libstdc++-v3/testsuite/20_util/synchronized_pool_resource/allocate.cc - gcc - Git at Google

 // Copyright (C) 2018-2023 Free Software Foundation, Inc.
 //
 // This file is part of the GNU ISO C++ Library.  This library is free
 // software; you can redistribute it and/or modify it under the
 // terms of the GNU General Public License as published by the
 // Free Software Foundation; either version 3, or (at your option)
 // any later version.

 // This library is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.

 // You should have received a copy of the GNU General Public License along
 // with this library; see the file COPYING3.  If not see
 // <http://www.gnu.org/licenses/>.

 // { dg-do run }
 // { dg-options "-pthread" }
 // { dg-require-effective-target c++17 }
 // { dg-require-effective-target pthread }
 // { dg-require-gthreads "" }

 #include <memory_resource>
 #include <cstring>
 #include <testsuite_allocator.h>
 #include <testsuite_hooks.h>

 void
 test01()
 {
   __gnu_test::memory_resource test_mr;
   {
     std::pmr::synchronized_pool_resource r(&test_mr);
     void* p1 = r.allocate(1, 1);
     VERIFY( p1 != nullptr );
     auto n = test_mr.number_of_active_allocations();
     VERIFY( n > 0 );
     // Ensure memory region can be written to (without corrupting heap!)
     std::memset(p1, 0xff, 1);
     void* p2 = r.allocate(1, 1);
     VERIFY( p2 != nullptr );
     VERIFY( p2 != p1 );
     VERIFY( test_mr.number_of_active_allocations() == n );
     std::memset(p1, 0xff, 1);
     r.deallocate(p1, 1, 1);
     // Returning single blocks to the pool doesn't return them upstream:
     VERIFY( test_mr.number_of_active_allocations() == n );
     r.deallocate(p2, 1, 1);
     VERIFY( test_mr.number_of_active_allocations() == n );
   }
   VERIFY( test_mr.number_of_active_allocations() == 0 );
 }

 void
 test02()
 {
   struct nullable_memory_resource : public std::pmr::memory_resource
   {
     void*
     do_allocate(std::size_t bytes, std::size_t alignment) override
     { return upstream->allocate(bytes, alignment); }

     void
     do_deallocate(void* p, std::size_t bytes, std::size_t alignment) override
     { upstream->deallocate(p, bytes, alignment); }

     bool
     do_is_equal(const memory_resource& r) const noexcept override
     { return &r == this; }

     std::pmr::memory_resource* upstream = std::pmr::get_default_resource();
   };

   nullable_memory_resource test_mr;
   std::pmr::synchronized_pool_resource r(&test_mr);
   void* p1 = r.allocate(8, 1);
   VERIFY( p1 != nullptr );
   std::memset(p1, 0xff, 8);
   test_mr.upstream = nullptr;
   void* p2 = r.allocate(8, 1); //should not need to replenish
   VERIFY( p2 != nullptr );
   VERIFY( p2 != p1 );
   std::memset(p1, 0xff, 8);
   r.deallocate(p1, 8, 1); // should not use upstream
   r.deallocate(p2, 8, 1); // should not use upstream

   // Destructor will return memory upstream, so restore the upstream resource:
   test_mr.upstream = std::pmr::get_default_resource();
 }

