////////////////////////////////////////////////////////////////////////////// // // (C) Copyright Ion Gaztanaga 2006-2012. Distributed under the Boost // Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // // See http://www.boost.org/libs/interprocess for documentation. // ////////////////////////////////////////////////////////////////////////////// #ifndef BOOST_INTERPROCESS_TEST_MEMORY_ALGORITHM_TEST_TEMPLATE_HEADER #define BOOST_INTERPROCESS_TEST_MEMORY_ALGORITHM_TEST_TEMPLATE_HEADER #include #include #include #include #include //std::nothrow #include //std::memset namespace boost { namespace interprocess { namespace test { enum deallocation_type { DirectDeallocation, InverseDeallocation, MixedDeallocation, EndDeallocationType }; //This test allocates until there is no more memory //and after that deallocates all in the inverse order template bool test_allocation(Allocator &a) { for( deallocation_type t = DirectDeallocation ; t != EndDeallocationType ; t = (deallocation_type)((int)t + 1)){ std::vector buffers; typename Allocator::size_type free_memory = a.get_free_memory(); for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } switch(t){ case DirectDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ a.deallocate(buffers[j]); } } break; case InverseDeallocation: { for(int j = (int)buffers.size() ;j-- ;){ a.deallocate(buffers[j]); } } break; case MixedDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } } break; default: break; } bool ok = free_memory == a.get_free_memory() && a.all_memory_deallocated() && a.check_sanity(); if(!ok) return ok; } return true; } //This test allocates until there is no more memory //and after that tries to shrink all the buffers to the //half of the original size template bool test_allocation_shrink(Allocator &a) { std::vector buffers; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i*2, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } //Now shrink to half for(int i = 0, max = (int)buffers.size() ;i < max ; ++i){ typename Allocator::size_type received_size; char *reuse = static_cast(buffers[i]); if(a.template allocation_command ( boost::interprocess::shrink_in_place | boost::interprocess::nothrow_allocation, i*2 , received_size = i, reuse)){ if(received_size > std::size_t(i*2)){ return false; } if(received_size < std::size_t(i)){ return false; } std::memset(buffers[i], 0, a.size(buffers[i])); } } //Deallocate it in non sequential order for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates until there is no more memory //and after that tries to expand all the buffers to //avoid the wasted internal fragmentation template bool test_allocation_expand(Allocator &a) { std::vector buffers; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } //Now try to expand to the double of the size for(int i = 0, max = (int)buffers.size() ;i < max ;++i){ typename Allocator::size_type received_size; std::size_t min_size = i+1; std::size_t preferred_size = i*2; preferred_size = min_size > preferred_size ? min_size : preferred_size; char *reuse = static_cast(buffers[i]); while(a.template allocation_command ( boost::interprocess::expand_fwd | boost::interprocess::nothrow_allocation, min_size , received_size = preferred_size, reuse)){ //Check received size is bigger than minimum if(received_size < min_size){ return false; } //Now, try to expand further min_size = received_size+1; preferred_size = min_size*2; } } //Deallocate it in non sequential order for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates until there is no more memory //and after that tries to expand all the buffers to //avoid the wasted internal fragmentation template bool test_allocation_shrink_and_expand(Allocator &a) { std::vector buffers; std::vector received_sizes; std::vector size_reduced; //Allocate buffers wand store received sizes for(int i = 0; true; ++i){ typename Allocator::size_type received_size; char *reuse = 0; void *ptr = a.template allocation_command ( boost::interprocess::allocate_new | boost::interprocess::nothrow_allocation, i, received_size = i*2, reuse); if(!ptr){ ptr = a.template allocation_command ( boost::interprocess::allocate_new | boost::interprocess::nothrow_allocation, 1, received_size = i*2, reuse); if(!ptr) break; } buffers.push_back(ptr); received_sizes.push_back(received_size); } //Now shrink to half for(int i = 