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//////////////////////////////////////////////////////////////////////////////
//
// (C) Copyright Ion Gaztanaga 2015-2015. 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/container for documentation.
//
//////////////////////////////////////////////////////////////////////////////
#define BOOST_CONTAINER_SOURCE
#include <boost/container/detail/config_begin.hpp>
#include <boost/container/detail/workaround.hpp>
#include <boost/container/pmr/global_resource.hpp>
#include <boost/container/detail/pool_resource.hpp>
#include <boost/container/detail/block_slist.hpp>
#include <boost/container/detail/min_max.hpp>
#include <boost/container/detail/placement_new.hpp>
#include <boost/intrusive/linear_slist_algorithms.hpp>
#include <boost/intrusive/detail/math.hpp>
#include <boost/static_assert.hpp>
#include <cstddef>
namespace boost {
namespace container {
namespace pmr {
//pool_data_t
class pool_data_t
: public block_slist_base<>
{
typedef block_slist_base<> block_slist_base_t;
public:
explicit pool_data_t(std::size_t initial_blocks_per_chunk)
: block_slist_base_t(), next_blocks_per_chunk(initial_blocks_per_chunk)
{ slist_algo::init_header(&free_slist); }
void *allocate_block() BOOST_NOEXCEPT
{
if(slist_algo::unique(&free_slist)){
return 0;
}
slist_node *pv = slist_algo::node_traits::get_next(&free_slist);
slist_algo::unlink_after(&free_slist);
pv->~slist_node();
return pv;
}
void deallocate_block(void *p) BOOST_NOEXCEPT
{
slist_node *pv = ::new(p, boost_container_new_t()) slist_node();
slist_algo::link_after(&free_slist, pv);
}
void release(memory_resource &upstream)
{
slist_algo::init_header(&free_slist);
this->block_slist_base_t::release(upstream);
next_blocks_per_chunk = pool_options_minimum_max_blocks_per_chunk;
}
void replenish(memory_resource &mr, std::size_t pool_block, std::size_t max_blocks_per_chunk)
{
//Limit max value
std::size_t blocks_per_chunk = boost::container::dtl::min_value(max_blocks_per_chunk, next_blocks_per_chunk);
//Avoid overflow
blocks_per_chunk = boost::container::dtl::min_value(blocks_per_chunk, std::size_t(-1)/pool_block);
//Minimum block size is at least max_align, so all pools allocate sizes that are multiple of max_align,
//meaning that all blocks are max_align-aligned.
char *p = static_cast<char *>(block_slist_base_t::allocate(blocks_per_chunk*pool_block, mr));
//Create header types. This is no-throw
for(std::size_t i = 0, max = blocks_per_chunk; i != max; ++i){
slist_node *const pv = ::new(p, boost_container_new_t()) slist_node();
slist_algo::link_after(&free_slist, pv);
p += pool_block;
}
//Update next block per chunk
next_blocks_per_chunk = max_blocks_per_chunk/2u < blocks_per_chunk ? max_blocks_per_chunk : blocks_per_chunk*2u;
}
std::size_t cache_count() const
{ return slist_algo::count(&free_slist) - 1u; }
slist_node free_slist;
std::size_t next_blocks_per_chunk;
};
//pool_resource
//Detect overflow in ceil_pow2
BOOST_STATIC_ASSERT(pool_options_default_max_blocks_per_chunk <= (std::size_t(-1)/2u+1u));
//Sanity checks
BOOST_STATIC_ASSERT(bi::detail::static_is_pow2<pool_options_default_max_blocks_per_chunk>::value);
BOOST_STATIC_ASSERT(bi::detail::static_is_pow2<pool_options_minimum_largest_required_pool_block>::value);
//unsynchronized_pool_resource
void pool_resource::priv_limit_option(std::size_t &val, std::size_t min, std::size_t max) //static
{
if(!val){
val = max;
}
else{
val = val < min ? min : boost::container::dtl::min_value(val, max);
}
}
std::size_t pool_resource::priv_pool_index(std::size_t block_size) //static
{
//For allocations equal or less than pool_options_minimum_largest_required_pool_block
//the smallest pool is used
block_size = boost::container::dtl::max_value(block_size, pool_options_minimum_largest_required_pool_block);
return bi::detail::ceil_log2(block_size)
- bi::detail::ceil_log2(pool_options_minimum_largest_required_pool_block);
}
std::size_t pool_resource::priv_pool_block(std::size_t index) //static
{
//For allocations equal or less than pool_options_minimum_largest_required_pool_block
//the smallest pool is used
return pool_options_minimum_largest_required_pool_block << index;
}
void pool_resource::priv_fix_options()
{
priv_limit_option(m_options.max_blocks_per_chunk
, pool_options_minimum_max_blocks_per_chunk
