Refactor uses_allocator test types for upcoming fixes

git-svn-id: https://llvm.org/svn/llvm-project/libcxx/trunk@289197 91177308-0d34-0410-b5e6-96231b3b80d8
2016-12-09 09:51:09 +00:00
parent 11715ba8e2
commit e386ad3090
9 changed files with 665 additions and 377 deletions
--- a/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_const_lvalue_pair.pass.cpp
+++ b/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_const_lvalue_pair.pass.cpp
@@ -23,7 +23,12 @@
 #include <tuple>
 #include <cassert>
 #include <cstdlib>
 #include "test_macros.h"
 #include "test_memory_resource.hpp"
 #include "uses_alloc_types.hpp"
 #include "controlled_allocators.hpp"
 #include "test_allocator.h"
 namespace ex = std::experimental::pmr;
--- a/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_rvalue.pass.cpp
+++ b/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_rvalue.pass.cpp
@@ -23,7 +23,12 @@
 #include <tuple>
 #include <cassert>
 #include <cstdlib>
 #include "test_macros.h"
 #include "test_memory_resource.hpp"
 #include "uses_alloc_types.hpp"
 #include "controlled_allocators.hpp"
 #include "test_allocator.h"
 namespace ex = std::experimental::pmr;
--- a/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_values.pass.cpp
+++ b/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_pair_values.pass.cpp
@@ -23,7 +23,12 @@
 #include <tuple>
 #include <cassert>
 #include <cstdlib>
 #include "test_macros.h"
 #include "test_memory_resource.hpp"
 #include "uses_alloc_types.hpp"
 #include "controlled_allocators.hpp"
 #include "test_allocator.h"
 namespace ex = std::experimental::pmr;
--- a/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_piecewise_pair.pass.cpp
+++ b/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_piecewise_pair.pass.cpp
@@ -24,7 +24,11 @@
 #include <tuple>
 #include <cassert>
 #include <cstdlib>
 #include "test_macros.h"
 #include "test_memory_resource.hpp"
 #include "uses_alloc_types.hpp"
 #include "controlled_allocators.hpp"
 #include "test_allocator.h"
 namespace ex = std::experimental::pmr;
--- a/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_types.pass.cpp
+++ b/test/std/experimental/memory/memory.polymorphic.allocator.class/memory.polymorphic.allocator.mem/construct_types.pass.cpp
@@ -21,7 +21,11 @@
 #include <type_traits>
 #include <cassert>
 #include <cstdlib>
 #include "test_macros.h"
 #include "test_memory_resource.hpp"
 #include "uses_alloc_types.hpp"
 #include "controlled_allocators.hpp"
 #include "test_allocator.h"
 namespace ex = std::experimental::pmr;
--- a/test/support/controlled_allocators.hpp
+++ b/test/support/controlled_allocators.hpp
@@ -0,0 +1,498 @@
 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 #ifndef SUPPORT_CONTROLLED_ALLOCATORS_HPP
 #define SUPPORT_CONTROLLED_ALLOCATORS_HPP
 #include <memory>
 #include <type_traits>
 #include <cstddef>
 #include <cstdlib>
 #include <cstring>
 #include <cstdint>
 #include <cassert>
 #include "test_macros.h"
 #include "type_id.h"
 struct AllocController;
    // 'AllocController' is a concrete type that instruments and controls the
    // behavior of of test allocators.
 template <class T, size_t ID = 0>
 class CountingAllocator;
    // 'CountingAllocator' is an basic implementation of the 'Allocator'
    // requirements that use the 'AllocController' interface.
 template <class T>
 class MinAlignAllocator;
    // 'MinAlignAllocator' is an instrumented test type which implements the
    // 'Allocator' requirements. 'MinAlignAllocator' ensures that it *never*
    // returns a pointer to over-aligned storage. For example
    // 'MinAlignPointer<char>{}.allocate(...)' will never a 2-byte aligned
    // pointer.
 template <class T>
 class NullAllocator;
    // 'NullAllocator' is an instrumented test type which implements the
    // 'Allocator' requirements except that 'allocator' and 'deallocate' are
    // nops.