 void
 test03()
 {
   __gnu_test::memory_resource test_mr;
   {
     std::pmr::synchronized_pool_resource r({10, 16}, &test_mr);
     std::size_t largest_pool = r.options().largest_required_pool_block;
     void* p1 = r.allocate(2 * largest_pool);
     VERIFY( p1 != nullptr );
     const std::size_t n = test_mr.number_of_active_allocations();
     // Allocation of pools + allocation of pmr::vector + oversize allocation:
     VERIFY( n >= 1 );
     std::memset(p1, 0xff, 2 * largest_pool);
     void* p2 = r.allocate(3 * largest_pool);
     VERIFY( p2 != nullptr );
     VERIFY( p2 != p1 );
     VERIFY( test_mr.number_of_active_allocations() == n + 1 );
     std::memset(p2, 0xff, 3 * largest_pool);
     r.deallocate(p1, 2 * largest_pool);
     VERIFY( test_mr.number_of_active_allocations() ==  n );
     r.deallocate(p2, 3 * largest_pool);
     VERIFY( test_mr.number_of_active_allocations() == n - 1 );
   }
   VERIFY( test_mr.number_of_active_allocations() == 0 );
   {
     std::pmr::synchronized_pool_resource r({16, 16}, &test_mr);
     (void) r.allocate(2);
     (void) r.allocate(8);
     (void) r.allocate(16);
     (void) r.allocate(2);
     (void) r.allocate(8);
     (void) r.allocate(16);
     (void) r.allocate(2 * r.options().largest_required_pool_block);
     VERIFY( test_mr.number_of_active_allocations() != 0 );
     // Destructor calls release()
   }
   VERIFY( test_mr.number_of_active_allocations() == 0 );
 }

 void
 test04()
 {
   __gnu_test::memory_resource test_mr;
   std::pmr::synchronized_pool_resource r({256, 256}, &test_mr);
   // Check alignment
   void* p1 = r.allocate(2, 64);
   VERIFY( (std::uintptr_t)p1 % 64 == 0 );
   void* p2 = r.allocate(2, 128);
   VERIFY( (std::uintptr_t)p2 % 128 == 0 );
   void* p3 = r.allocate(2, 256);
   VERIFY( (std::uintptr_t)p3 % 256 == 0 );
   const std::size_t largest_pool = r.options().largest_required_pool_block;
   void* p4 = r.allocate(2 * largest_pool, 1024);
   VERIFY( (std::uintptr_t)p4 % 1024 == 0 );
   r.deallocate(p1, 2, 64);
   r.deallocate(p2, 2, 128);
   r.deallocate(p3, 2, 256);
   r.deallocate(p4, 2 * largest_pool, 1024);
 }

 int
 main()
 {
   test01();
   test02();
   test03();
   test04();
 }
	// Copyright (C) 2018-2023 Free Software Foundation, Inc.
	//
	// This file is part of the GNU ISO C++ Library. This library is free
	// software; you can redistribute it and/or modify it under the
	// terms of the GNU General Public License as published by the
	// Free Software Foundation; either version 3, or (at your option)
	// any later version.

	// This library is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.

	// You should have received a copy of the GNU General Public License along
	// with this library; see the file COPYING3. If not see
	// <http://www.gnu.org/licenses/>.

	// { dg-do run }
	// { dg-options "-pthread" }
	// { dg-require-effective-target c++17 }
	// { dg-require-effective-target pthread }
	// { dg-require-gthreads "" }

	#include <memory_resource>
	#include <cstring>
	#include <testsuite_allocator.h>
	#include <testsuite_hooks.h>

	void
	test01()
	{
	__gnu_test::memory_resource test_mr;
	{
	std::pmr::synchronized_pool_resource r(&test_mr);
	void* p1 = r.allocate(1, 1);
	VERIFY( p1 != nullptr );
	auto n = test_mr.number_of_active_allocations();
	VERIFY( n > 0 );
	// Ensure memory region can be written to (without corrupting heap!)
	std::memset(p1, 0xff, 1);
	void* p2 = r.allocate(1, 1);
	VERIFY( p2 != nullptr );
	VERIFY( p2 != p1 );
	VERIFY( test_mr.number_of_active_allocations() == n );
	std::memset(p1, 0xff, 1);
	r.deallocate(p1, 1, 1);
	// Returning single blocks to the pool doesn't return them upstream:
	VERIFY( test_mr.number_of_active_allocations() == n );
	r.deallocate(p2, 1, 1);
	VERIFY( test_mr.number_of_active_allocations() == n );
	}
	VERIFY( test_mr.number_of_active_allocations() == 0 );
	}

