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Fixes #10011 segment_manager::find( unique_instance_t* ) fails to compile

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Ion Gaztañaga
2014-06-02 14:40:19 +02:00
parent 81a5fcf56d
commit aa09229e8a
9 changed files with 692 additions and 101 deletions
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test/segment_manager_test.cpp Normal file
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#include <boost/interprocess/indexes/flat_map_index.hpp>
#include <boost/interprocess/indexes/map_index.hpp>
#include <boost/interprocess/indexes/null_index.hpp>
#include <boost/interprocess/indexes/unordered_map_index.hpp>
#include <boost/interprocess/indexes/iset_index.hpp>
#include <boost/interprocess/indexes/iunordered_set_index.hpp>
#include <boost/interprocess/mem_algo/simple_seq_fit.hpp>
#include <boost/interprocess/mem_algo/rbtree_best_fit.hpp>
#include <boost/interprocess/mapped_region.hpp>
#include <boost/interprocess/segment_manager.hpp>
#include <boost/interprocess/shared_memory_object.hpp>
#include <boost/interprocess/sync/mutex_family.hpp>
#include <boost/interprocess/exceptions.hpp>
#include "get_process_id_name.hpp"
#include <cstddef>
#include <new>
#include <cstring>
using namespace boost::interprocess;
template <class SegmentManager>
struct atomic_func_test
{
SegmentManager &rsm;
int *object;
atomic_func_test(SegmentManager &sm)
: rsm(sm), object()
{}
void operator()()
{
object = rsm.template find<int>("atomic_func_find_object").first;
}
};
template <class SegmentManager>
bool test_segment_manager()
{
typedef typename SegmentManager::size_type size_type;
const unsigned int ShmSizeSize = 1024*64u;
std::string shmname(test::get_process_id_name());
shared_memory_object::remove(shmname.c_str());
shared_memory_object sh_mem( create_only, shmname.c_str(), read_write );
sh_mem.truncate( ShmSizeSize );
mapped_region mapping( sh_mem, read_write );
SegmentManager* seg_mgr = new( mapping.get_address() ) SegmentManager( ShmSizeSize );
std::size_t free_mem_before = seg_mgr->get_free_memory();
std::size_t size_before = seg_mgr->get_size();
if(size_before != ShmSizeSize)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
if(seg_mgr->get_min_size() >= ShmSizeSize)
return false;
{//test get_free_memory() / allocate()/deallocate()
const size_type Size = ShmSizeSize/2;
void *mem = seg_mgr->allocate(Size+1);
const size_type free_mem = seg_mgr->get_free_memory();
if(free_mem >= Size)
return false;
if(seg_mgr->all_memory_deallocated())
return false;
const size_type Size2 = free_mem/2;
void *mem2 = seg_mgr->allocate(size_type(Size2+1), std::nothrow);
if(seg_mgr->get_free_memory() >= Size2)
return false;
if(seg_mgr->size(mem) < (Size+1))
return false;
if(seg_mgr->size(mem2) < (Size2+1))
return false;
seg_mgr->deallocate(mem);
seg_mgr->deallocate(mem2);
if(!seg_mgr->all_memory_deallocated())
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
try{ seg_mgr->allocate(ShmSizeSize*2); }catch(interprocess_exception&){}
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(seg_mgr->allocate(ShmSizeSize*2, std::nothrow))
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
}
{//test allocate_aligned
const std::size_t Alignment = 128u;
void *mem = seg_mgr->allocate_aligned(ShmSizeSize/4, Alignment);
if(seg_mgr->all_memory_deallocated())
return false;
std::size_t offset = static_cast<std::size_t>
(static_cast<const char *>(mem) - static_cast<const char *>(mapping.get_address()));
if(offset & (Alignment-1))
return false;
void *mem2 = seg_mgr->allocate_aligned(ShmSizeSize/4, Alignment, std::nothrow);
std::size_t offset2 = static_cast<std::size_t>
(static_cast<const char *>(mem2) - static_cast<const char *>(mapping.get_address()));
if(offset2 & (Alignment-1))
return false;
seg_mgr->deallocate(mem);
seg_mgr->deallocate(mem2);
if(!seg_mgr->all_memory_deallocated())