 #define DISALLOW_COPY(Type) \
  Type(Type const&) = delete; \
  Type& operator=(Type const&) = delete
 constexpr std::size_t MaxAlignV = alignof(std::max_align_t);
 struct TestException {};
 struct AllocController {
    int copy_constructed = 0;
    int move_constructed = 0;
    int alive = 0;
    int alloc_count = 0;
    int dealloc_count = 0;
    int is_equal_count = 0;
    std::size_t alive_size;
    std::size_t allocated_size;
    std::size_t deallocated_size;
    std::size_t last_size = 0;
    std::size_t last_align = 0;
    void * last_pointer = 0;
    std::size_t last_alloc_size = 0;
    std::size_t last_alloc_align = 0;
    void * last_alloc_pointer = nullptr;
    std::size_t last_dealloc_size = 0;
    std::size_t last_dealloc_align = 0;
    void * last_dealloc_pointer = nullptr;
    bool throw_on_alloc = false;
    int construct_called = 0;
    void *last_construct_pointer = nullptr;
    TypeID const* last_construct_alloc = nullptr;
    TypeID const* last_construct_type = nullptr;
    TypeID const* last_construct_args = nullptr;
    int destroy_called = 0;
    void *last_destroy_pointer = nullptr;
    TypeID const* last_destroy_alloc = nullptr;
    TypeID const* last_destroy_type = nullptr;
    AllocController() = default;
    void countAlloc(void* p, size_t s, size_t a) {
        ++alive;
        ++alloc_count;
        alive_size += s;
        allocated_size += s;
        last_pointer = last_alloc_pointer = p;
        last_size = last_alloc_size = s;
        last_align = last_alloc_align = a;
    }
    void countDealloc(void* p, size_t s, size_t a) {
        --alive;
        ++dealloc_count;
        alive_size -= s;
        deallocated_size += s;
        last_pointer = last_dealloc_pointer = p;
        last_size = last_dealloc_size = s;
        last_align = last_dealloc_align = a;
    }
    template <class ...Args, class Alloc, class Tp>
    void countConstruct(Alloc const& a, Tp *p) {
      ++construct_called;
      last_construct_pointer = p;
      last_construct_alloc = &makeTypeID<Alloc>();
      last_construct_type = &makeTypeID<Tp>();
      last_construct_args = &makeArgumentID<Args...>();
    }
    template <class Alloc, class Tp>
    void countDestroy(Alloc const& a, Tp *p) {
      ++destroy_called;
      last_destroy_alloc = &makeTypeID<Alloc>();
      last_destroy_type = &makeTypeID<Tp>();
      last_destroy_pointer = p;
    }
    void reset() { std::memset(this, 0, sizeof(*this)); }
    void resetConstructDestroy() {
      construct_called = 0;
      last_construct_pointer = nullptr;
      last_construct_alloc = last_construct_args = last_construct_type = nullptr;
      destroy_called = 0;
      last_destroy_alloc = nullptr;
      last_destroy_pointer = nullptr;
    }
 public:
    bool checkAlloc(void* p, size_t s, size_t a) const {
        return p == last_alloc_pointer &&
               s == last_alloc_size &&
               a == last_alloc_align;
    }
    bool checkAlloc(void* p, size_t s) const {
        return p == last_alloc_pointer &&
               s == last_alloc_size;
    }
    bool checkAllocAtLeast(void* p, size_t s, size_t a) const {
        return p == last_alloc_pointer &&
               s <= last_alloc_size &&
               a <= last_alloc_align;
    }
    bool checkAllocAtLeast(void* p, size_t s) const {
        return p == last_alloc_pointer &&
               s <= last_alloc_size;
    }
    bool checkDealloc(void* p, size_t s, size_t a) const {
        return p == last_dealloc_pointer &&
               s == last_dealloc_size &&
               a == last_dealloc_align;
    }
    bool checkDealloc(void* p, size_t s) const {
        return p == last_dealloc_pointer &&
               s == last_dealloc_size;
    }
    bool checkDeallocMatchesAlloc() const {
        return last_dealloc_pointer == last_alloc_pointer &&
               last_dealloc_size == last_alloc_size &&
               last_dealloc_align == last_alloc_align;
    }
    template <class ...Args, class Alloc, class Tp>
    bool checkConstruct(Alloc const&, Tp *p) const {
      auto expectAlloc = &makeTypeID<Alloc>();
      auto expectTp = &makeTypeID<Tp>();
      auto expectArgs = &makeArgumentID<Args...>();
      return last_construct_pointer == p &&
          COMPARE_TYPEID(last_construct_alloc, expectAlloc) &&
          COMPARE_TYPEID(last_construct_type, expectTp) &&
          COMPARE_TYPEID(last_construct_args, expectArgs);
