Add support for NO_DEPEND_GENERATE to makefile calls and respond accordingly in FLMs.
Remove remaining bits of the old (and redundant) DEPEND_SKIP variant from interfaces and FLMs.
Correct CLI option storage.
// 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)
// (C) Copyright 2007 Anthony Williams
#ifndef BOOST_THREAD_LOCKS_HPP
#define BOOST_THREAD_LOCKS_HPP
#include <boost/thread/detail/config.hpp>
#include <boost/thread/exceptions.hpp>
#include <boost/thread/detail/move.hpp>
#include <algorithm>
#include <iterator>
#include <boost/thread/thread_time.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/config/abi_prefix.hpp>
namespace boost
{
struct xtime;
#if defined(BOOST_NO_SFINAE) || \
BOOST_WORKAROUND(__IBMCPP__, BOOST_TESTED_AT(600)) || \
BOOST_WORKAROUND(__SUNPRO_CC, BOOST_TESTED_AT(0x590))
#define BOOST_THREAD_NO_AUTO_DETECT_MUTEX_TYPES
#endif
#ifndef BOOST_THREAD_NO_AUTO_DETECT_MUTEX_TYPES
namespace detail
{
template<typename T>
struct has_member_lock
{
typedef char true_type;
struct false_type
{
true_type dummy[2];
};
template<typename U>
static true_type has_member(U*,void (U::*dummy)()=&U::lock);
static false_type has_member(void*);
BOOST_STATIC_CONSTANT(bool, value=sizeof(has_member_lock<T>::has_member((T*)NULL))==sizeof(true_type));
};
template<typename T>
struct has_member_unlock
{
typedef char true_type;
struct false_type
{
true_type dummy[2];
};
template<typename U>
static true_type has_member(U*,void (U::*dummy)()=&U::unlock);
static false_type has_member(void*);
BOOST_STATIC_CONSTANT(bool, value=sizeof(has_member_unlock<T>::has_member((T*)NULL))==sizeof(true_type));
};
template<typename T>
struct has_member_try_lock
{
typedef char true_type;
struct false_type
{
true_type dummy[2];
};
template<typename U>
static true_type has_member(U*,bool (U::*dummy)()=&U::try_lock);
static false_type has_member(void*);
BOOST_STATIC_CONSTANT(bool, value=sizeof(has_member_try_lock<T>::has_member((T*)NULL))==sizeof(true_type));
};
}
template<typename T>
struct is_mutex_type
{
BOOST_STATIC_CONSTANT(bool, value = detail::has_member_lock<T>::value &&
detail::has_member_unlock<T>::value &&
detail::has_member_try_lock<T>::value);
};
#else
template<typename T>
struct is_mutex_type
{
BOOST_STATIC_CONSTANT(bool, value = false);
};
#endif
struct defer_lock_t
{};
struct try_to_lock_t
{};
struct adopt_lock_t
{};
const defer_lock_t defer_lock={};
const try_to_lock_t try_to_lock={};
const adopt_lock_t adopt_lock={};
template<typename Mutex>
class shared_lock;
template<typename Mutex>
class upgrade_lock;
template<typename Mutex>
class unique_lock;
namespace detail
{
template<typename Mutex>
class try_lock_wrapper;
}
#ifdef BOOST_THREAD_NO_AUTO_DETECT_MUTEX_TYPES
template<typename T>
struct is_mutex_type<unique_lock<T> >
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<typename T>
struct is_mutex_type<shared_lock<T> >
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<typename T>
struct is_mutex_type<upgrade_lock<T> >
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<typename T>
struct is_mutex_type<detail::try_lock_wrapper<T> >
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
class mutex;
class timed_mutex;
class recursive_mutex;
class recursive_timed_mutex;
class shared_mutex;
template<>
struct is_mutex_type<mutex>
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<>
struct is_mutex_type<timed_mutex>
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<>
struct is_mutex_type<recursive_mutex>
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<>
struct is_mutex_type<recursive_timed_mutex>
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<>
