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nest-open-source / nest-cam / 4320010 / boost / 62d1066a6d52d5ac4e10c106f0eab14c820be0ce / . / boost / boost / interprocess / detail / os_thread_functions.hpp
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//////////////////////////////////////////////////////////////////////////////
//
// (C) Copyright Ion Gaztanaga 2005-2013. 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.
//
//////////////////////////////////////////////////////////////////////////////
//Thread launching functions are adapted from boost/detail/lightweight_thread.hpp
//
// boost/detail/lightweight_thread.hpp
//
// Copyright (c) 2002 Peter Dimov and Multi Media Ltd.
// Copyright (c) 2008 Peter Dimov
//
// 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
#ifndef BOOST_INTERPROCESS_DETAIL_OS_THREAD_FUNCTIONS_HPP
#define BOOST_INTERPROCESS_DETAIL_OS_THREAD_FUNCTIONS_HPP
#ifndef BOOST_CONFIG_HPP
# include <boost/config.hpp>
#endif
#
#if defined(BOOST_HAS_PRAGMA_ONCE)
# pragma once
#endif
#include <boost/interprocess/detail/config_begin.hpp>
#include <boost/interprocess/detail/workaround.hpp>
#include <boost/interprocess/streams/bufferstream.hpp>
#include <boost/interprocess/detail/posix_time_types_wrk.hpp>
#include <cstddef>
#include <ostream>
#if defined(BOOST_INTERPROCESS_WINDOWS)
# include <boost/interprocess/detail/win32_api.hpp>
# include <process.h>
#else
# include <pthread.h>
# include <unistd.h>
# include <sched.h>
# include <time.h>
# ifdef BOOST_INTERPROCESS_BSD_DERIVATIVE
//Some *BSD systems (OpenBSD & NetBSD) need sys/param.h before sys/sysctl.h, whereas
//others (FreeBSD & Darwin) need sys/types.h
# include <sys/types.h>
# include <sys/param.h>
# include <sys/sysctl.h>
# endif
//According to the article "C/C++ tip: How to measure elapsed real time for benchmarking"
# if defined(CLOCK_MONOTONIC_PRECISE) //BSD
# define BOOST_INTERPROCESS_CLOCK_MONOTONIC CLOCK_MONOTONIC_PRECISE
# elif defined(CLOCK_MONOTONIC_RAW) //Linux
# define BOOST_INTERPROCESS_CLOCK_MONOTONIC CLOCK_MONOTONIC_RAW
# elif defined(CLOCK_HIGHRES) //Solaris
# define BOOST_INTERPROCESS_CLOCK_MONOTONIC CLOCK_HIGHRES
# elif defined(CLOCK_MONOTONIC) //POSIX (AIX, BSD, Linux, Solaris)
# define BOOST_INTERPROCESS_CLOCK_MONOTONIC CLOCK_MONOTONIC
# elif !defined(CLOCK_MONOTONIC) && (defined(macintosh) || defined(__APPLE__) || defined(__APPLE_CC__))
# include <mach/mach_time.h> // mach_absolute_time, mach_timebase_info_data_t
# define BOOST_INTERPROCESS_MATCH_ABSOLUTE_TIME
# else
# error "No high resolution steady clock in your system, please provide a patch"
# endif
#endif
namespace boost {
namespace interprocess {
namespace ipcdetail{
#if defined (BOOST_INTERPROCESS_WINDOWS)
typedef unsigned long OS_process_id_t;
typedef unsigned long OS_thread_id_t;
typedef void* OS_thread_t;
typedef OS_thread_id_t OS_systemwide_thread_id_t;
//process
inline OS_process_id_t get_current_process_id()
{ return winapi::get_current_process_id(); }
inline OS_process_id_t get_invalid_process_id()
{ return OS_process_id_t(0); }
//thread