    }
    template <class Alloc, class Tp>
    bool checkDestroy(Alloc const&, Tp *p) const {
      return last_destroy_pointer == p &&
          last_destroy_alloc == &makeTypeID<Alloc>() &&
          last_destroy_type == &makeTypeID<Tp>();
    }
    bool checkDestroyMatchesConstruct() const {
      return last_destroy_pointer == last_construct_pointer &&
          last_destroy_type == last_construct_type;
    }
    void countIsEqual() {
        ++is_equal_count;
    }
    bool checkIsEqualCalledEq(int n) const {
        return is_equal_count == n;
    }
 private:
  DISALLOW_COPY(AllocController);
 };
 template <class T, size_t ID>
 class CountingAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    template <class U>
    struct rebind { using other = CountingAllocator<U, ID>; };
    CountingAllocator() = delete;
    explicit CountingAllocator(AllocController& PP) : P(&PP) {}
    CountingAllocator(CountingAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    CountingAllocator(CountingAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U, ID> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U, ID>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n)
    {
        void* ret = ::operator new(n*sizeof(T));
        P->countAlloc(ret, n*sizeof(T), alignof(T));
        return static_cast<T*>(ret);
    }
    void deallocate(T* p, std::size_t n)
    {
        void* vp = static_cast<void*>(p);
        P->countDealloc(vp, n*sizeof(T), alignof(T));
        ::operator delete(vp);
    }
    template <class U, class ...Args>
    void construct(U *p, Args&&... args) {
      auto *c = ::new ((void*)p) U(std::forward<Args>(args)...);
      P->countConstruct<Args&&...>(*this, p);
    }
    template <class U>
    void destroy(U* p) {
      p->~U();
      P->countDestroy(*this, p);
    }
    AllocController& getController() const { return *P; }
 private:
    template <class Tp, size_t XID> friend class CountingAllocator;
    AllocController *P;
 };
 template <size_t ID>
 class CountingAllocator<void, ID>
 {
 public:
    typedef void* pointer;
    typedef const void* const_pointer;
    typedef void value_type;
    template <class U>
    struct rebind { using other = CountingAllocator<U, ID>; };
    CountingAllocator() = delete;
    explicit CountingAllocator(AllocController& PP) : P(&PP) {}
    CountingAllocator(CountingAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    CountingAllocator(CountingAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U, ID> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U, ID>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    void construct(...) = delete;
    void destroy(void*) = delete;
    AllocController& getController() const { return *P; }
 private:
    template <class Tp, size_t> friend class CountingAllocator;
    AllocController *P;
 };
 template <class T, class U, size_t ID>
 inline bool operator==(CountingAllocator<T, ID> const& x,
                       CountingAllocator<U, ID> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U, size_t ID>
 inline bool operator!=(CountingAllocator<T, ID> const& x,
                       CountingAllocator<U, ID> const& y) {
    return !(x == y);
 }
 template <class T>
 class MinAlignedAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    MinAlignedAllocator() = delete;
    explicit MinAlignedAllocator(AllocController& R) : P(&R) {}
    MinAlignedAllocator(MinAlignedAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    MinAlignedAllocator(MinAlignedAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    MinAlignedAllocator(MinAlignedAllocator<U> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    MinAlignedAllocator(MinAlignedAllocator<U>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n) {
        char* aligned_ptr = (char*)::operator new(alloc_size(n*sizeof(T)));
        assert(is_max_aligned(aligned_ptr));
        char* unaligned_ptr = aligned_ptr + alignof(T);
        assert(is_min_aligned(unaligned_ptr));
        P->countAlloc(unaligned_ptr, n * sizeof(T), alignof(T));
        return ((T*)unaligned_ptr);
    }
    void deallocate(T* p, std::size_t n) {
        assert(is_min_aligned(p));
        char* aligned_ptr = ((char*)p) - alignof(T);
        assert(is_max_aligned(aligned_ptr));
        P->countDealloc(p, n*sizeof(T), alignof(T));
