llvm-mirror/unittests/ADT/FunctionExtrasTest.cpp

//===- FunctionExtrasTest.cpp - Unit tests for function type erasure ------===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#include "llvm/ADT/FunctionExtras.h"
#include "gtest/gtest.h"

#include <memory>

using namespace llvm;

namespace {

TEST(UniqueFunctionTest, Basic) {
  unique_function<int(int, int)> Sum = [](int A, int B) { return A + B; };
  EXPECT_EQ(Sum(1, 2), 3);

  unique_function<int(int, int)> Sum2 = std::move(Sum);
  EXPECT_EQ(Sum2(1, 2), 3);

  unique_function<int(int, int)> Sum3 = [](int A, int B) { return A + B; };
  Sum2 = std::move(Sum3);
  EXPECT_EQ(Sum2(1, 2), 3);

  Sum2 = unique_function<int(int, int)>([](int A, int B) { return A + B; });
  EXPECT_EQ(Sum2(1, 2), 3);

  // Explicit self-move test.
  *&Sum2 = std::move(Sum2);
  EXPECT_EQ(Sum2(1, 2), 3);

  Sum2 = unique_function<int(int, int)>();
  EXPECT_FALSE(Sum2);

  // Make sure we can forward through l-value reference parameters.
  unique_function<void(int &)> Inc = [](int &X) { ++X; };
  int X = 42;
  Inc(X);
  EXPECT_EQ(X, 43);

  // Make sure we can forward through r-value reference parameters with
  // move-only types.
  unique_function<int(std::unique_ptr<int> &&)> ReadAndDeallocByRef =
      [](std::unique_ptr<int> &&Ptr) {
        int V = *Ptr;
        Ptr.reset();
        return V;
      };
  std::unique_ptr<int> Ptr{new int(13)};
  EXPECT_EQ(ReadAndDeallocByRef(std::move(Ptr)), 13);
  EXPECT_FALSE((bool)Ptr);

  // Make sure we can pass a move-only temporary as opposed to a local variable.
  EXPECT_EQ(ReadAndDeallocByRef(std::unique_ptr<int>(new int(42))), 42);

  // Make sure we can pass a move-only type by-value.
  unique_function<int(std::unique_ptr<int>)> ReadAndDeallocByVal =
      [](std::unique_ptr<int> Ptr) {
        int V = *Ptr;
        Ptr.reset();
        return V;
      };
  Ptr.reset(new int(13));
  EXPECT_EQ(ReadAndDeallocByVal(std::move(Ptr)), 13);
  EXPECT_FALSE((bool)Ptr);

  EXPECT_EQ(ReadAndDeallocByVal(std::unique_ptr<int>(new int(42))), 42);
}

TEST(UniqueFunctionTest, Captures) {
  long A = 1, B = 2, C = 3, D = 4, E = 5;

  unique_function<long()> Tmp;

  unique_function<long()> C1 = [A]() { return A; };
  EXPECT_EQ(C1(), 1);
  Tmp = std::move(C1);
  EXPECT_EQ(Tmp(), 1);

  unique_function<long()> C2 = [A, B]() { return A + B; };
  EXPECT_EQ(C2(), 3);
  Tmp = std::move(C2);
  EXPECT_EQ(Tmp(), 3);

  unique_function<long()> C3 = [A, B, C]() { return A + B + C; };
  EXPECT_EQ(C3(), 6);
  Tmp = std::move(C3);
  EXPECT_EQ(Tmp(), 6);

  unique_function<long()> C4 = [A, B, C, D]() { return A + B + C + D; };
  EXPECT_EQ(C4(), 10);
  Tmp = std::move(C4);
  EXPECT_EQ(Tmp(), 10);

  unique_function<long()> C5 = [A, B, C, D, E]() { return A + B + C + D + E; };
  EXPECT_EQ(C5(), 15);
  Tmp = std::move(C5);
  EXPECT_EQ(Tmp(), 15);
}

TEST(UniqueFunctionTest, MoveOnly) {
  struct SmallCallable {
    std::unique_ptr<int> A{new int(1)};

    int operator()(int B) { return *A + B; }
  };
  unique_function<int(int)> Small = SmallCallable();
  EXPECT_EQ(Small(2), 3);
  unique_function<int(int)> Small2 = std::move(Small);
  EXPECT_EQ(Small2(2), 3);

  struct LargeCallable {
    std::unique_ptr<int> A{new int(1)};
    std::unique_ptr<int> B{new int(2)};
    std::unique_ptr<int> C{new int(3)};
    std::unique_ptr<int> D{new int(4)};
    std::unique_ptr<int> E{new int(5)};

    int operator()() { return *A + *B + *C + *D + *E; }
  };
  unique_function<int()> Large = LargeCallable();
  EXPECT_EQ(Large(), 15);
  unique_function<int()> Large2 = std::move(Large);
  EXPECT_EQ(Large2(), 15);
}