inline OS_thread_id_t get_current_thread_id()
{ return winapi::get_current_thread_id(); }
inline OS_thread_id_t get_invalid_thread_id()
{ return OS_thread_id_t(0xffffffff); }
inline bool equal_thread_id(OS_thread_id_t id1, OS_thread_id_t id2)
{ return id1 == id2; }
//return the system tick in ns
inline unsigned long get_system_tick_ns()
{
unsigned long curres;
winapi::set_timer_resolution(10000, 0, &curres);
//Windows API returns the value in hundreds of ns
return (curres - 1ul)*100ul;
}
//return the system tick in us
inline unsigned long get_system_tick_us()
{
unsigned long curres;
winapi::set_timer_resolution(10000, 0, &curres);
//Windows API returns the value in hundreds of ns
return (curres - 1ul)/10ul + 1ul;
}
typedef unsigned __int64 OS_highres_count_t;
inline unsigned long get_system_tick_in_highres_counts()
{
__int64 freq;
unsigned long curres;
winapi::set_timer_resolution(10000, 0, &curres);
//Frequency in counts per second
if(!winapi::query_performance_frequency(&freq)){
//Tick resolution in ms
return (curres-1ul)/10000ul + 1ul;
}
else{
//In femtoseconds
__int64 count_fs = (1000000000000000LL - 1LL)/freq + 1LL;
__int64 tick_counts = (static_cast<__int64>(curres)*100000000LL - 1LL)/count_fs + 1LL;
return static_cast<unsigned long>(tick_counts);
}
}
inline OS_highres_count_t get_current_system_highres_count()
{
__int64 count;
if(!winapi::query_performance_counter(&count)){
count = winapi::get_tick_count();
}
return count;
}
inline void zero_highres_count(OS_highres_count_t &count)
{ count = 0; }
inline bool is_highres_count_zero(const OS_highres_count_t &count)
{ return count == 0; }
template <class Ostream>
inline Ostream &ostream_highres_count(Ostream &ostream, const OS_highres_count_t &count)
{
ostream << count;
return ostream;
}
inline OS_highres_count_t system_highres_count_subtract(const OS_highres_count_t &l, const OS_highres_count_t &r)
{ return l - r; }
inline bool system_highres_count_less(const OS_highres_count_t &l, const OS_highres_count_t &r)
{ return l < r; }
inline bool system_highres_count_less_ul(const OS_highres_count_t &l, unsigned long r)
{ return l < static_cast<OS_highres_count_t>(r); }
inline void thread_sleep_tick()
{ winapi::sleep_tick(); }
inline void thread_yield()
{ winapi::sched_yield(); }
inline void thread_sleep(unsigned int ms)
{ winapi::sleep(ms); }
//systemwide thread
inline OS_systemwide_thread_id_t get_current_systemwide_thread_id()
{
return get_current_thread_id();
}
inline void systemwide_thread_id_copy
(const volatile OS_systemwide_thread_id_t &from, volatile OS_systemwide_thread_id_t &to)
{
to = from;
}
inline bool equal_systemwide_thread_id(const OS_systemwide_thread_id_t &id1, const OS_systemwide_thread_id_t &id2)
{
return equal_thread_id(id1, id2);
}
inline OS_systemwide_thread_id_t get_invalid_systemwide_thread_id()
{
return get_invalid_thread_id();
}
inline long double get_current_process_creation_time()
{
winapi::interprocess_filetime CreationTime, ExitTime, KernelTime, UserTime;
winapi::get_process_times
( winapi::get_current_process(), &CreationTime, &ExitTime, &KernelTime, &UserTime);