        return ::operator delete(static_cast<void*>(aligned_ptr));
    }
    template <class U, class ...Args>
    void construct(U *p, Args&&... args) {
      auto *c = ::new ((void*)p) U(std::forward<Args>(args)...);
      P->countConstruct<Args&&...>(*this, p);
    }
    template <class U>
    void destroy(U* p) {
      p->~U();
      P->countDestroy(*this, p);
    }
    AllocController& getController() const { return *P; }
 private:
    static const std::size_t BlockSize = alignof(std::max_align_t);
    static std::size_t alloc_size(std::size_t s) {
        std::size_t bytes = (s + BlockSize - 1) & ~(BlockSize - 1);
        bytes += BlockSize;
        assert(bytes % BlockSize == 0);
        return bytes;
    }
    static bool is_max_aligned(void* p) {
        return reinterpret_cast<std::uintptr_t>(p) % BlockSize == 0;
    }
    static bool is_min_aligned(void* p) {
        if (alignof(T) == BlockSize) {
            return is_max_aligned(p);
        } else {
            return reinterpret_cast<std::uintptr_t>(p) % BlockSize == alignof(T);
        }
    }
    template <class Tp> friend class MinAlignedAllocator;
    mutable AllocController *P;
 };
 template <class T, class U>
 inline bool operator==(MinAlignedAllocator<T> const& x,
                       MinAlignedAllocator<U> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U>
 inline bool operator!=(MinAlignedAllocator<T> const& x,
                       MinAlignedAllocator<U> const& y) {
    return !(x == y);
 }
 template <class T>
 class NullAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    NullAllocator() = delete;
    explicit NullAllocator(AllocController& PP) : P(&PP) {}
    NullAllocator(NullAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    NullAllocator(NullAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    NullAllocator(NullAllocator<U> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    NullAllocator(NullAllocator<U>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n)
    {
        P->countAlloc(nullptr, n*sizeof(T), alignof(T));
        return nullptr;
    }
    void deallocate(T* p, std::size_t n)
    {
        void* vp = static_cast<void*>(p);
        P->countDealloc(vp, n*sizeof(T), alignof(T));
    }
    AllocController& getController() const { return *P; }
 private:
    template <class Tp> friend class NullAllocator;
    AllocController *P;
 };
 template <class T, class U>
 inline bool operator==(NullAllocator<T> const& x,
                       NullAllocator<U> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U>
 inline bool operator!=(NullAllocator<T> const& x,
                       NullAllocator<U> const& y) {
    return !(x == y);
 }
 #endif /* SUPPORT_CONTROLLED_ALLOCATORS_HPP */
--- a/test/support/test_memory_resource.hpp
+++ b/test/support/test_memory_resource.hpp
@@ -11,6 +11,7 @@
 #define SUPPORT_TEST_MEMORY_RESOURCE_HPP
 #include <experimental/memory_resource>
 #include <experimental/utility>
 #include <memory>
 #include <type_traits>
 #include <cstddef>
@@ -19,354 +20,17 @@
 #include <cstdint>
 #include <cassert>
 #include "test_macros.h"
 #include "controlled_allocators.hpp"
 #include "uses_alloc_types.hpp"
-struct AllocController;
+// FIXME: This is a hack to allow uses_allocator_types.hpp to work with
-    // 'AllocController' is a concrete type that instruments and controls the
+// erased_type. However we can't define that behavior directly in the header
-    // behavior of of test allocators.
+// because it con't include <experimental/memory_resource>
-
+template <>
-template <class T>
+struct TransformErasedTypeAlloc<std::experimental::erased_type> {
-class CountingAllocator;
+  using type = std::experimental::pmr::memory_resource*;
    // 'CountingAllocator' is an basic implementation of the 'Allocator'
    // requirements that use the 'AllocController' interface.
 template <class T>
 class MinAlignAllocator;
    // 'MinAlignAllocator' is an instrumented test type which implements the
    // 'Allocator' requirements. 'MinAlignAllocator' ensures that it *never*
    // returns a pointer to over-aligned storage. For example
    // 'MinAlignPointer<char>{}.allocate(...)' will never a 2-byte aligned
    // pointer.
 template <class T>
 class NullAllocator;
    // 'NullAllocator' is an instrumented test type which implements the
    // 'Allocator' requirements except that 'allocator' and 'deallocate' are
    // nops.