struct is_mutex_type<shared_mutex>
{
BOOST_STATIC_CONSTANT(bool, value = true);
};
#endif
template<typename Mutex>
class lock_guard
{
private:
Mutex& m;
explicit lock_guard(lock_guard&);
lock_guard& operator=(lock_guard&);
public:
explicit lock_guard(Mutex& m_):
m(m_)
{
m.lock();
}
lock_guard(Mutex& m_,adopt_lock_t):
m(m_)
{}
~lock_guard()
{
m.unlock();
}
};
template<typename Mutex>
class unique_lock
{
private:
Mutex* m;
bool is_locked;
unique_lock(unique_lock&);
explicit unique_lock(upgrade_lock<Mutex>&);
unique_lock& operator=(unique_lock&);
unique_lock& operator=(upgrade_lock<Mutex>& other);
public:
unique_lock():
m(0),is_locked(false)
{}
explicit unique_lock(Mutex& m_):
m(&m_),is_locked(false)
{
lock();
}
unique_lock(Mutex& m_,adopt_lock_t):
m(&m_),is_locked(true)
{}
unique_lock(Mutex& m_,defer_lock_t):
m(&m_),is_locked(false)
{}
unique_lock(Mutex& m_,try_to_lock_t):
m(&m_),is_locked(false)
{
try_lock();
}
template<typename TimeDuration>
unique_lock(Mutex& m_,TimeDuration const& target_time):
m(&m_),is_locked(false)
{
timed_lock(target_time);
}
unique_lock(Mutex& m_,system_time const& target_time):
m(&m_),is_locked(false)
{
timed_lock(target_time);
}
#ifdef BOOST_HAS_RVALUE_REFS
unique_lock(unique_lock&& other):
m(other.m),is_locked(other.is_locked)
{
other.is_locked=false;
other.m=0;
}
explicit unique_lock(upgrade_lock<Mutex>&& other);
unique_lock<Mutex>&& move()
{
return static_cast<unique_lock<Mutex>&&>(*this);
}
unique_lock& operator=(unique_lock<Mutex>&& other)
{
unique_lock temp(other);
swap(temp);
return *this;
}
unique_lock& operator=(upgrade_lock<Mutex>&& other)
{
unique_lock temp(other);
swap(temp);
return *this;
}
void swap(unique_lock&& other)
{
std::swap(m,other.m);
std::swap(is_locked,other.is_locked);
}
#else
unique_lock(detail::thread_move_t<unique_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
other->is_locked=false;
other->m=0;
}
unique_lock(detail::thread_move_t<upgrade_lock<Mutex> > other);
operator detail::thread_move_t<unique_lock<Mutex> >()
{
return move();
}
detail::thread_move_t<unique_lock<Mutex> > move()
{
return detail::thread_move_t<unique_lock<Mutex> >(*this);
}
unique_lock& operator=(detail::thread_move_t<unique_lock<Mutex> > other)
{
unique_lock temp(other);
swap(temp);
return *this;
}
unique_lock& operator=(detail::thread_move_t<upgrade_lock<Mutex> > other)
{
unique_lock temp(other);
swap(temp);
return *this;
}
void swap(unique_lock& other)
{
std::swap(m,other.m);
std::swap(is_locked,other.is_locked);
}
void swap(detail::thread_move_t<unique_lock<Mutex> > other)
{
std::swap(m,other->m);
std::swap(is_locked,other->is_locked);
}
#endif
~unique_lock()
{
if(owns_lock())
{
m->unlock();
}
}
void lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
m->lock();
is_locked=true;
}
bool try_lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
is_locked=m->try_lock();
return is_locked;
}
template<typename TimeDuration>
bool timed_lock(TimeDuration const& relative_time)
{
is_locked=m->timed_lock(relative_time);
return is_locked;
}
bool timed_lock(::boost::system_time const& absolute_time)
{
is_locked=m->timed_lock(absolute_time);
return is_locked;
}
bool timed_lock(::boost::xtime const& absolute_time)
{
is_locked=m->timed_lock(absolute_time);
return is_locked;
}
void unlock()
{
if(!owns_lock())
{
throw boost::lock_error();
}
m->unlock();
is_locked=false;
}
typedef void (unique_lock::*bool_type)();
operator bool_type() const
{
return is_locked?&unique_lock::lock:0;
}
bool operator!() const
{
return !owns_lock();
}
bool owns_lock() const
{
return is_locked;
}
Mutex* mutex() const
{
return m;
}
Mutex* release()