TEST(UniqueFunctionTest, CountForwardingCopies) {
  struct CopyCounter {
    int &CopyCount;

    CopyCounter(int &CopyCount) : CopyCount(CopyCount) {}
    CopyCounter(const CopyCounter &Arg) : CopyCount(Arg.CopyCount) {
      ++CopyCount;
    }
  };

  unique_function<void(CopyCounter)> ByValF = [](CopyCounter) {};
  int CopyCount = 0;
  ByValF(CopyCounter(CopyCount));
  EXPECT_EQ(1, CopyCount);

  CopyCount = 0;
  {
    CopyCounter Counter{CopyCount};
    ByValF(Counter);
  }
  EXPECT_EQ(2, CopyCount);

  // Check that we don't generate a copy at all when we can bind a reference all
  // the way down, even if that reference could *in theory* allow copies.
  unique_function<void(const CopyCounter &)> ByRefF = [](const CopyCounter &) {
  };
  CopyCount = 0;
  ByRefF(CopyCounter(CopyCount));
  EXPECT_EQ(0, CopyCount);

  CopyCount = 0;
  {
    CopyCounter Counter{CopyCount};
    ByRefF(Counter);
  }
  EXPECT_EQ(0, CopyCount);

  // If we use a reference, we can make a stronger guarantee that *no* copy
  // occurs.
  struct Uncopyable {
    Uncopyable() = default;
    Uncopyable(const Uncopyable &) = delete;
  };
  unique_function<void(const Uncopyable &)> UncopyableF =
      [](const Uncopyable &) {};
  UncopyableF(Uncopyable());
  Uncopyable X;
  UncopyableF(X);
}

TEST(UniqueFunctionTest, CountForwardingMoves) {
  struct MoveCounter {
    int &MoveCount;

    MoveCounter(int &MoveCount) : MoveCount(MoveCount) {}
    MoveCounter(MoveCounter &&Arg) : MoveCount(Arg.MoveCount) { ++MoveCount; }
  };

  unique_function<void(MoveCounter)> ByValF = [](MoveCounter) {};
  int MoveCount = 0;
  ByValF(MoveCounter(MoveCount));
  EXPECT_EQ(1, MoveCount);

  MoveCount = 0;
  {
    MoveCounter Counter{MoveCount};
    ByValF(std::move(Counter));
  }
  EXPECT_EQ(2, MoveCount);

  // Check that when we use an r-value reference we get no spurious copies.
  unique_function<void(MoveCounter &&)> ByRefF = [](MoveCounter &&) {};
  MoveCount = 0;
  ByRefF(MoveCounter(MoveCount));
  EXPECT_EQ(0, MoveCount);

  MoveCount = 0;
  {
    MoveCounter Counter{MoveCount};
    ByRefF(std::move(Counter));
  }
  EXPECT_EQ(0, MoveCount);

  // If we use an r-value reference we can in fact make a stronger guarantee
  // with an unmovable type.
  struct Unmovable {
    Unmovable() = default;
    Unmovable(Unmovable &&) = delete;
  };
  unique_function<void(const Unmovable &)> UnmovableF = [](const Unmovable &) {
  };
  UnmovableF(Unmovable());
  Unmovable X;
  UnmovableF(X);
}

} // anonymous namespace
[ADT] Add llvm::unique_function which is like std::function but supporting move-only closures. Most of the core optimizations for std::function are here plus a potentially novel one that detects trivially movable and destroyable functors and implements those with fewer indirections. This is especially useful as we start trying to add concurrency primitives as those often end up with move-only types (futures, promises, etc) and wanting them to work through lambdas. As further work, we could add better support for things like const-qualified operator()s to support more algorithms, and r-value ref qualified operator()s to model call-once. None of that is here though. We can also provide our own llvm::function that has some of the optimizations used in this class, but with copy semantics instead of move semantics. This is motivated by increasing usage of things like executors and the task queue where it is useful to embed move-only types like a std::promise within a type erased function. That isn't possible without this version of a type erased function. Differential Revision: https://reviews.llvm.org/D48349 llvm-svn: 336156 2018-07-03 01:57:29 +02:00			`//===- FunctionExtrasTest.cpp - Unit tests for function type erasure ------===//`
			`//`
			`// The LLVM Compiler Infrastructure`
			`//`
			`// This file is distributed under the University of Illinois Open Source`
			`// License. See LICENSE.TXT for details.`
			`//`
			`//===----------------------------------------------------------------------===//`