	void
	test02()
	{
	struct nullable_memory_resource : public std::pmr::memory_resource
	{
	void*
	do_allocate(std::size_t bytes, std::size_t alignment) override
	{ return upstream->allocate(bytes, alignment); }

	void
	do_deallocate(void* p, std::size_t bytes, std::size_t alignment) override
	{ upstream->deallocate(p, bytes, alignment); }

	bool
	do_is_equal(const memory_resource& r) const noexcept override
	{ return &r == this; }

	std::pmr::memory_resource* upstream = std::pmr::get_default_resource();
	};

	nullable_memory_resource test_mr;
	std::pmr::synchronized_pool_resource r(&test_mr);
	void* p1 = r.allocate(8, 1);
	VERIFY( p1 != nullptr );
	std::memset(p1, 0xff, 8);
	test_mr.upstream = nullptr;
	void* p2 = r.allocate(8, 1); //should not need to replenish
	VERIFY( p2 != nullptr );
	VERIFY( p2 != p1 );
	std::memset(p1, 0xff, 8);
	r.deallocate(p1, 8, 1); // should not use upstream
	r.deallocate(p2, 8, 1); // should not use upstream

	// Destructor will return memory upstream, so restore the upstream resource:
	test_mr.upstream = std::pmr::get_default_resource();
	}

	void
	test03()
	{
	__gnu_test::memory_resource test_mr;
	{
	std::pmr::synchronized_pool_resource r({10, 16}, &test_mr);
	std::size_t largest_pool = r.options().largest_required_pool_block;
	void* p1 = r.allocate(2 * largest_pool);
	VERIFY( p1 != nullptr );
	const std::size_t n = test_mr.number_of_active_allocations();
	// Allocation of pools + allocation of pmr::vector + oversize allocation:
	VERIFY( n >= 1 );
	std::memset(p1, 0xff, 2 * largest_pool);
	void* p2 = r.allocate(3 * largest_pool);
	VERIFY( p2 != nullptr );
	VERIFY( p2 != p1 );
	VERIFY( test_mr.number_of_active_allocations() == n + 1 );
	std::memset(p2, 0xff, 3 * largest_pool);
	r.deallocate(p1, 2 * largest_pool);
	VERIFY( test_mr.number_of_active_allocations() == n );
	r.deallocate(p2, 3 * largest_pool);
	VERIFY( test_mr.number_of_active_allocations() == n - 1 );
	}
	VERIFY( test_mr.number_of_active_allocations() == 0 );
	{
	std::pmr::synchronized_pool_resource r({16, 16}, &test_mr);
	(void) r.allocate(2);
	(void) r.allocate(8);
	(void) r.allocate(16);
	(void) r.allocate(2);
	(void) r.allocate(8);
	(void) r.allocate(16);
	(void) r.allocate(2 * r.options().largest_required_pool_block);
	VERIFY( test_mr.number_of_active_allocations() != 0 );
	// Destructor calls release()
	}
	VERIFY( test_mr.number_of_active_allocations() == 0 );
	}

	void
	test04()
	{
	__gnu_test::memory_resource test_mr;
	std::pmr::synchronized_pool_resource r({256, 256}, &test_mr);
	// Check alignment
	void* p1 = r.allocate(2, 64);
	VERIFY( (std::uintptr_t)p1 % 64 == 0 );
	void* p2 = r.allocate(2, 128);
	VERIFY( (std::uintptr_t)p2 % 128 == 0 );
	void* p3 = r.allocate(2, 256);
	VERIFY( (std::uintptr_t)p3 % 256 == 0 );
	const std::size_t largest_pool = r.options().largest_required_pool_block;
	void* p4 = r.allocate(2 * largest_pool, 1024);
	VERIFY( (std::uintptr_t)p4 % 1024 == 0 );
	r.deallocate(p1, 2, 64);
	r.deallocate(p2, 2, 128);
	r.deallocate(p3, 2, 256);
	r.deallocate(p4, 2 * largest_pool, 1024);
	}

	int
	main()
	{
	test01();
	test02();
	test03();
	test04();
	}