{
Mutex* const res=m;
m=0;
is_locked=false;
return res;
}
friend class shared_lock<Mutex>;
friend class upgrade_lock<Mutex>;
};
#ifdef BOOST_HAS_RVALUE_REFS
template<typename Mutex>
void swap(unique_lock<Mutex>&& lhs,unique_lock<Mutex>&& rhs)
{
lhs.swap(rhs);
}
#else
template<typename Mutex>
void swap(unique_lock<Mutex>& lhs,unique_lock<Mutex>& rhs)
{
lhs.swap(rhs);
}
#endif
#ifdef BOOST_HAS_RVALUE_REFS
template<typename Mutex>
inline unique_lock<Mutex>&& move(unique_lock<Mutex>&& ul)
{
return ul;
}
#endif
template<typename Mutex>
class shared_lock
{
protected:
Mutex* m;
bool is_locked;
private:
explicit shared_lock(shared_lock&);
shared_lock& operator=(shared_lock&);
public:
shared_lock():
m(0),is_locked(false)
{}
explicit shared_lock(Mutex& m_):
m(&m_),is_locked(false)
{
lock();
}
shared_lock(Mutex& m_,adopt_lock_t):
m(&m_),is_locked(true)
{}
shared_lock(Mutex& m_,defer_lock_t):
m(&m_),is_locked(false)
{}
shared_lock(Mutex& m_,try_to_lock_t):
m(&m_),is_locked(false)
{
try_lock();
}
shared_lock(Mutex& m_,system_time const& target_time):
m(&m_),is_locked(false)
{
timed_lock(target_time);
}
shared_lock(detail::thread_move_t<shared_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
other->is_locked=false;
other->m=0;
}
shared_lock(detail::thread_move_t<unique_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
if(is_locked)
{
m->unlock_and_lock_shared();
}
other->is_locked=false;
other->m=0;
}
shared_lock(detail::thread_move_t<upgrade_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
if(is_locked)
{
m->unlock_upgrade_and_lock_shared();
}
other->is_locked=false;
other->m=0;
}
operator detail::thread_move_t<shared_lock<Mutex> >()
{
return move();
}
detail::thread_move_t<shared_lock<Mutex> > move()
{
return detail::thread_move_t<shared_lock<Mutex> >(*this);
}
shared_lock& operator=(detail::thread_move_t<shared_lock<Mutex> > other)
{
shared_lock temp(other);
swap(temp);
return *this;
}
shared_lock& operator=(detail::thread_move_t<unique_lock<Mutex> > other)
{
shared_lock temp(other);
swap(temp);
return *this;
}
shared_lock& operator=(detail::thread_move_t<upgrade_lock<Mutex> > other)
{
shared_lock temp(other);
swap(temp);
return *this;
}
#ifdef BOOST_HAS_RVALUE_REFS
void swap(shared_lock&& other)
{
std::swap(m,other.m);
std::swap(is_locked,other.is_locked);
}
#else
void swap(shared_lock& other)
{
std::swap(m,other.m);
std::swap(is_locked,other.is_locked);
}
void swap(boost::detail::thread_move_t<shared_lock<Mutex> > other)
{
std::swap(m,other->m);
std::swap(is_locked,other->is_locked);
}
#endif
Mutex* mutex() const
{
return m;
}
~shared_lock()
{
if(owns_lock())
{
m->unlock_shared();
}
}
void lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
m->lock_shared();
is_locked=true;
}
bool try_lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
is_locked=m->try_lock_shared();
return is_locked;
}
bool timed_lock(boost::system_time const& target_time)
{
if(owns_lock())
{
throw boost::lock_error();
}
is_locked=m->timed_lock_shared(target_time);
return is_locked;
}
template<typename Duration>
bool timed_lock(Duration const& target_time)
{
if(owns_lock())
{
throw boost::lock_error();
}
is_locked=m->timed_lock_shared(target_time);
return is_locked;
}
void unlock()
{
if(!owns_lock())
{
throw boost::lock_error();
}
m->unlock_shared();
is_locked=false;
}
typedef void (shared_lock<Mutex>::*bool_type)();
operator bool_type() const
{
return is_locked?&shared_lock::lock:0;
}
bool operator!() const
{
return !owns_lock();
}
bool owns_lock() const
{
return is_locked;
}
};
#ifdef BOOST_HAS_RVALUE_REFS
template<typename Mutex>
void swap(shared_lock<Mutex>&& lhs,shared_lock<Mutex>&& rhs)