			`#include "llvm/ADT/FunctionExtras.h"`
			`#include "gtest/gtest.h"`

			`#include <memory>`

			`using namespace llvm;`

			`namespace {`

			`TEST(UniqueFunctionTest, Basic) {`
			`unique_function<int(int, int)> Sum = [](int A, int B) { return A + B; };`
			`EXPECT_EQ(Sum(1, 2), 3);`

			`unique_function<int(int, int)> Sum2 = std::move(Sum);`
			`EXPECT_EQ(Sum2(1, 2), 3);`

			`unique_function<int(int, int)> Sum3 = [](int A, int B) { return A + B; };`
			`Sum2 = std::move(Sum3);`
			`EXPECT_EQ(Sum2(1, 2), 3);`

			`Sum2 = unique_function<int(int, int)>([](int A, int B) { return A + B; });`
			`EXPECT_EQ(Sum2(1, 2), 3);`

			`// Explicit self-move test.`
			`*&Sum2 = std::move(Sum2);`
			`EXPECT_EQ(Sum2(1, 2), 3);`

			`Sum2 = unique_function<int(int, int)>();`
			`EXPECT_FALSE(Sum2);`

			`// Make sure we can forward through l-value reference parameters.`
			`unique_function<void(int &)> Inc = [](int &X) { ++X; };`
			`int X = 42;`
			`Inc(X);`
			`EXPECT_EQ(X, 43);`

			`// Make sure we can forward through r-value reference parameters with`
			`// move-only types.`
			`unique_function<int(std::unique_ptr<int> &&)> ReadAndDeallocByRef =`
			`[](std::unique_ptr<int> &&Ptr) {`
			`int V = *Ptr;`
			`Ptr.reset();`
			`return V;`
			`};`
			`std::unique_ptr<int> Ptr{new int(13)};`
			`EXPECT_EQ(ReadAndDeallocByRef(std::move(Ptr)), 13);`
			`EXPECT_FALSE((bool)Ptr);`

			`// Make sure we can pass a move-only temporary as opposed to a local variable.`
			`EXPECT_EQ(ReadAndDeallocByRef(std::unique_ptr<int>(new int(42))), 42);`

			`// Make sure we can pass a move-only type by-value.`
			`unique_function<int(std::unique_ptr<int>)> ReadAndDeallocByVal =`
			`[](std::unique_ptr<int> Ptr) {`
			`int V = *Ptr;`
			`Ptr.reset();`
			`return V;`
			`};`
			`Ptr.reset(new int(13));`
			`EXPECT_EQ(ReadAndDeallocByVal(std::move(Ptr)), 13);`
			`EXPECT_FALSE((bool)Ptr);`

			`EXPECT_EQ(ReadAndDeallocByVal(std::unique_ptr<int>(new int(42))), 42);`
			`}`

			`TEST(UniqueFunctionTest, Captures) {`
			`long A = 1, B = 2, C = 3, D = 4, E = 5;`

			`unique_function<long()> Tmp;`

			`unique_function<long()> C1 = [A]() { return A; };`
			`EXPECT_EQ(C1(), 1);`
			`Tmp = std::move(C1);`
			`EXPECT_EQ(Tmp(), 1);`

			`unique_function<long()> C2 = [A, B]() { return A + B; };`
			`EXPECT_EQ(C2(), 3);`
			`Tmp = std::move(C2);`
			`EXPECT_EQ(Tmp(), 3);`

			`unique_function<long()> C3 = [A, B, C]() { return A + B + C; };`
			`EXPECT_EQ(C3(), 6);`
			`Tmp = std::move(C3);`
			`EXPECT_EQ(Tmp(), 6);`

			`unique_function<long()> C4 = [A, B, C, D]() { return A + B + C + D; };`
			`EXPECT_EQ(C4(), 10);`
			`Tmp = std::move(C4);`
			`EXPECT_EQ(Tmp(), 10);`

			`unique_function<long()> C5 = [A, B, C, D, E]() { return A + B + C + D + E; };`
			`EXPECT_EQ(C5(), 15);`
			`Tmp = std::move(C5);`
			`EXPECT_EQ(Tmp(), 15);`
			`}`

			`TEST(UniqueFunctionTest, MoveOnly) {`
			`struct SmallCallable {`
			`std::unique_ptr<int> A{new int(1)};`