typedef long double ldouble_t;
const ldouble_t resolution = (100.0l/1000000000.0l);
return CreationTime.dwHighDateTime*(ldouble_t(1u<<31u)*2.0l*resolution) +
CreationTime.dwLowDateTime*resolution;
}
inline unsigned int get_num_cores()
{
winapi::system_info sysinfo;
winapi::get_system_info( &sysinfo );
//in Windows dw is long which is equal in bits to int
return static_cast<unsigned>(sysinfo.dwNumberOfProcessors);
}
#else //#if defined (BOOST_INTERPROCESS_WINDOWS)
typedef pthread_t OS_thread_t;
typedef pthread_t OS_thread_id_t;
typedef pid_t OS_process_id_t;
struct OS_systemwide_thread_id_t
{
OS_systemwide_thread_id_t()
: pid(), tid()
{}
OS_systemwide_thread_id_t(pid_t p, pthread_t t)
: pid(p), tid(t)
{}
OS_systemwide_thread_id_t(const OS_systemwide_thread_id_t &x)
: pid(x.pid), tid(x.tid)
{}
OS_systemwide_thread_id_t(const volatile OS_systemwide_thread_id_t &x)
: pid(x.pid), tid(x.tid)
{}
OS_systemwide_thread_id_t & operator=(const OS_systemwide_thread_id_t &x)
{ pid = x.pid; tid = x.tid; return *this; }
OS_systemwide_thread_id_t & operator=(const volatile OS_systemwide_thread_id_t &x)
{ pid = x.pid; tid = x.tid; return *this; }
void operator=(const OS_systemwide_thread_id_t &x) volatile
{ pid = x.pid; tid = x.tid; }
pid_t pid;
pthread_t tid;
};
inline void systemwide_thread_id_copy
(const volatile OS_systemwide_thread_id_t &from, volatile OS_systemwide_thread_id_t &to)
{
to.pid = from.pid;
to.tid = from.tid;
}
//process
inline OS_process_id_t get_current_process_id()
{ return ::getpid(); }
inline OS_process_id_t get_invalid_process_id()
{ return pid_t(0); }
//thread
inline OS_thread_id_t get_current_thread_id()
{ return ::pthread_self(); }
inline OS_thread_id_t get_invalid_thread_id()
{
static pthread_t invalid_id;
return invalid_id;
}
inline bool equal_thread_id(OS_thread_id_t id1, OS_thread_id_t id2)
{ return 0 != pthread_equal(id1, id2); }
inline void thread_yield()
{ ::sched_yield(); }
#ifndef BOOST_INTERPROCESS_MATCH_ABSOLUTE_TIME
typedef struct timespec OS_highres_count_t;
#else
typedef unsigned long long OS_highres_count_t;
#endif
inline unsigned long get_system_tick_ns()
{
#ifdef _SC_CLK_TCK
long ticks_per_second =::sysconf(_SC_CLK_TCK); // ticks per sec
if(ticks_per_second <= 0){ //Try a typical value on error
ticks_per_second = 100;
}
return 999999999ul/static_cast<unsigned long>(ticks_per_second)+1ul;
#else
#error "Can't obtain system tick value for your system, please provide a patch"
#endif
}
inline unsigned long get_system_tick_in_highres_counts()
{
#ifndef BOOST_INTERPROCESS_MATCH_ABSOLUTE_TIME
return get_system_tick_ns();
#else
mach_timebase_info_data_t info;
mach_timebase_info(&info);
//ns
return static_cast<unsigned long>
(
static_cast<double>(get_system_tick_ns())
/ (static_cast<double>(info.numer) / info.denom)
);
#endif
}
//return system ticks in us
inline unsigned long get_system_tick_us()
{
return (get_system_tick_ns()-1)/1000ul + 1ul;
}
inline OS_highres_count_t get_current_system_highres_count()
{
#if defined(BOOST_INTERPROCESS_CLOCK_MONOTONIC)
struct timespec count;
::clock_gettime(BOOST_INTERPROCESS_CLOCK_MONOTONIC, &count);