{
lhs.swap(rhs);
}
#else
template<typename Mutex>
void swap(shared_lock<Mutex>& lhs,shared_lock<Mutex>& rhs)
{
lhs.swap(rhs);
}
#endif
template<typename Mutex>
class upgrade_lock
{
protected:
Mutex* m;
bool is_locked;
private:
explicit upgrade_lock(upgrade_lock&);
upgrade_lock& operator=(upgrade_lock&);
public:
upgrade_lock():
m(0),is_locked(false)
{}
explicit upgrade_lock(Mutex& m_):
m(&m_),is_locked(false)
{
lock();
}
upgrade_lock(Mutex& m_,adopt_lock_t):
m(&m_),is_locked(true)
{}
upgrade_lock(Mutex& m_,defer_lock_t):
m(&m_),is_locked(false)
{}
upgrade_lock(Mutex& m_,try_to_lock_t):
m(&m_),is_locked(false)
{
try_lock();
}
upgrade_lock(detail::thread_move_t<upgrade_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
other->is_locked=false;
other->m=0;
}
upgrade_lock(detail::thread_move_t<unique_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
if(is_locked)
{
m->unlock_and_lock_upgrade();
}
other->is_locked=false;
other->m=0;
}
operator detail::thread_move_t<upgrade_lock<Mutex> >()
{
return move();
}
detail::thread_move_t<upgrade_lock<Mutex> > move()
{
return detail::thread_move_t<upgrade_lock<Mutex> >(*this);
}
upgrade_lock& operator=(detail::thread_move_t<upgrade_lock<Mutex> > other)
{
upgrade_lock temp(other);
swap(temp);
return *this;
}
upgrade_lock& operator=(detail::thread_move_t<unique_lock<Mutex> > other)
{
upgrade_lock temp(other);
swap(temp);
return *this;
}
void swap(upgrade_lock& other)
{
std::swap(m,other.m);
std::swap(is_locked,other.is_locked);
}
~upgrade_lock()
{
if(owns_lock())
{
m->unlock_upgrade();
}
}
void lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
m->lock_upgrade();
is_locked=true;
}
bool try_lock()
{
if(owns_lock())
{
throw boost::lock_error();
}
is_locked=m->try_lock_upgrade();
return is_locked;
}
void unlock()
{
if(!owns_lock())
{
throw boost::lock_error();
}
m->unlock_upgrade();
is_locked=false;
}
typedef void (upgrade_lock::*bool_type)();
operator bool_type() const
{
return is_locked?&upgrade_lock::lock:0;
}
bool operator!() const
{
return !owns_lock();
}
bool owns_lock() const
{
return is_locked;
}
friend class shared_lock<Mutex>;
friend class unique_lock<Mutex>;
};
#ifdef BOOST_HAS_RVALUE_REFS
template<typename Mutex>
unique_lock<Mutex>::unique_lock(upgrade_lock<Mutex>&& other):
m(other.m),is_locked(other.is_locked)
{
other.is_locked=false;
if(is_locked)
{
m.unlock_upgrade_and_lock();
}
}
#else
template<typename Mutex>
unique_lock<Mutex>::unique_lock(detail::thread_move_t<upgrade_lock<Mutex> > other):
m(other->m),is_locked(other->is_locked)
{
other->is_locked=false;
if(is_locked)
{
m->unlock_upgrade_and_lock();
}
}
#endif
template <class Mutex>
class upgrade_to_unique_lock
{
private:
upgrade_lock<Mutex>* source;
unique_lock<Mutex> exclusive;
explicit upgrade_to_unique_lock(upgrade_to_unique_lock&);
upgrade_to_unique_lock& operator=(upgrade_to_unique_lock&);
public:
explicit upgrade_to_unique_lock(upgrade_lock<Mutex>& m_):
source(&m_),exclusive(move(*source))
{}
~upgrade_to_unique_lock()
{
if(source)
{
*source=move(exclusive);
}
}
upgrade_to_unique_lock(detail::thread_move_t<upgrade_to_unique_lock<Mutex> > other):
source(other->source),exclusive(move(other->exclusive))
{
other->source=0;
}
upgrade_to_unique_lock& operator=(detail::thread_move_t<upgrade_to_unique_lock<Mutex> > other)
{
upgrade_to_unique_lock temp(other);
swap(temp);
return *this;
}
void swap(upgrade_to_unique_lock& other)
{
std::swap(source,other.source);
exclusive.swap(other.exclusive);
}
typedef void (upgrade_to_unique_lock::*bool_type)(upgrade_to_unique_lock&);
operator bool_type() const
{