			`int operator()(int B) { return *A + B; }`
			`};`
			`unique_function<int(int)> Small = SmallCallable();`
			`EXPECT_EQ(Small(2), 3);`
			`unique_function<int(int)> Small2 = std::move(Small);`
			`EXPECT_EQ(Small2(2), 3);`

			`struct LargeCallable {`
			`std::unique_ptr<int> A{new int(1)};`
			`std::unique_ptr<int> B{new int(2)};`
			`std::unique_ptr<int> C{new int(3)};`
			`std::unique_ptr<int> D{new int(4)};`
			`std::unique_ptr<int> E{new int(5)};`

			`int operator()() { return A + B + C + D + *E; }`
			`};`
			`unique_function<int()> Large = LargeCallable();`
			`EXPECT_EQ(Large(), 15);`
			`unique_function<int()> Large2 = std::move(Large);`
			`EXPECT_EQ(Large2(), 15);`
			`}`

			`TEST(UniqueFunctionTest, CountForwardingCopies) {`
			`struct CopyCounter {`
			`int &CopyCount;`

			`CopyCounter(int &CopyCount) : CopyCount(CopyCount) {}`
			`CopyCounter(const CopyCounter &Arg) : CopyCount(Arg.CopyCount) {`
			`++CopyCount;`
			`}`
			`};`

			`unique_function<void(CopyCounter)> ByValF = [](CopyCounter) {};`
			`int CopyCount = 0;`
			`ByValF(CopyCounter(CopyCount));`
			`EXPECT_EQ(1, CopyCount);`

			`CopyCount = 0;`
			`{`
			`CopyCounter Counter{CopyCount};`
			`ByValF(Counter);`
			`}`
			`EXPECT_EQ(2, CopyCount);`

			`// Check that we don't generate a copy at all when we can bind a reference all`
			`// the way down, even if that reference could in theory allow copies.`
			`unique_function<void(const CopyCounter &)> ByRefF = [](const CopyCounter &) {`
			`};`
			`CopyCount = 0;`
			`ByRefF(CopyCounter(CopyCount));`
			`EXPECT_EQ(0, CopyCount);`

			`CopyCount = 0;`
			`{`
			`CopyCounter Counter{CopyCount};`
			`ByRefF(Counter);`
			`}`
			`EXPECT_EQ(0, CopyCount);`

			`// If we use a reference, we can make a stronger guarantee that no copy`
			`// occurs.`
			`struct Uncopyable {`
			`Uncopyable() = default;`
			`Uncopyable(const Uncopyable &) = delete;`
			`};`
			`unique_function<void(const Uncopyable &)> UncopyableF =`
			`[](const Uncopyable &) {};`
			`UncopyableF(Uncopyable());`
			`Uncopyable X;`
			`UncopyableF(X);`
			`}`

			`TEST(UniqueFunctionTest, CountForwardingMoves) {`
			`struct MoveCounter {`
			`int &MoveCount;`

			`MoveCounter(int &MoveCount) : MoveCount(MoveCount) {}`
			`MoveCounter(MoveCounter &&Arg) : MoveCount(Arg.MoveCount) { ++MoveCount; }`
			`};`

			`unique_function<void(MoveCounter)> ByValF = [](MoveCounter) {};`
			`int MoveCount = 0;`
			`ByValF(MoveCounter(MoveCount));`
			`EXPECT_EQ(1, MoveCount);`

			`MoveCount = 0;`
			`{`
			`MoveCounter Counter{MoveCount};`
			`ByValF(std::move(Counter));`
			`}`
			`EXPECT_EQ(2, MoveCount);`

			`// Check that when we use an r-value reference we get no spurious copies.`
			`unique_function<void(MoveCounter &&)> ByRefF = [](MoveCounter &&) {};`
			`MoveCount = 0;`
			`ByRefF(MoveCounter(MoveCount));`
			`EXPECT_EQ(0, MoveCount);`

			`MoveCount = 0;`
			`{`
			`MoveCounter Counter{MoveCount};`
			`ByRefF(std::move(Counter));`
			`}`
			`EXPECT_EQ(0, MoveCount);`

			`// If we use an r-value reference we can in fact make a stronger guarantee`
			`// with an unmovable type.`
			`struct Unmovable {`
			`Unmovable() = default;`
			`Unmovable(Unmovable &&) = delete;`
			`};`
			`unique_function<void(const Unmovable &)> UnmovableF = [](const Unmovable &) {`
			`};`
			`UnmovableF(Unmovable());`
			`Unmovable X;`
			`UnmovableF(X);`
			`}`

			`} // anonymous namespace`