return count;
#elif defined(BOOST_INTERPROCESS_MATCH_ABSOLUTE_TIME)
return ::mach_absolute_time();
#endif
}
#ifndef BOOST_INTERPROCESS_MATCH_ABSOLUTE_TIME
inline void zero_highres_count(OS_highres_count_t &count)
{ count.tv_sec = 0; count.tv_nsec = 0; }
inline bool is_highres_count_zero(const OS_highres_count_t &count)
{ return count.tv_sec == 0 && count.tv_nsec == 0; }
template <class Ostream>
inline Ostream &ostream_highres_count(Ostream &ostream, const OS_highres_count_t &count)
{
ostream << count.tv_sec << "s:" << count.tv_nsec << "ns";
return ostream;
}
inline OS_highres_count_t system_highres_count_subtract(const OS_highres_count_t &l, const OS_highres_count_t &r)
{
OS_highres_count_t res;
if (l.tv_nsec < r.tv_nsec){
res.tv_nsec = 1000000000 + l.tv_nsec - r.tv_nsec;
res.tv_sec = l.tv_sec - 1 - r.tv_sec;
}
else{
res.tv_nsec = l.tv_nsec - r.tv_nsec;
res.tv_sec = l.tv_sec - r.tv_sec;
}
return res;
}
inline bool system_highres_count_less(const OS_highres_count_t &l, const OS_highres_count_t &r)
{ return l.tv_sec < r.tv_sec || (l.tv_sec == r.tv_sec && l.tv_nsec < r.tv_nsec); }
inline bool system_highres_count_less_ul(const OS_highres_count_t &l, unsigned long r)
{ return !l.tv_sec && (static_cast<unsigned long>(l.tv_nsec) < r); }
#else
inline void zero_highres_count(OS_highres_count_t &count)
{ count = 0; }
inline bool is_highres_count_zero(const OS_highres_count_t &count)
{ return count == 0; }
template <class Ostream>
inline Ostream &ostream_highres_count(Ostream &ostream, const OS_highres_count_t &count)
{
ostream << count ;
return ostream;
}
inline OS_highres_count_t system_highres_count_subtract(const OS_highres_count_t &l, const OS_highres_count_t &r)
{ return l - r; }
inline bool system_highres_count_less(const OS_highres_count_t &l, const OS_highres_count_t &r)
{ return l < r; }
inline bool system_highres_count_less_ul(const OS_highres_count_t &l, unsigned long r)
{ return l < static_cast<OS_highres_count_t>(r); }
#endif
inline void thread_sleep_tick()
{
struct timespec rqt;
//Sleep for the half of the tick time
rqt.tv_sec = 0;
rqt.tv_nsec = get_system_tick_ns()/2;
::nanosleep(&rqt, 0);
}
inline void thread_sleep(unsigned int ms)
{
struct timespec rqt;
rqt.tv_sec = ms/1000u;
rqt.tv_nsec = (ms%1000u)*1000000u;
::nanosleep(&rqt, 0);
}
//systemwide thread
inline OS_systemwide_thread_id_t get_current_systemwide_thread_id()
{
return OS_systemwide_thread_id_t(::getpid(), ::pthread_self());
}
inline bool equal_systemwide_thread_id(const OS_systemwide_thread_id_t &id1, const OS_systemwide_thread_id_t &id2)
{
return (0 != pthread_equal(id1.tid, id2.tid)) && (id1.pid == id2.pid);
}
inline OS_systemwide_thread_id_t get_invalid_systemwide_thread_id()
{
return OS_systemwide_thread_id_t(get_invalid_process_id(), get_invalid_thread_id());
}
inline long double get_current_process_creation_time()
{ return 0.0L; }
inline unsigned int get_num_cores()
{
#ifdef _SC_NPROCESSORS_ONLN
long cores = ::sysconf(_SC_NPROCESSORS_ONLN);
// sysconf returns -1 if the name is invalid, the option does not exist or
// does not have a definite limit.