0, max = (int)buffers.size() ; i < max ; ++i){ typename Allocator::size_type received_size; char *reuse = static_cast(buffers[i]); if(a.template allocation_command ( boost::interprocess::shrink_in_place | boost::interprocess::nothrow_allocation, received_sizes[i] , received_size = i, reuse)){ if(received_size > std::size_t(received_sizes[i])){ return false; } if(received_size < std::size_t(i)){ return false; } size_reduced.push_back(received_size != received_sizes[i]); } } //Now try to expand to the original size for(int i = 0, max = (int)buffers.size() ;i < max ;++i){ typename Allocator::size_type received_size; std::size_t request_size = received_sizes[i]; char *reuse = static_cast(buffers[i]); if(a.template allocation_command ( boost::interprocess::expand_fwd | boost::interprocess::nothrow_allocation, request_size , received_size = request_size, reuse)){ if(received_size != received_sizes[i]){ return false; } } else{ return false; } } //Deallocate it in non sequential order for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates until there is no more memory //and after that deallocates the odd buffers to //make room for expansions. The expansion will probably //success since the deallocation left room for that. template bool test_allocation_deallocation_expand(Allocator &a) { std::vector buffers; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } //Now deallocate the half of the blocks //so expand maybe can merge new free blocks for(int i = 0, max = (int)buffers.size() ;i < max ;++i){ if(i%2){ a.deallocate(buffers[i]); buffers[i] = 0; } } //Now try to expand to the double of the size for(int i = 0, max = (int)buffers.size() ;i < max ;++i){ // if(buffers[i]){ typename Allocator::size_type received_size; std::size_t min_size = i+1; std::size_t preferred_size = i*2; preferred_size = min_size > preferred_size ? min_size : preferred_size; char *reuse = static_cast(buffers[i]); while(a.template allocation_command ( boost::interprocess::expand_fwd | boost::interprocess::nothrow_allocation, min_size , received_size = preferred_size, reuse)){ //Check received size is bigger than minimum if(received_size < min_size){ return false; } //Now, try to expand further min_size = received_size+1; preferred_size = min_size*2; } } } //Now erase null values from the vector buffers.erase( std::remove(buffers.begin(), buffers.end(), static_cast(0)) , buffers.end()); //Deallocate it in non sequential order for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates until there is no more memory //and after that deallocates all except the last. //If the allocation algorithm is a bottom-up algorithm //the last buffer will be in the end of the segment. //Then the test will start expanding backwards, until //the buffer fills all the memory template bool test_allocation_with_reuse(Allocator &a) { //We will repeat this test for different sized elements for(int sizeof_object = 1; sizeof_object < 20; ++sizeof_object){ std::vector buffers; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i*sizeof_object, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } //Now deallocate all except the latest //Now try to expand to the double of the sizeof_object for(int i = 0, max = (int)buffers.size() - 1 ;i < max ;++i){ a.deallocate(buffers[i]); } //Save the unique buffer and clear vector void *ptr = buffers.back(); buffers.clear(); //Now allocate with reuse typename Allocator::size_type received_size = 0; for(int i = 0; true; ++i){ std::size_t min_size = (received_size + 1); std::size_t prf_size = (received_size + (i+1)*2); void *reuse = ptr; void *ret = a.raw_allocation_command ( boost::interprocess::expand_bwd | boost::interprocess::nothrow_allocation, min_size , received_size = prf_size, reuse, sizeof_object); if(!ret) break; //If we have memory, this must be a buffer reuse if(!reuse) return 1; if(received_size < min_size) return 1; ptr = ret; } //There is only a single block so deallocate it a.deallocate(ptr); if(!a.all_memory_deallocated() || !a.check_sanity()) return false; } return true; } //This test allocates memory with different alignments //and checks returned memory is aligned. template bool test_aligned_allocation(Allocator &a) { //Allocate aligned buffers in a loop //and then deallocate it bool continue_loop = true; for(unsigned int i = 1; continue_loop; i <<= 1){ for(unsigned int j = 1; true; j <<= 1){ void *ptr = a.allocate_aligned(i-1, j, std::nothrow); if(!ptr){ if(j == 1) continue_loop = false; break; } if(((std::size_t)ptr & (j - 1)) != 0) return false; a.deallocate(ptr); if(!a.all_memory_deallocated() || !a.check_sanity()){ return false; } } } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates memory with different alignments //and checks returned memory is aligned. template bool test_continuous_aligned_allocation(Allocator &a) { std::vector buffers; //Allocate aligned buffers in a loop //and then deallocate it bool continue_loop = true; for(unsigned i = 1; continue_loop && i; i <<= 1){ for(unsigned int j = 1; j; j <<= 1){ for(bool any_allocated = false; 1;){ void *ptr = a.allocate_aligned(i-1, j, std::nothrow); buffers.push_back(ptr); if(!ptr){ if(j == 1 && !any_allocated){ continue_loop = false; } break; } else{ any_allocated = true; } if(((std::size_t)ptr & (j - 1)) != 0) return false; } //Deallocate all for(unsigned int k = (int)buffers.size(); k--;){ a.deallocate(buffers[k]); } buffers.clear(); if(!a.all_memory_deallocated() && a.check_sanity()) return false; if(!continue_loop) break; } } return a.all_memory_deallocated() && a.check_sanity(); } //This test allocates memory, writes it with a non-zero value and //tests zero_free_memory initializes to zero for the next allocation template bool test_clear_free_memory(Allocator &a) { std::vector buffers; //Allocate memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 1, size); buffers.push_back(ptr); } //Mark it for(int i = 0, max = buffers.size(); i < max; ++i){ std::memset(buffers[i], 1, i); } //Deallocate all for(int j = (int)buffers.size() ;j-- ;){ a.deallocate(buffers[j]); } buffers.clear(); if(!a.all_memory_deallocated() && a.check_sanity()) return false; //Now clear all free memory a.zero_free_memory(); if(!a.all_memory_deallocated() && a.check_sanity()) return false; //Now test all allocated memory is zero //Allocate memory const char *first_addr = 0; for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; if(i == 0){ first_addr = (char*)ptr; } std::size_t memsize = a.size(ptr); buffers.push_back(ptr); for(int j = 0; j < (int)memsize; ++j){ if(static_cast((char*)ptr)[j]){ std::cout << "Zero memory test failed. in buffer " << i << " byte " << j << " first address " << (void*) first_addr << " offset " << ((char*)ptr+j) - (char*)first_addr << " memsize: " << memsize << std::endl; return false; } } } //Deallocate all for(int j = (int)buffers.size() ;j-- ;){ a.deallocate(buffers[j]); } if(!a.all_memory_deallocated() && a.check_sanity()) return false; return true; } //This test uses tests grow and shrink_to_fit functions template bool test_grow_shrink_to_fit(Allocator &a) { std::vector buffers; typename Allocator::size_type original_size = a.get_size(); typename Allocator::size_type original_free = a.get_free_memory(); a.shrink_to_fit(); if(!a.all_memory_deallocated() && a.check_sanity()) return false; typename Allocator::size_type shrunk_size = a.get_size(); typename Allocator::size_type shrunk_free_memory = a.get_free_memory(); if(shrunk_size != a.get_min_size()) return 1; a.grow(original_size - shrunk_size); if(!a.all_memory_deallocated() && a.check_sanity()) return false; if(original_size != a.get_size()) return false; if(original_free != a.get_free_memory()) return false; //Allocate memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers.push_back(ptr); } //Now deallocate the half of the blocks //so expand maybe can merge new free blocks for(int i = 0, max = (int)buffers.size() ;i < max ;++i){ if(i%2){ a.deallocate(buffers[i]); buffers[i] = 0; } } //Deallocate the rest of the blocks //Deallocate it in non sequential order for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%5)*((int)buffers.size())/4; if(pos == int(buffers.size())) --pos; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); typename Allocator::size_type old_free = a.get_free_memory(); a.shrink_to_fit(); if(!a.check_sanity()) return false; if(original_size < a.get_size()) return false; if(old_free < a.get_free_memory()) return false; a.grow(original_size - a.get_size()); if(!a.check_sanity()) return false; if(original_size != a.get_size()) return false; if(old_free != a.get_free_memory()) return false; } //Now shrink it to the maximum a.shrink_to_fit(); if(a.get_size() != a.get_min_size()) return 