return exclusive.owns_lock()?&upgrade_to_unique_lock::swap:0;
}
bool operator!() const
{
return !owns_lock();
}
bool owns_lock() const
{
return exclusive.owns_lock();
}
};
namespace detail
{
template<typename Mutex>
class try_lock_wrapper:
private unique_lock<Mutex>
{
typedef unique_lock<Mutex> base;
public:
try_lock_wrapper()
{}
explicit try_lock_wrapper(Mutex& m):
base(m,try_to_lock)
{}
try_lock_wrapper(Mutex& m_,adopt_lock_t):
base(m_,adopt_lock)
{}
try_lock_wrapper(Mutex& m_,defer_lock_t):
base(m_,defer_lock)
{}
try_lock_wrapper(Mutex& m_,try_to_lock_t):
base(m_,try_to_lock)
{}
try_lock_wrapper(detail::thread_move_t<try_lock_wrapper<Mutex> > other):
base(detail::thread_move_t<base>(*other))
{}
operator detail::thread_move_t<try_lock_wrapper<Mutex> >()
{
return move();
}
detail::thread_move_t<try_lock_wrapper<Mutex> > move()
{
return detail::thread_move_t<try_lock_wrapper<Mutex> >(*this);
}
try_lock_wrapper& operator=(detail::thread_move_t<try_lock_wrapper<Mutex> > other)
{
try_lock_wrapper temp(other);
swap(temp);
return *this;
}
#ifdef BOOST_HAS_RVALUE_REFS
void swap(try_lock_wrapper&& other)
{
base::swap(other);
}
#else
void swap(try_lock_wrapper& other)
{
base::swap(other);
}
void swap(detail::thread_move_t<try_lock_wrapper<Mutex> > other)
{
base::swap(*other);
}
#endif
void lock()
{
base::lock();
}
bool try_lock()
{
return base::try_lock();
}
void unlock()
{
base::unlock();
}
bool owns_lock() const
{
return base::owns_lock();
}
Mutex* mutex() const
{
return base::mutex();
}
Mutex* release()
{
return base::release();
}
bool operator!() const
{
return !this->owns_lock();
}
typedef typename base::bool_type bool_type;
operator bool_type() const
{
return base::operator bool_type();
}
};
#ifdef BOOST_HAS_RVALUE_REFS
template<typename Mutex>
void swap(try_lock_wrapper<Mutex>&& lhs,try_lock_wrapper<Mutex>&& rhs)
{
lhs.swap(rhs);
}
#else
template<typename Mutex>
void swap(try_lock_wrapper<Mutex>& lhs,try_lock_wrapper<Mutex>& rhs)
{
lhs.swap(rhs);
}
#endif
template<typename MutexType1,typename MutexType2>
unsigned try_lock_internal(MutexType1& m1,MutexType2& m2)
{
boost::unique_lock<MutexType1> l1(m1,boost::try_to_lock);
if(!l1)
{
return 1;
}
if(!m2.try_lock())
{
return 2;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3>
unsigned try_lock_internal(MutexType1& m1,MutexType2& m2,MutexType3& m3)
{
boost::unique_lock<MutexType1> l1(m1,boost::try_to_lock);
if(!l1)
{
return 1;
}
if(unsigned const failed_lock=try_lock_internal(m2,m3))
{
return failed_lock+1;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4>
unsigned try_lock_internal(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4)
{
boost::unique_lock<MutexType1> l1(m1,boost::try_to_lock);
if(!l1)
{
return 1;
}
if(unsigned const failed_lock=try_lock_internal(m2,m3,m4))
{
return failed_lock+1;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4,typename MutexType5>
unsigned try_lock_internal(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4,MutexType5& m5)
{
boost::unique_lock<MutexType1> l1(m1,boost::try_to_lock);
if(!l1)
{
return 1;
}
if(unsigned const failed_lock=try_lock_internal(m2,m3,m4,m5))
{
return failed_lock+1;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2>
unsigned lock_helper(MutexType1& m1,MutexType2& m2)
{
boost::unique_lock<MutexType1> l1(m1);
if(!m2.try_lock())
{
return 1;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3>
unsigned lock_helper(MutexType1& m1,MutexType2& m2,MutexType3& m3)
{
boost::unique_lock<MutexType1> l1(m1);
if(unsigned const failed_lock=try_lock_internal(m2,m3))
{
return failed_lock;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4>
