrasTest, ApplyTuple) {
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auto T = std::make_tuple(1, 3, 7);
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auto U = llvm::apply_tuple(
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[](int A, int B, int C) { return std::make_tuple(A - B, B - C, C - A); },
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T);
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EXPECT_EQ(-2, std::get<0>(U));
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EXPECT_EQ(-4, std::get<1>(U));
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EXPECT_EQ(6, std::get<2>(U));
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auto V = llvm::apply_tuple(
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[](int A, int B, int C) {
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return std::make_tuple(std::make_pair(A, char('A' + A)),
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std::make_pair(B, char('A' + B)),
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std::make_pair(C, char('A' + C)));
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},
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T);
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EXPECT_EQ(std::make_pair(1, 'B'), std::get<0>(V));
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EXPECT_EQ(std::make_pair(3, 'D'), std::get<1>(V));
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EXPECT_EQ(std::make_pair(7, 'H'), std::get<2>(V));
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}
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class apply_variadic {
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static int apply_one(int X) { return X + 1; }
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static char apply_one(char C) { return C + 1; }
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static StringRef apply_one(StringRef S) { return S.drop_back(); }
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public:
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template <typename... Ts>
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auto operator()(Ts &&... Items)
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-> decltype(std::make_tuple(apply_one(Items)...)) {
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return std::make_tuple(apply_one(Items)...);
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}
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};
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TEST(STLExtrasTest, ApplyTupleVariadic) {
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auto Items = std::make_tuple(1, llvm::StringRef("Test"), 'X');
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auto Values = apply_tuple(apply_variadic(), Items);
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EXPECT_EQ(2, std::get<0>(Values));
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EXPECT_EQ("Tes", std::get<1>(Values));
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EXPECT_EQ('Y', std::get<2>(Values));
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}
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TEST(STLExtrasTest, CountAdaptor) {
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std::vector<int> v;
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v.push_back(1);
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v.push_back(2);
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v.push_back(1);
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v.push_back(4);
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v.push_back(3);
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v.push_back(2);
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v.push_back(1);
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EXPECT_EQ(3, count(v, 1));
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EXPECT_EQ(2, count(v, 2));
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EXPECT_EQ(1, count(v, 3));
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EXPECT_EQ(1, count(v, 4));
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}
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TEST(STLExtrasTest, for_each) {
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std::vector<int> v{0, 1, 2, 3, 4};
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int count = 0;
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llvm::for_each(v, [&count](int) { ++count; });
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EXPECT_EQ(5, count);
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}
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TEST(STLExtrasTest, ToVector) {
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std::vector<char> v = {'a', 'b', 'c'};
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auto Enumerated = to_vector<4>(enumerate(v));
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ASSERT_EQ(3u, Enumerated.size());
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for (size_t I = 0; I < v.size(); ++I) {
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EXPECT_EQ(I, Enumerated[I].index());
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EXPECT_EQ(v[I], Enumerated[I].value());
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}
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}
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TEST(STLExtrasTest, ConcatRange) {
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std::vector<int> Expected = {1, 2, 3, 4, 5, 6, 7, 8};
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std::vector<int> Test;
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std::vector<int> V1234 = {1, 2, 3, 4};
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std::list<int> L56 = {5, 6};
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SmallVector<int, 2> SV78 = {7, 8};
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// Use concat across different sized ranges of different types with different
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// iterators.
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for (int &i : concat<int>(V1234, L56, SV78))
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Test.push_back(i);
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EXPECT_EQ(Expected, Test);
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// Use concat between a temporary, an L-value, and an R-value to make sure
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// complex lifetimes work well.
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Test.clear();
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for (int &i : concat<int>(std::vector<int>(V1234), L56, std::move(SV78)))
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Test.push_back(i);
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EXPECT_EQ(Expected, Test);
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}
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TEST(STLExtrasTest, PartitionAdaptor) {
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std::vector<int> V = {1, 2, 3, 4, 5, 6, 7, 8};
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auto I = partition(V, [](int i) { return i % 2 == 0; });
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ASSERT_EQ(V.begin() + 4, I);
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// Sort the two halves as partition may have messed with the order.
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llvm::sort(V.begin(), I);
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llvm::sort(I, V.end());
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EXPECT_EQ(2, V[0]);
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EXPECT_EQ(4, V[1]);
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EXPECT_EQ(6, V[2]);
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EXPECT_EQ(8, V[3]);
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EXPECT_EQ(1, V[4]);
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EXPECT_EQ(3, V[5]);
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EXPECT_EQ(5, V[6]);
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EXPECT_EQ(7, V[7]);
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}
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TEST(STLExtrasTest, EraseIf) {
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std::vector<int> V = {1, 2, 3, 4, 5, 6, 7, 8};
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erase_if(V, [](int i) { return i % 2 == 0; });
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EXPECT_EQ(4u, V.size());
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EXPECT_EQ(1, V[0]);
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EXPECT_EQ(3, V[1]);
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EXPECT_EQ(5, V[2]);
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EXPECT_EQ(7, V[3]);
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}
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namespace some_namespace {
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struct some_struct {
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std::vector<int> data;
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std::string swap_val;
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};
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std::vector<int>::const_iterator begin(const some_struct &s) {
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return s.data.begin();
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}
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std::vector<int>::const_iterator end(const some_struct &s) {
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return s.data.end();
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}
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void swap(some_struct &lhs, some_struct &rhs) {
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// make swap visible as non-adl swap would even seem to
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// work with std::swap which defaults to moving
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lhs.swap_val = "lhs";
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rhs.swap_val = "rhs";
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}
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} // namespace some_namespace
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TEST(STLExtrasTest, ADLTest) {
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some_namespace::some_struct s{{1, 2, 3, 4, 5}, ""};
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some_namespace::some_struct s2{{2, 4, 6, 8, 10}, ""};
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EXPECT_EQ(*adl_begin(s), 1);
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EXPECT_EQ(*(adl_end(s) - 1), 5);
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adl_swap(s, s2);
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EXPECT_EQ(s.swap_val, "lhs");
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EXPECT_EQ(s2.swap_val, "rhs");
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int count = 0;
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llvm::for_each(s, [&count](int) { ++count; });
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EXPECT_EQ(5, count);
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}
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} // namespace
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