1; if(shrunk_free_memory != a.get_free_memory()) return 1; if(!a.all_memory_deallocated() && a.check_sanity()) return false; a.grow(original_size - shrunk_size); if(original_size != a.get_size()) return false; if(original_free != a.get_free_memory()) return false; if(!a.all_memory_deallocated() && a.check_sanity()) return false; return true; } //This test allocates multiple values until there is no more memory //and after that deallocates all in the inverse order template bool test_many_equal_allocation(Allocator &a) { for( deallocation_type t = DirectDeallocation ; t != EndDeallocationType ; t = (deallocation_type)((int)t + 1)){ typename Allocator::size_type free_memory = a.get_free_memory(); std::vector buffers2; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); if(!a.check_sanity()) return false; buffers2.push_back(ptr); } //Now deallocate the half of the blocks //so expand maybe can merge new free blocks for(int i = 0, max = (int)buffers2.size() ;i < max ;++i){ if(i%2){ a.deallocate(buffers2[i]); buffers2[i] = 0; } } if(!a.check_sanity()) return false; typedef typename Allocator::multiallocation_chain multiallocation_chain; std::vector buffers; for(int i = 0; true; ++i){ multiallocation_chain chain; a.allocate_many(std::nothrow, i+1, (i+1)*2, chain); if(chain.empty()) break; typename multiallocation_chain::size_type n = chain.size(); while(!chain.empty()){ buffers.push_back(ipcdetail::to_raw_pointer(chain.pop_front())); } if(n != std::size_t((i+1)*2)) return false; } if(!a.check_sanity()) return false; switch(t){ case DirectDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ a.deallocate(buffers[j]); } } break; case InverseDeallocation: { for(int j = (int)buffers.size() ;j-- ;){ a.deallocate(buffers[j]); } } break; case MixedDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } } break; default: break; } //Deallocate the rest of the blocks //Deallocate it in non sequential order for(int j = 0, max = (int)buffers2.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers2.size())/4; a.deallocate(buffers2[pos]); buffers2.erase(buffers2.begin()+pos); } bool ok = free_memory == a.get_free_memory() && a.all_memory_deallocated() && a.check_sanity(); if(!ok) return ok; } return true; } //This test allocates multiple values until there is no more memory //and after that deallocates all in the inverse order template bool test_many_different_allocation(Allocator &a) { typedef typename Allocator::multiallocation_chain multiallocation_chain; const std::size_t ArraySize = 11; typename Allocator::size_type requested_sizes[ArraySize]; for(std::size_t i = 0; i < ArraySize; ++i){ requested_sizes[i] = 4*i; } for( deallocation_type t = DirectDeallocation ; t != EndDeallocationType ; t = (deallocation_type)((int)t + 1)){ typename Allocator::size_type free_memory = a.get_free_memory(); std::vector buffers2; //Allocate buffers with extra memory for(int i = 0; true; ++i){ void *ptr = a.allocate(i, std::nothrow); if(!ptr) break; std::size_t size = a.size(ptr); std::memset(ptr, 0, size); buffers2.push_back(ptr); } //Now deallocate the half of the blocks //so expand maybe can merge new free blocks for(int i = 0, max = (int)buffers2.size() ;i < max ;++i){ if(i%2){ a.deallocate(buffers2[i]); buffers2[i] = 0; } } std::vector buffers; for(int i = 0; true; ++i){ multiallocation_chain chain; a.allocate_many(std::nothrow, requested_sizes, ArraySize, 1, chain); if(chain.empty()) break; typename multiallocation_chain::size_type n = chain.size(); while(!chain.empty()){ buffers.push_back(ipcdetail::to_raw_pointer(chain.pop_front())); } if(n != ArraySize) return false; } switch(t){ case DirectDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ a.deallocate(buffers[j]); } } break; case InverseDeallocation: { for(int j = (int)buffers.size() ;j-- ;){ a.deallocate(buffers[j]); } } break; case MixedDeallocation: { for(int j = 0, max = (int)buffers.