unsigned lock_helper(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4)
{
boost::unique_lock<MutexType1> l1(m1);
if(unsigned const failed_lock=try_lock_internal(m2,m3,m4))
{
return failed_lock;
}
l1.release();
return 0;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4,typename MutexType5>
unsigned lock_helper(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4,MutexType5& m5)
{
boost::unique_lock<MutexType1> l1(m1);
if(unsigned const failed_lock=try_lock_internal(m2,m3,m4,m5))
{
return failed_lock;
}
l1.release();
return 0;
}
}
namespace detail
{
template<bool x>
struct is_mutex_type_wrapper
{};
template<typename MutexType1,typename MutexType2>
void lock_impl(MutexType1& m1,MutexType2& m2,is_mutex_type_wrapper<true>)
{
unsigned const lock_count=2;
unsigned lock_first=0;
while(true)
{
switch(lock_first)
{
case 0:
lock_first=detail::lock_helper(m1,m2);
if(!lock_first)
return;
break;
case 1:
lock_first=detail::lock_helper(m2,m1);
if(!lock_first)
return;
lock_first=(lock_first+1)%lock_count;
break;
}
}
}
template<typename Iterator>
void lock_impl(Iterator begin,Iterator end,is_mutex_type_wrapper<false>);
}
template<typename MutexType1,typename MutexType2>
void lock(MutexType1& m1,MutexType2& m2)
{
detail::lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
void lock(const MutexType1& m1,MutexType2& m2)
{
detail::lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
void lock(MutexType1& m1,const MutexType2& m2)
{
detail::lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
void lock(const MutexType1& m1,const MutexType2& m2)
{
detail::lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2,typename MutexType3>
void lock(MutexType1& m1,MutexType2& m2,MutexType3& m3)
{
unsigned const lock_count=3;
unsigned lock_first=0;
while(true)
{
switch(lock_first)
{
case 0:
lock_first=detail::lock_helper(m1,m2,m3);
if(!lock_first)
return;
break;
case 1:
lock_first=detail::lock_helper(m2,m3,m1);
if(!lock_first)
return;
lock_first=(lock_first+1)%lock_count;
break;
case 2:
lock_first=detail::lock_helper(m3,m1,m2);
if(!lock_first)
return;
lock_first=(lock_first+2)%lock_count;
break;
}
}
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4>
void lock(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4)
{
unsigned const lock_count=4;
unsigned lock_first=0;
while(true)
{
switch(lock_first)
{
case 0:
lock_first=detail::lock_helper(m1,m2,m3,m4);
if(!lock_first)
return;
break;
case 1:
lock_first=detail::lock_helper(m2,m3,m4,m1);
if(!lock_first)
return;
lock_first=(lock_first+1)%lock_count;
break;
case 2:
lock_first=detail::lock_helper(m3,m4,m1,m2);
if(!lock_first)
return;
lock_first=(lock_first+2)%lock_count;
break;
case 3:
lock_first=detail::lock_helper(m4,m1,m2,m3);
if(!lock_first)
return;
lock_first=(lock_first+3)%lock_count;
break;
}
}
}
template<typename MutexType1,typename MutexType2,typename MutexType3,
typename MutexType4,typename MutexType5>
void lock(MutexType1& m1,MutexType2& m2,MutexType3& m3,
MutexType4& m4,MutexType5& m5)
{
unsigned const lock_count=5;
unsigned lock_first=0;
while(true)
{
switch(lock_first)
{
case 0:
lock_first=detail::lock_helper(m1,m2,m3,m4,m5);
if(!lock_first)
return;
break;
case 1:
lock_first=detail::lock_helper(m2,m3,m4,m5,m1);
if(!lock_first)
return;
lock_first=(lock_first+1)%lock_count;
break;
case 2:
lock_first=detail::lock_helper(m3,m4,m5,m1,m2);
if(!lock_first)
return;
lock_first=(lock_first+2)%lock_count;
break;
case 3:
lock_first=detail::lock_helper(m4,m5,m1,m2,m3);
if(!lock_first)
return;
lock_first=(lock_first+3)%lock_count;
break;
case 4:
lock_first=detail::lock_helper(m5,m1,m2,m3,m4);
if(!lock_first)
return;
lock_first=(lock_first+4)%lock_count;