 #define DISALLOW_COPY(Type) \
  Type(Type const&) = delete; \
  Type& operator=(Type const&) = delete
 constexpr std::size_t MaxAlignV = alignof(std::max_align_t);
 struct TestException {};
 struct AllocController {
    int copy_constructed = 0;
    int move_constructed = 0;
    int alive = 0;
    int alloc_count = 0;
    int dealloc_count = 0;
    int is_equal_count = 0;
    std::size_t alive_size;
    std::size_t allocated_size;
    std::size_t deallocated_size;
    std::size_t last_size = 0;
    std::size_t last_align = 0;
    void * last_pointer = 0;
    std::size_t last_alloc_size = 0;
    std::size_t last_alloc_align = 0;
    void * last_alloc_pointer = nullptr;
    std::size_t last_dealloc_size = 0;
    std::size_t last_dealloc_align = 0;
    void * last_dealloc_pointer = nullptr;
    bool throw_on_alloc = false;
    AllocController() = default;
    void countAlloc(void* p, size_t s, size_t a) {
        ++alive;
        ++alloc_count;
        alive_size += s;
        allocated_size += s;
        last_pointer = last_alloc_pointer = p;
        last_size = last_alloc_size = s;
        last_align = last_alloc_align = a;
    }
    void countDealloc(void* p, size_t s, size_t a) {
        --alive;
        ++dealloc_count;
        alive_size -= s;
        deallocated_size += s;
        last_pointer = last_dealloc_pointer = p;
        last_size = last_dealloc_size = s;
        last_align = last_dealloc_align = a;
    }
    void reset() { std::memset(this, 0, sizeof(*this)); }
 public:
    bool checkAlloc(void* p, size_t s, size_t a) const {
        return p == last_alloc_pointer &&
               s == last_alloc_size &&
               a == last_alloc_align;
    }
    bool checkAlloc(void* p, size_t s) const {
        return p == last_alloc_pointer &&
               s == last_alloc_size;
    }
    bool checkAllocAtLeast(void* p, size_t s, size_t a) const {
        return p == last_alloc_pointer &&
               s <= last_alloc_size &&
               a <= last_alloc_align;
    }
    bool checkAllocAtLeast(void* p, size_t s) const {
        return p == last_alloc_pointer &&
               s <= last_alloc_size;
    }
    bool checkDealloc(void* p, size_t s, size_t a) const {
        return p == last_dealloc_pointer &&
               s == last_dealloc_size &&
               a == last_dealloc_align;
    }
    bool checkDealloc(void* p, size_t s) const {
        return p == last_dealloc_pointer &&
               s == last_dealloc_size;
    }
    bool checkDeallocMatchesAlloc() const {
        return last_dealloc_pointer == last_alloc_pointer &&
               last_dealloc_size == last_alloc_size &&
               last_dealloc_align == last_alloc_align;
    }
    void countIsEqual() {
        ++is_equal_count;
    }
    bool checkIsEqualCalledEq(int n) const {
        return is_equal_count == n;
    }
 private:
  DISALLOW_COPY(AllocController);
 };
 template <class T>
 class CountingAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    CountingAllocator() = delete;
    explicit CountingAllocator(AllocController& PP) : P(&PP) {}
    CountingAllocator(CountingAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    CountingAllocator(CountingAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    CountingAllocator(CountingAllocator<U>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n)
    {
        void* ret = ::operator new(n*sizeof(T));
        P->countAlloc(ret, n*sizeof(T), alignof(T));
        return static_cast<T*>(ret);
    }
    void deallocate(T* p, std::size_t n)
    {
        void* vp = static_cast<void*>(p);
        P->countDealloc(vp, n*sizeof(T), alignof(T));
        ::operator delete(vp);
    }
    AllocController& getController() const { return *P; }
 private:
    template <class Tp> friend class CountingAllocator;
    AllocController *P;
 };
 template <class T, class U>
 inline bool operator==(CountingAllocator<T> const& x,
                       CountingAllocator<U> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U>
 inline bool operator!=(CountingAllocator<T> const& x,
                       CountingAllocator<U> const& y) {
    return !(x == y);
 }
 template <class T>
 class MinAlignedAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    MinAlignedAllocator() = delete;
    explicit MinAlignedAllocator(AllocController& R) : P(&R) {}
    MinAlignedAllocator(MinAlignedAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    MinAlignedAllocator(MinAlignedAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    MinAlignedAllocator(MinAlignedAllocator<U> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    MinAlignedAllocator(MinAlignedAllocator<U>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n) {
        char* aligned_ptr = (char*)::operator new(alloc_size(n*sizeof(T)));