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers.size())/4; a.deallocate(buffers[pos]); buffers.erase(buffers.begin()+pos); } } break; default: break; } //Deallocate the rest of the blocks //Deallocate it in non sequential order for(int j = 0, max = (int)buffers2.size() ;j < max ;++j){ int pos = (j%4)*((int)buffers2.size())/4; a.deallocate(buffers2[pos]); buffers2.erase(buffers2.begin()+pos); } bool ok = free_memory == a.get_free_memory() && a.all_memory_deallocated() && a.check_sanity(); if(!ok) return ok; } return true; } //This test allocates multiple values until there is no more memory //and after that deallocates all in the inverse order template bool test_many_deallocation(Allocator &a) { typedef typename Allocator::multiallocation_chain multiallocation_chain; typedef typename Allocator::multiallocation_chain multiallocation_chain; const std::size_t ArraySize = 11; vector buffers; typename Allocator::size_type requested_sizes[ArraySize]; for(std::size_t i = 0; i < ArraySize; ++i){ requested_sizes[i] = 4*i; } typename Allocator::size_type free_memory = a.get_free_memory(); { for(int i = 0; true; ++i){ multiallocation_chain chain; a.allocate_many(std::nothrow, requested_sizes, ArraySize, 1, chain); if(chain.empty()) break; buffers.push_back(boost::move(chain)); } for(int i = 0, max = (int)buffers.size(); i != max; ++i){ a.deallocate_many(buffers[i]); } buffers.clear(); bool ok = free_memory == a.get_free_memory() && a.all_memory_deallocated() && a.check_sanity(); if(!ok) return ok; } { for(int i = 0; true; ++i){ multiallocation_chain chain; a.allocate_many(std::nothrow, i*4, ArraySize, chain); if(chain.empty()) break; buffers.push_back(boost::move(chain)); } for(int i = 0, max = (int)buffers.size(); i != max; ++i){ a.deallocate_many(buffers[i]); } buffers.clear(); bool ok = free_memory == a.get_free_memory() && a.all_memory_deallocated() && a.check_sanity(); if(!ok) return ok; } return true; } //This function calls all tests template bool test_all_allocation(Allocator &a) { std::cout << "Starting test_allocation. Class: " << typeid(a).name() << std::endl; if(!test_allocation(a)){ std::cout << "test_allocation_direct_deallocation failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_many_equal_allocation. Class: " << typeid(a).name() << std::endl; if(!test_many_equal_allocation(a)){ std::cout << "test_many_equal_allocation failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_many_different_allocation. Class: " << typeid(a).name() << std::endl; if(!test_many_different_allocation(a)){ std::cout << "test_many_different_allocation failed. Class: " << typeid(a).name() << std::endl; return false; } if(!test_many_deallocation(a)){ std::cout << "test_many_deallocation failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_allocation_shrink. Class: " << typeid(a).name() << std::endl; if(!test_allocation_shrink(a)){ std::cout << "test_allocation_shrink failed. Class: " << typeid(a).name() << std::endl; return false; } if(!test_allocation_shrink_and_expand(a)){ std::cout << "test_allocation_shrink_and_expand failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_allocation_expand. Class: " << typeid(a).name() << std::endl; if(!test_allocation_expand(a)){ std::cout << "test_allocation_expand failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_allocation_deallocation_expand. Class: " << typeid(a).name() << std::endl; if(!test_allocation_deallocation_expand(a)){ std::cout << "test_allocation_deallocation_expand failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_allocation_with_reuse. Class: " << typeid(a).name() << std::endl; if(!test_allocation_with_reuse(a)){ std::cout << "test_allocation_with_reuse failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_aligned_allocation. Class: " << typeid(a).name() << std::endl; if(!test_aligned_allocation(a)){ std::cout << "test_aligned_allocation failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_continuous_aligned_allocation. Class: " << typeid(a).name() << std::endl; if(!test_continuous_aligned_allocation(a)){ std::cout << "test_continuous_aligned_allocation failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_clear_free_memory. Class: " << typeid(a).name() << std::endl; if(!test_clear_free_memory(a)){ std::cout << "test_clear_free_memory failed. Class: " << typeid(a).name() << std::endl; return false; } std::cout << "Starting test_grow_shrink_to_fit. Class: " << typeid(a).name() << std::endl; if(!test_grow_shrink_to_fit(a)){ std::cout << "test_grow_shrink_to_fit failed. Class: " << typeid(a).name() << std::endl; return false; } return true; } }}} //namespace boost { namespace interprocess { namespace test { #include #endif //BOOST_INTERPROCESS_TEST_MEMORY_ALGORITHM_TEST_TEMPLATE_HEADER