break;
}
}
}
namespace detail
{
template<typename Mutex,bool x=is_mutex_type<Mutex>::value>
struct try_lock_impl_return
{
typedef int type;
};
template<typename Iterator>
struct try_lock_impl_return<Iterator,false>
{
typedef Iterator type;
};
template<typename MutexType1,typename MutexType2>
int try_lock_impl(MutexType1& m1,MutexType2& m2,is_mutex_type_wrapper<true>)
{
return ((int)detail::try_lock_internal(m1,m2))-1;
}
template<typename Iterator>
Iterator try_lock_impl(Iterator begin,Iterator end,is_mutex_type_wrapper<false>);
}
template<typename MutexType1,typename MutexType2>
typename detail::try_lock_impl_return<MutexType1>::type try_lock(MutexType1& m1,MutexType2& m2)
{
return detail::try_lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
typename detail::try_lock_impl_return<MutexType1>::type try_lock(const MutexType1& m1,MutexType2& m2)
{
return detail::try_lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
typename detail::try_lock_impl_return<MutexType1>::type try_lock(MutexType1& m1,const MutexType2& m2)
{
return detail::try_lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2>
typename detail::try_lock_impl_return<MutexType1>::type try_lock(const MutexType1& m1,const MutexType2& m2)
{
return detail::try_lock_impl(m1,m2,detail::is_mutex_type_wrapper<is_mutex_type<MutexType1>::value>());
}
template<typename MutexType1,typename MutexType2,typename MutexType3>
int try_lock(MutexType1& m1,MutexType2& m2,MutexType3& m3)
{
return ((int)detail::try_lock_internal(m1,m2,m3))-1;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,typename MutexType4>
int try_lock(MutexType1& m1,MutexType2& m2,MutexType3& m3,MutexType4& m4)
{
return ((int)detail::try_lock_internal(m1,m2,m3,m4))-1;
}
template<typename MutexType1,typename MutexType2,typename MutexType3,typename MutexType4,typename MutexType5>
int try_lock(MutexType1& m1,MutexType2& m2,MutexType3& m3,MutexType4& m4,MutexType5& m5)
{
return ((int)detail::try_lock_internal(m1,m2,m3,m4,m5))-1;
}
namespace detail
{
template<typename Iterator>
struct range_lock_guard
{
Iterator begin;
Iterator end;
range_lock_guard(Iterator begin_,Iterator end_):
begin(begin_),end(end_)
{
lock(begin,end);
}
void release()
{
begin=end;
}
~range_lock_guard()
{
for(;begin!=end;++begin)
{
begin->unlock();
}
}
};
template<typename Iterator>
Iterator try_lock_impl(Iterator begin,Iterator end,is_mutex_type_wrapper<false>)
{
if(begin==end)
{
return end;
}
typedef typename std::iterator_traits<Iterator>::value_type lock_type;
unique_lock<lock_type> guard(*begin,try_to_lock);
if(!guard.owns_lock())
{
return begin;
}
Iterator const failed=try_lock(++begin,end);
if(failed==end)
{
guard.release();
}
return failed;
}
}
namespace detail
{
template<typename Iterator>
void lock_impl(Iterator begin,Iterator end,is_mutex_type_wrapper<false>)
{
typedef typename std::iterator_traits<Iterator>::value_type lock_type;
if(begin==end)
{
return;
}
bool start_with_begin=true;
Iterator second=begin;
++second;
Iterator next=second;
for(;;)
{
unique_lock<lock_type> begin_lock(*begin,defer_lock);
if(start_with_begin)
{
begin_lock.lock();
Iterator const failed_lock=try_lock(next,end);
if(failed_lock==end)
{
begin_lock.release();
return;
}
start_with_begin=false;
next=failed_lock;
}
else
{
detail::range_lock_guard<Iterator> guard(next,end);
if(begin_lock.try_lock())
{
Iterator const failed_lock=try_lock(second,next);
if(failed_lock==next)
{
begin_lock.release();
guard.release();
return;
}
start_with_begin=false;
next=failed_lock;
}
else
{
start_with_begin=true;
next=second;
}
}
}
}
}
}
#include <boost/config/abi_suffix.hpp>
#endif