, pool_options_default_max_blocks_per_chunk);
priv_limit_option
( m_options.largest_required_pool_block
, pool_options_minimum_largest_required_pool_block
, pool_options_default_largest_required_pool_block);
m_options.largest_required_pool_block = bi::detail::ceil_pow2(m_options.largest_required_pool_block);
}
void pool_resource::priv_init_pools()
{
const std::size_t num_pools = priv_pool_index(m_options.largest_required_pool_block)+1u;
//Otherwise, just use the default alloc (zero pools)
void *p = 0;
//This can throw
p = m_upstream.allocate(sizeof(pool_data_t)*num_pools);
//This is nothrow
m_pool_data = static_cast<pool_data_t *>(p);
for(std::size_t i = 0, max = num_pools; i != max; ++i){
::new(&m_pool_data[i], boost_container_new_t()) pool_data_t(pool_options_minimum_max_blocks_per_chunk);
}
m_pool_count = num_pools;
}
void pool_resource::priv_constructor_body()
{
this->priv_fix_options();
}
pool_resource::pool_resource(const pool_options& opts, memory_resource* upstream) BOOST_NOEXCEPT
: m_options(opts), m_upstream(*upstream), m_oversized_list(), m_pool_data(), m_pool_count()
{ this->priv_constructor_body(); }
pool_resource::pool_resource() BOOST_NOEXCEPT
: m_options(), m_upstream(*get_default_resource()), m_oversized_list(), m_pool_data(), m_pool_count()
{ this->priv_constructor_body(); }
pool_resource::pool_resource(memory_resource* upstream) BOOST_NOEXCEPT
: m_options(), m_upstream(*upstream), m_oversized_list(), m_pool_data(), m_pool_count()
{ this->priv_constructor_body(); }
pool_resource::pool_resource(const pool_options& opts) BOOST_NOEXCEPT
: m_options(opts), m_upstream(*get_default_resource()), m_oversized_list(), m_pool_data(), m_pool_count()
{ this->priv_constructor_body(); }
pool_resource::~pool_resource()
{
this->release();
for(std::size_t i = 0, max = m_pool_count; i != max; ++i){
m_pool_data[i].~pool_data_t();
}
if(m_pool_data){
m_upstream.deallocate((void*)m_pool_data, sizeof(pool_data_t)*m_pool_count);
}
}
void pool_resource::release()
{
m_oversized_list.release(m_upstream);
for(std::size_t i = 0, max = m_pool_count; i != max; ++i)
{
m_pool_data[i].release(m_upstream);
}
}
memory_resource* pool_resource::upstream_resource() const
{ return &m_upstream; }
pool_options pool_resource::options() const
{ return m_options; }
void* pool_resource::do_allocate(std::size_t bytes, std::size_t alignment)
{
if(!m_pool_data){
this->priv_init_pools();
}
(void)alignment; //alignment ignored here, max_align is used by pools
if(bytes > m_options.largest_required_pool_block){
return m_oversized_list.allocate(bytes, m_upstream);
}
else{
const std::size_t pool_idx = priv_pool_index(bytes);
pool_data_t & pool = m_pool_data[pool_idx];
void *p = pool.allocate_block();
if(!p){
pool.replenish(m_upstream, priv_pool_block(pool_idx), m_options.max_blocks_per_chunk);
p = pool.allocate_block();
}
return p;
}
}
void pool_resource::do_deallocate(void* p, std::size_t bytes, std::size_t alignment)
{
(void)alignment; //alignment ignored here, max_align is used by pools
if(bytes > m_options.largest_required_pool_block){
//Just cached
return m_oversized_list.deallocate(p, m_upstream);
}
else{
const std::size_t pool_idx = priv_pool_index(bytes);
return m_pool_data[pool_idx].deallocate_block(p);
}
}
std::size_t pool_resource::pool_count() const
{
if(BOOST_LIKELY((0 != m_pool_data))){
return m_pool_count;
}
else{
return priv_pool_index(m_options.largest_required_pool_block)+1u;
}
}
std::size_t pool_resource::pool_index(std::size_t bytes) const
{
if(bytes > m_options.largest_required_pool_block){
return pool_count();
}
else{
return priv_pool_index(bytes);
}
}
std::size_t pool_resource::pool_next_blocks_per_chunk(std::size_t pool_idx) const
{
if(BOOST_LIKELY((m_pool_data && pool_idx < m_pool_count))){
return m_pool_data[pool_idx].next_blocks_per_chunk;
}
else{
return 1u;
}
}
std::size_t pool_resource::pool_block(std::size_t pool_idx) const
{ return priv_pool_block(pool_idx); }
std::size_t pool_resource::pool_cached_blocks(std::size_t pool_idx) const
{
if(BOOST_LIKELY((m_pool_data && pool_idx < m_pool_count))){
return m_pool_data[pool_idx].cache_count();
}
else{
return 0u;
}
}
} //namespace pmr {
} //namespace container {
} //namespace boost {
#include <boost/container/detail/config_end.hpp>
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