// if sysconf returns some other negative number, we have no idea
// what is going on. Default to something safe.
if(cores <= 0){
return 1;
}
//Check for overflow (unlikely)
else if(static_cast<unsigned long>(cores) >=
static_cast<unsigned long>(static_cast<unsigned int>(-1))){
return static_cast<unsigned int>(-1);
}
else{
return static_cast<unsigned int>(cores);
}
#elif defined(BOOST_INTERPROCESS_BSD_DERIVATIVE) && defined(HW_NCPU)
int request[2] = { CTL_HW, HW_NCPU };
int num_cores;
std::size_t result_len = sizeof(num_cores);
if ( (::sysctl (request, 2, &num_cores, &result_len, 0, 0) < 0) || (num_cores <= 0) ){
//Return a safe value
return 1;
}
else{
return static_cast<unsigned int>(num_cores);
}
#endif
}
inline int thread_create(OS_thread_t * thread, void *(*start_routine)(void*), void* arg)
{ return pthread_create(thread, 0, start_routine, arg); }
inline void thread_join(OS_thread_t thread)
{ (void)pthread_join(thread, 0); }
#endif //#if defined (BOOST_INTERPROCESS_WINDOWS)
typedef char pid_str_t[sizeof(OS_process_id_t)*3+1];
inline void get_pid_str(pid_str_t &pid_str, OS_process_id_t pid)
{
bufferstream bstream(pid_str, sizeof(pid_str));
bstream << pid << std::ends;
}
inline void get_pid_str(pid_str_t &pid_str)
{ get_pid_str(pid_str, get_current_process_id()); }
#if defined(BOOST_INTERPROCESS_WINDOWS)
inline int thread_create( OS_thread_t * thread, unsigned (__stdcall * start_routine) (void*), void* arg )
{
void* h = (void*)_beginthreadex( 0, 0, start_routine, arg, 0, 0 );
if( h != 0 ){
*thread = h;
return 0;
}
else{
return 1;
}
}
inline void thread_join( OS_thread_t thread)
{
winapi::wait_for_single_object( thread, winapi::infinite_time );
winapi::close_handle( thread );
}
#endif
class abstract_thread
{
public:
virtual ~abstract_thread() {}
virtual void run() = 0;
};
template<class T>
class os_thread_func_ptr_deleter
{
public:
explicit os_thread_func_ptr_deleter(T* p)
: m_p(p)
{}
T *release()
{ T *p = m_p; m_p = 0; return p; }
T *get() const
{ return m_p; }
T *operator ->() const
{ return m_p; }
~os_thread_func_ptr_deleter()
{ delete m_p; }
private:
T *m_p;
};
#if defined(BOOST_INTERPROCESS_WINDOWS)
inline unsigned __stdcall launch_thread_routine( void * pv )
{
os_thread_func_ptr_deleter<abstract_thread> pt( static_cast<abstract_thread *>( pv ) );
pt->run();
return 0;
}
#else
extern "C" void * launch_thread_routine( void * pv );
inline void * launch_thread_routine( void * pv )
{
os_thread_func_ptr_deleter<abstract_thread> pt( static_cast<abstract_thread *>( pv ) );
pt->run();
return 0;
}
#endif
template<class F>
class launch_thread_impl
: public abstract_thread
{
public:
explicit launch_thread_impl( F f )
: f_( f )
{}
void run()
{ f_(); }
private:
F f_;
};
template<class F>
inline int thread_launch( OS_thread_t & pt, F f )
{
os_thread_func_ptr_deleter<abstract_thread> p( new launch_thread_impl<F>( f ) );
int r = thread_create(&pt, launch_thread_routine, p.get());
if( r == 0 ){
p.release();
}
return r;
}
} //namespace ipcdetail{
} //namespace interprocess {
} //namespace boost {
#include <boost/interprocess/detail/config_end.hpp>
#endif //BOOST_INTERPROCESS_DETAIL_OS_THREAD_FUNCTIONS_HPP