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
try{ seg_mgr->allocate_aligned(ShmSizeSize*2, Alignment); }catch(interprocess_exception&){}
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(seg_mgr->allocate_aligned(ShmSizeSize*2, Alignment, std::nothrow))
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
}
{//test shrink_to_fit
seg_mgr->shrink_to_fit();
if(!seg_mgr->all_memory_deallocated())
return false;
std::size_t empty_shrunk_size = seg_mgr->get_size();
std::size_t empty_shrunk_free_mem = seg_mgr->get_free_memory();
if(empty_shrunk_size >= size_before)
return false;
if(empty_shrunk_free_mem >= size_before)
return false;
seg_mgr->grow(size_type(size_before - empty_shrunk_size));
if(seg_mgr->get_size() != size_before)
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test zero_free_memory
const size_type Size(ShmSizeSize/2+1), Size2(ShmSizeSize/8);
void *mem = seg_mgr->allocate(Size);
void *mem2 = seg_mgr->allocate(Size2);
//Mark memory to non-zero
std::memset(mem, 0xFF, Size);
std::memset(mem2, 0xFF, Size2);
static unsigned char zerobuf[Size];
//Deallocate and check still non-zero
seg_mgr->deallocate(mem);
seg_mgr->deallocate(mem2);
if(!std::memcmp(mem, zerobuf, Size))
return false;
if(!std::memcmp(mem2, zerobuf, Size2))
return false;
//zero_free_memory and check it's zeroed
seg_mgr->zero_free_memory();
//TODO: some parts are not zeroed because they are used
//as internal metadata, find a way to test this
//if(std::memcmp(mem, zerobuf, Size))
//return false;
//if(std::memcmp(mem2, zerobuf, Size2))
//return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test anonymous object
int *int_object = seg_mgr->template construct<int>(anonymous_instance)();
if(1 != seg_mgr->get_instance_length(int_object))
return false;
if(anonymous_type != seg_mgr->get_instance_type(int_object))
return false;
if(seg_mgr->get_instance_name(int_object))
return false;
seg_mgr->destroy_ptr(int_object);
int const int_array_values[10] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int *int_array = seg_mgr->template construct_it<int>(anonymous_instance, std::nothrow)[10](&int_array_values[0]);
if(10 != seg_mgr->get_instance_length(int_object))
return false;
if(anonymous_type != seg_mgr->get_instance_type(int_array))
return false;
if(seg_mgr->get_instance_name(int_array))
return false;
seg_mgr->destroy_ptr(int_array);
try{ seg_mgr->template construct<int>(anonymous_instance)[ShmSizeSize](); }catch(interprocess_exception&){}
if(seg_mgr->template construct<int>(anonymous_instance, std::nothrow)[ShmSizeSize]())
try{ seg_mgr->template construct_it<int>(anonymous_instance)[ShmSizeSize](&int_array_values[0]); }catch(interprocess_exception&){}
if(seg_mgr->template construct_it<int>(anonymous_instance, std::nothrow)[ShmSizeSize](&int_array_values[0]))
return false;
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test named object
const char *const object1_name = "object1";
const char *const object2_name = "object2";
int const int_array_values[10] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
for(std::size_t i = 0; i != 4; ++i){
if(seg_mgr->template find<unsigned int>(object1_name).first)
return false;
//Single element construction
unsigned int *uint_object = 0;
switch(i){
case 0:
uint_object = seg_mgr->template construct<unsigned int>(object1_name)();
break;
case 1:
uint_object = seg_mgr->template construct<unsigned int>(object1_name, std::nothrow)();
break;
case 2:
uint_object = seg_mgr->template find_or_construct<unsigned int>(object1_name)();
break;
case 3:
uint_object = seg_mgr->template find_or_construct<unsigned int>(object1_name, std::nothrow)();
break;
}
std::pair<unsigned int*, std::size_t> find_ret = seg_mgr->template find<unsigned int>(object1_name);
if(uint_object != find_ret.first)
return false;
if(1 != find_ret.second)
return false;
if(1 != seg_mgr->get_instance_length(uint_object))