        assert(is_max_aligned(aligned_ptr));
        char* unaligned_ptr = aligned_ptr + alignof(T);
        assert(is_min_aligned(unaligned_ptr));
        P->countAlloc(unaligned_ptr, n * sizeof(T), alignof(T));
        return ((T*)unaligned_ptr);
    }
    void deallocate(T* p, std::size_t n) {
        assert(is_min_aligned(p));
        char* aligned_ptr = ((char*)p) - alignof(T);
        assert(is_max_aligned(aligned_ptr));
        P->countDealloc(p, n*sizeof(T), alignof(T));
        return ::operator delete(static_cast<void*>(aligned_ptr));
    }
    AllocController& getController() const { return *P; }
 private:
    static const std::size_t BlockSize = alignof(std::max_align_t);
    static std::size_t alloc_size(std::size_t s) {
        std::size_t bytes = (s + BlockSize - 1) & ~(BlockSize - 1);
        bytes += BlockSize;
        assert(bytes % BlockSize == 0);
        return bytes;
    }
    static bool is_max_aligned(void* p) {
        return reinterpret_cast<std::uintptr_t>(p) % BlockSize == 0;
    }
    static bool is_min_aligned(void* p) {
        if (alignof(T) == BlockSize) {
            return is_max_aligned(p);
        } else {
            return reinterpret_cast<std::uintptr_t>(p) % BlockSize == alignof(T);
        }
    }
    template <class Tp> friend class MinAlignedAllocator;
    mutable AllocController *P;
 };
 template <class T, class U>
 inline bool operator==(MinAlignedAllocator<T> const& x,
                       MinAlignedAllocator<U> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U>
 inline bool operator!=(MinAlignedAllocator<T> const& x,
                       MinAlignedAllocator<U> const& y) {
    return !(x == y);
 }
 template <class T>
 class NullAllocator
 {
 public:
    typedef T value_type;
    typedef T* pointer;
    NullAllocator() = delete;
    explicit NullAllocator(AllocController& PP) : P(&PP) {}
    NullAllocator(NullAllocator const& other) : P(other.P) {
        P->copy_constructed += 1;
    }
    NullAllocator(NullAllocator&& other) : P(other.P) {
        P->move_constructed += 1;
    }
    template <class U>
    NullAllocator(NullAllocator<U> const& other) TEST_NOEXCEPT : P(other.P) {
        P->copy_constructed += 1;
    }
    template <class U>
    NullAllocator(NullAllocator<U>&& other) TEST_NOEXCEPT : P(other.P) {
        P->move_constructed += 1;
    }
    T* allocate(std::size_t n)
    {
        P->countAlloc(nullptr, n*sizeof(T), alignof(T));
        return nullptr;
    }
    void deallocate(T* p, std::size_t n)
    {
        void* vp = static_cast<void*>(p);
        P->countDealloc(vp, n*sizeof(T), alignof(T));
    }
    AllocController& getController() const { return *P; }
 private:
    template <class Tp> friend class NullAllocator;
    AllocController *P;
 };
 template <class T, class U>
 inline bool operator==(NullAllocator<T> const& x,
                       NullAllocator<U> const& y) {
    return &x.getController() == &y.getController();
 }
 template <class T, class U>
 inline bool operator!=(NullAllocator<T> const& x,
                       NullAllocator<U> const& y) {
    return !(x == y);
 }
 template <class ProviderT, int = 0>
 class TestResourceImp : public std::experimental::pmr::memory_resource
 {
--- a/test/support/type_id.h
+++ b/test/support/type_id.h
@@ -10,9 +10,13 @@
 #define SUPPORT_TYPE_ID_H
 #include <functional>
 #include <typeinfo>
 #include <string>
 #include <cstdio>
 #include <cassert>
 #include "test_macros.h"
 #include "demangle.h"
 #if TEST_STD_VER < 11
 #error This header requires C++11 or greater
@@ -25,25 +29,41 @@ struct TypeID {
  {return LHS.m_id == RHS.m_id; }
  friend bool operator!=(TypeID const& LHS, TypeID const& RHS)
  {return LHS.m_id != RHS.m_id; }
  std::string name() const {
    return demangle(m_id);
  }
  void dump() const {
    std::string s = name();
    std::printf("TypeID: %s\n", s.c_str());
  }
 private:
-  explicit constexpr TypeID(const int* xid) : m_id(xid) {}
+  explicit constexpr TypeID(const char* xid) : m_id(xid) {}
  TypeID(const TypeID&) = delete;
  TypeID& operator=(TypeID const&) = delete;
-  const int* const m_id;
+  const char* const m_id;
-  template <class T> friend TypeID const& makeTypeID();
+  template <class T> friend TypeID const& makeTypeIDImp();
 };
 // makeTypeID - Return the TypeID for the specified type 'T'.
 template <class T>
-inline TypeID const& makeTypeID() {
+inline TypeID const& makeTypeIDImp() {
-  static int dummy;
+  static const TypeID id(typeid(T).name());
  static const TypeID id(&dummy);
  return id;
 }
 template <class T>
 struct TypeWrapper {};
 template <class T>
 inline  TypeID const& makeTypeID() {
  return makeTypeIDImp<TypeWrapper<T>>();
 }
 template <class ...Args>
 struct ArgumentListID {};
@@ -51,7 +71,23 @@ struct ArgumentListID {};
 // of arguments.