return false;
if(named_type != seg_mgr->get_instance_type(uint_object))
return false;
if(std::strcmp(object1_name, seg_mgr->get_instance_name(uint_object)))
return false;
//Array construction
if(seg_mgr->template find<int>(object2_name).first)
return false;
int *int_array = 0;
switch(i){
case 0:
int_array = seg_mgr->template construct_it<int>(object2_name)[10](&int_array_values[0]);
break;
case 1:
int_array = seg_mgr->template construct_it<int>(object2_name, std::nothrow)[10](&int_array_values[0]);
break;
case 2:
int_array = seg_mgr->template find_or_construct_it<int>(object2_name)[10](&int_array_values[0]);
break;
case 3:
int_array = seg_mgr->template find_or_construct_it<int>(object2_name, std::nothrow)[10](&int_array_values[0]);
break;
}
std::pair<int*, std::size_t> find_ret2 = seg_mgr->template find<int>(object2_name);
if(int_array != find_ret2.first)
return false;
if(10 != find_ret2.second)
return false;
if(10 != seg_mgr->get_instance_length(int_array))
return false;
if(named_type != seg_mgr->get_instance_type(int_array))
return false;
if(std::strcmp(object2_name, seg_mgr->get_instance_name(int_array)))
return false;
if(seg_mgr->get_num_named_objects() != 2)
return false;
typename SegmentManager::const_named_iterator nb(seg_mgr->named_begin());
typename SegmentManager::const_named_iterator ne(seg_mgr->named_end());
for(std::size_t i = 0, imax = seg_mgr->get_num_named_objects(); i != imax; ++i){ ++nb; }
if(nb != ne)
return false;
seg_mgr->destroy_ptr(uint_object);
seg_mgr->template destroy<int>(object2_name);
}
try{ seg_mgr->template construct<unsigned int>(object1_name)[ShmSizeSize](); }catch(interprocess_exception&){}
if(seg_mgr->template construct<int>(object2_name, std::nothrow)[ShmSizeSize]())
try{ seg_mgr->template construct_it<unsigned int>(object1_name)[ShmSizeSize](&int_array_values[0]); }catch(interprocess_exception&){}
if(seg_mgr->template construct_it<int>(object2_name, std::nothrow)[ShmSizeSize](&int_array_values[0]))
return false;
seg_mgr->shrink_to_fit_indexes();
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
seg_mgr->reserve_named_objects(1);
//In indexes with no capacity() memory won't be allocated so don't check anything was allocated.
//if(seg_mgr->all_memory_deallocated()) return false;
seg_mgr->shrink_to_fit_indexes();
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test unique object
int const int_array_values[10] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
for(std::size_t i = 0; i != 4; ++i){
if(seg_mgr->template find<unsigned int>(unique_instance).first)
return false;
//Single element construction
unsigned int *uint_object = 0;
switch(i){
case 0:
uint_object = seg_mgr->template construct<unsigned int>(unique_instance)();
break;
case 1:
uint_object = seg_mgr->template construct<unsigned int>(unique_instance, std::nothrow)();
break;
case 2:
uint_object = seg_mgr->template find_or_construct<unsigned int>(unique_instance)();
break;
case 3:
uint_object = seg_mgr->template find_or_construct<unsigned int>(unique_instance, std::nothrow)();
break;
}
std::pair<unsigned int*, std::size_t> find_ret = seg_mgr->template find<unsigned int>(unique_instance);
if(uint_object != find_ret.first)
return false;
if(1 != find_ret.second)
return false;
if(1 != seg_mgr->get_instance_length(uint_object))
return false;
if(unique_type != seg_mgr->get_instance_type(uint_object))
return false;
if(std::strcmp(typeid(unsigned int).name(), seg_mgr->get_instance_name(uint_object)))
return false;
//Array construction
if(seg_mgr->template find<int>(unique_instance).first)
return false;
int *int_array = 0;
switch(i){
case 0:
int_array = seg_mgr->template construct_it<int>(unique_instance)[10](&int_array_values[0]);
break;
case 1:
int_array = seg_mgr->template construct_it<int>(unique_instance, std::nothrow)[10](&int_array_values[0]);
break;
case 2:
int_array = seg_mgr->template find_or_construct_it<int>(unique_instance)[10](&int_array_values[0]);
break;
case 3:
int_array = seg_mgr->template find_or_construct_it<int>(unique_instance, std::nothrow)[10](&int_array_values[0]);
break;
}
std::pair<int*, std::size_t> find_ret2 = seg_mgr->template find<int>(unique_instance);
if(int_array != find_ret2.first)
return false;
if(10 != find_ret2.second)
return false;
if(10 != seg_mgr->get_instance_length(int_array))
return false;
if(unique_type != seg_mgr->get_instance_type(int_array))
return false;
if(std::strcmp(typeid(int).name(), seg_mgr->get_instance_name(int_array)))
return false;
if(seg_mgr->get_num_unique_objects() != 2)
return false;
typename SegmentManager::const_unique_iterator nb(seg_mgr->unique_begin());
typename SegmentManager::const_unique_iterator ne(seg_mgr->unique_end());
for(std::size_t i = 0, imax = seg_mgr->get_num_unique_objects(); i != imax; ++i){ ++nb; }
if(nb != ne)
return false;
seg_mgr->destroy_ptr(uint_object);
seg_mgr->template destroy<int>(unique_instance);
}
try{ seg_mgr->template construct<unsigned int>(unique_instance)[ShmSizeSize](); }catch(interprocess_exception&){}
if(seg_mgr->template construct<int>(unique_instance, std::nothrow)[ShmSizeSize]())
try{ seg_mgr->template construct_it<unsigned int>(unique_instance)[ShmSizeSize](&int_array_values[0]); }catch(interprocess_exception&){}
if(seg_mgr->template construct_it<int>(unique_instance, std::nothrow)[ShmSizeSize](&int_array_values[0]))
return false;
seg_mgr->shrink_to_fit_indexes();
if(seg_mgr->get_free_memory() != free_mem_before)
return false;
if(!seg_mgr->all_memory_deallocated())
return false;
seg_mgr->reserve_unique_objects(1);
//In indexes with no capacity() memory won't be allocated so don't check anything was allocated.
//if(seg_mgr->all_memory_deallocated()) return false;
seg_mgr->shrink_to_fit_indexes();
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test allocator/deleter
if(!seg_mgr->all_memory_deallocated())
return false;
typedef typename SegmentManager::template allocator<float>::type allocator_t;
typedef typename SegmentManager::template deleter<float>::type deleter_t;
allocator_t alloc(seg_mgr->template get_allocator<float>());
deleter_t delet(seg_mgr->template get_deleter<float>());
if(!seg_mgr->all_memory_deallocated())
return false;
offset_ptr<float> f = alloc.allocate(50);
if(seg_mgr->all_memory_deallocated())
return false;
alloc.deallocate(f, 50);
if(!seg_mgr->all_memory_deallocated())
return false;
}
{//test allocator/deleter
if(!seg_mgr->all_memory_deallocated())
return false;
int *int_object = seg_mgr->template construct<int>("atomic_func_find_object")();
atomic_func_test<SegmentManager> func(*seg_mgr);
seg_mgr->atomic_func(func);
if(int_object != func.object)
return 1;
seg_mgr->destroy_ptr(int_object);
seg_mgr->shrink_to_fit_indexes();
if(!seg_mgr->all_memory_deallocated())
return false;
}
return true;
}
template<class MemoryAlgorithm>
bool test_each_algo()
{
{
typedef segment_manager< char, MemoryAlgorithm, flat_map_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}
{
typedef segment_manager< char, MemoryAlgorithm, map_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}
/*
{
typedef segment_manager< char, MemoryAlgorithm, null_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}*/
/*
{
typedef segment_manager< char, MemoryAlgorithm, unordered_map_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}*/
{
typedef segment_manager< char, MemoryAlgorithm, iset_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}
{
typedef segment_manager< char, MemoryAlgorithm, iunordered_set_index > segment_manager_t;
if(!test_segment_manager<segment_manager_t>())
return false;
}
return true;
}
int main()
{
if(!test_each_algo< simple_seq_fit< null_mutex_family > >())
return 1;
if(!test_each_algo< rbtree_best_fit< null_mutex_family > >())
return 1;
return 0;
}