 template <class ...Args>
 inline  TypeID const& makeArgumentID() {
-  return makeTypeID<ArgumentListID<Args...>>();
+  return makeTypeIDImp<ArgumentListID<Args...>>();
 }
 // COMPARE_TYPEID(...) is a utility macro for generating diagnostics when
 // two typeid's are expected to be equal
 #define COMPARE_TYPEID(LHS, RHS) CompareTypeIDVerbose(#LHS, LHS, #RHS, RHS)
 inline bool CompareTypeIDVerbose(const char* LHSString, TypeID const* LHS,
                                 const char* RHSString, TypeID const* RHS) {
  if (*LHS == *RHS)
    return true;
  std::printf("TypeID's not equal:\n");
  std::printf("%s: %s\n----------\n%s: %s\n",
              LHSString, LHS->name().c_str(),
              RHSString, RHS->name().c_str());
  return false;
 }
 #endif // SUPPORT_TYPE_ID_H
--- a/test/support/uses_alloc_types.hpp
+++ b/test/support/uses_alloc_types.hpp
@@ -10,12 +10,11 @@
 #ifndef USES_ALLOC_TYPES_HPP
 #define USES_ALLOC_TYPES_HPP
 # include <experimental/memory_resource>
 # include <experimental/utility>
 # include <memory>
 # include <cassert>
 #include <cstdlib>
-#include "test_memory_resource.hpp"
+#include "test_macros.h"
 #include "type_id.h"
 // There are two forms of uses-allocator construction:
@@ -31,6 +30,30 @@ constexpr UsesAllocatorType UA_None = UsesAllocatorType::UA_None;
 constexpr UsesAllocatorType UA_AllocArg = UsesAllocatorType::UA_AllocArg;
 constexpr UsesAllocatorType UA_AllocLast = UsesAllocatorType::UA_AllocLast;
 inline const char* toString(UsesAllocatorType UA) {
    switch (UA) {
    case UA_None:
        return "UA_None";
    case UA_AllocArg:
        return "UA_AllocArg";
    case UA_AllocLast:
        return "UA_AllocLast";
    default:
    std::abort();
    }
 }
 #define COMPARE_ALLOC_TYPE(LHS, RHS) CompareVerbose(#LHS, LHS, #RHS, RHS)
 inline bool CompareVerbose(const char* LHSString, UsesAllocatorType LHS,
                           const char* RHSString, UsesAllocatorType RHS) {
    if (LHS == RHS)
        return true;
    std::printf("UsesAllocatorType's don't match:\n%s %s\n----------\n%s %s\n",
                LHSString, toString(LHS), RHSString, toString(RHS));
    return false;
 }
 template <class Alloc, std::size_t N>
 class UsesAllocatorV1;
    // Implements form (1) of uses-allocator construction from the specified
@@ -115,66 +138,107 @@ using EnableIfB = typename std::enable_if<Value, bool>::type;
 } // end namespace detail
 // FIXME: UsesAllocatorTestBase needs some special logic to deal with
 // polymorphic allocators. However we don't want to include
 // <experimental/memory_resource> in this header. Therefore in order
 // to inject this behavior later we use a trait.
 // See test_memory_resource.hpp for more info.
 template <class Alloc>
 struct TransformErasedTypeAlloc {
  using type = Alloc;
 };
 using detail::EnableIfB;
 struct AllocLastTag {};
 template <class Alloc, bool = std::is_default_constructible<Alloc>::value>
 struct UsesAllocatorTestBaseStorage {
    Alloc allocator;
    UsesAllocatorTestBaseStorage() = default;
    UsesAllocatorTestBaseStorage(Alloc const& a) : allocator(a) {}
    const Alloc* get_allocator() const { return &allocator; }
 };
 template <class Alloc>
 struct UsesAllocatorTestBaseStorage<Alloc, false> {
  union {
    char dummy;
    Alloc alloc;
  };
  bool has_alloc = false;
  UsesAllocatorTestBaseStorage() : dummy(), has_alloc(false) {}
  UsesAllocatorTestBaseStorage(Alloc const& a) : alloc(a), has_alloc(true) {}
  ~UsesAllocatorTestBaseStorage() {
      if (has_alloc)
          alloc.~Alloc();
  }
  Alloc const* get_allocator() const {
      if (!has_alloc)
          return nullptr;
      return &alloc;
  }
 };
 template <class Self, class Alloc>
 struct UsesAllocatorTestBase {
 public:
-    using CtorAlloc = typename std::conditional<
+    using CtorAlloc = typename TransformErasedTypeAlloc<Alloc>::type;
        std::is_same<Alloc, std::experimental::erased_type>::value,
        std::experimental::pmr::memory_resource*,
        Alloc
    >::type;
    template <class ...ArgTypes>
    bool checkConstruct(UsesAllocatorType expectType) const {
-        return expectType == constructor_called &&
+        auto expectArgs = &makeArgumentID<ArgTypes...>();
-               makeArgumentID<ArgTypes...>() == *args_id;
+        return COMPARE_ALLOC_TYPE(expectType, constructor_called) &&
               COMPARE_TYPEID(args_id, expectArgs);
    }
    template <class ...ArgTypes>
    bool checkConstruct(UsesAllocatorType expectType,
                        CtorAlloc const& expectAlloc) const {
-        return expectType == constructor_called &&
+        auto ExpectID = &makeArgumentID<ArgTypes...>() ;
-               makeArgumentID<ArgTypes...>() == *args_id &&
+        return COMPARE_ALLOC_TYPE(expectType, constructor_called) &&
-               expectAlloc == allocator;
+               COMPARE_TYPEID(args_id, ExpectID) &&
               has_alloc() && expectAlloc == *get_alloc();
    }
    bool checkConstructEquiv(UsesAllocatorTestBase& O) const {
-        return constructor_called == O.constructor_called
+        if (has_alloc() != O.has_alloc())
-            && *args_id == *O.args_id
+            return false;
-            && allocator == O.allocator;
+        return COMPARE_ALLOC_TYPE(constructor_called, O.constructor_called)
            && COMPARE_TYPEID(args_id, O.args_id)
            && (!has_alloc() || *get_alloc() == *O.get_alloc());
    }
 protected:
    explicit UsesAllocatorTestBase(const TypeID* aid)
-        : args_id(aid), constructor_called(UA_None), allocator()
+        : args_id(aid), constructor_called(UA_None), alloc_store()
    {}
    UsesAllocatorTestBase(UsesAllocatorTestBase const&)
        : args_id(&makeArgumentID<Self const&>()), constructor_called(UA_None),
-          allocator()
+          alloc_store()
    {}
    UsesAllocatorTestBase(UsesAllocatorTestBase&&)
        : args_id(&makeArgumentID<Self&&>()), constructor_called(UA_None),
-          allocator()
+          alloc_store()
    {}
    template <class ...Args>
    UsesAllocatorTestBase(std::allocator_arg_t, CtorAlloc const& a, Args&&...)
        : args_id(&makeArgumentID<Args&&...>()),
          constructor_called(UA_AllocArg),
-          allocator(a)
+          alloc_store(a)
    {}
    template <class ...Args, class ArgsIDL = detail::TakeNArgs<sizeof...(Args) - 1, Args&&...>>
    UsesAllocatorTestBase(AllocLastTag, Args&&... args)
-        : args_id(&makeTypeID<typename ArgsIDL::type>()),
+        : args_id(&makeTypeIDImp<typename ArgsIDL::type>()),
          constructor_called(UA_AllocLast),
-          allocator(getAllocatorFromPack(
+          alloc_store(UsesAllocatorTestBase::getAllocatorFromPack(
            typename ArgsIDL::type{},
            std::forward<Args>(args)...))
    {
@@ -183,7 +247,7 @@ protected:
 private:
    template <class ...LArgs, class ...Args>
    static CtorAlloc getAllocatorFromPack(ArgumentListID<LArgs...>, Args&&... args) {
-        return getAllocatorFromPackImp<LArgs const&...>(args...);
+        return UsesAllocatorTestBase::getAllocatorFromPackImp<LArgs const&...>(args...);
    }
    template <class ...LArgs>
@@ -191,10 +255,13 @@ private:
        typename detail::Identity<LArgs>::type..., CtorAlloc const& alloc) {
        return alloc;
    }
    bool has_alloc() const { return alloc_store.get_allocator() != nullptr; }
    const CtorAlloc *get_alloc() const { return alloc_store.get_allocator(); }
 public:
    const TypeID* args_id;
    UsesAllocatorType constructor_called = UA_None;
-    CtorAlloc allocator;
+    UsesAllocatorTestBaseStorage<CtorAlloc> alloc_store;
 };
 template <class Alloc, size_t Arity>