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[/] [open8_urisc/] [trunk/] [gnu/] [binutils/] [gold/] [gold-threads.cc] - Rev 160
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// gold-threads.cc -- thread support for gold // Copyright 2006, 2007, 2008, 2009, 2010 Free Software Foundation, Inc. // Written by Ian Lance Taylor <iant@google.com>. // This file is part of gold. // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 3 of the License, or // (at your option) any later version. // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, // MA 02110-1301, USA. #include "gold.h" #include <cstring> #ifdef ENABLE_THREADS #include <pthread.h> #endif #include "options.h" #include "parameters.h" #include "gold-threads.h" namespace gold { class Condvar_impl_nothreads; // The non-threaded version of Lock_impl. class Lock_impl_nothreads : public Lock_impl { public: Lock_impl_nothreads() : acquired_(false) { } ~Lock_impl_nothreads() { gold_assert(!this->acquired_); } void acquire() { gold_assert(!this->acquired_); this->acquired_ = true; } void release() { gold_assert(this->acquired_); this->acquired_ = false; } private: friend class Condvar_impl_nothreads; bool acquired_; }; #ifdef ENABLE_THREADS class Condvar_impl_threads; // The threaded version of Lock_impl. class Lock_impl_threads : public Lock_impl { public: Lock_impl_threads(); ~Lock_impl_threads(); void acquire(); void release(); private: // This class can not be copied. Lock_impl_threads(const Lock_impl_threads&); Lock_impl_threads& operator=(const Lock_impl_threads&); friend class Condvar_impl_threads; pthread_mutex_t mutex_; }; Lock_impl_threads::Lock_impl_threads() { pthread_mutexattr_t attr; int err = pthread_mutexattr_init(&attr); if (err != 0) gold_fatal(_("pthead_mutextattr_init failed: %s"), strerror(err)); #ifdef PTHREAD_MUTEX_ADAPTIVE_NP err = pthread_mutextattr_settype(&attr, PTHREAD_MUTEX_ADAPTIVE_NP); if (err != 0) gold_fatal(_("pthread_mutextattr_settype failed: %s"), strerror(err)); #endif err = pthread_mutex_init(&this->mutex_, &attr); if (err != 0) gold_fatal(_("pthread_mutex_init failed: %s"), strerror(err)); err = pthread_mutexattr_destroy(&attr); if (err != 0) gold_fatal(_("pthread_mutexattr_destroy failed: %s"), strerror(err)); } Lock_impl_threads::~Lock_impl_threads() { int err = pthread_mutex_destroy(&this->mutex_); if (err != 0) gold_fatal(_("pthread_mutex_destroy failed: %s"), strerror(err)); } void Lock_impl_threads::acquire() { int err = pthread_mutex_lock(&this->mutex_); if (err != 0) gold_fatal(_("pthread_mutex_lock failed: %s"), strerror(err)); } void Lock_impl_threads::release() { int err = pthread_mutex_unlock(&this->mutex_); if (err != 0) gold_fatal(_("pthread_mutex_unlock failed: %s"), strerror(err)); } #endif // defined(ENABLE_THREADS) // Class Lock. Lock::Lock() { if (!parameters->options().threads()) this->lock_ = new Lock_impl_nothreads; else { #ifdef ENABLE_THREADS this->lock_ = new Lock_impl_threads; #else gold_unreachable(); #endif } } Lock::~Lock() { delete this->lock_; } // The non-threaded version of Condvar_impl. class Condvar_impl_nothreads : public Condvar_impl { public: Condvar_impl_nothreads() { } ~Condvar_impl_nothreads() { } void wait(Lock_impl* li) { gold_assert(static_cast<Lock_impl_nothreads*>(li)->acquired_); } void signal() { } void broadcast() { } }; #ifdef ENABLE_THREADS // The threaded version of Condvar_impl. class Condvar_impl_threads : public Condvar_impl { public: Condvar_impl_threads(); ~Condvar_impl_threads(); void wait(Lock_impl*); void signal(); void broadcast(); private: // This class can not be copied. Condvar_impl_threads(const Condvar_impl_threads&); Condvar_impl_threads& operator=(const Condvar_impl_threads&); pthread_cond_t cond_; }; Condvar_impl_threads::Condvar_impl_threads() { int err = pthread_cond_init(&this->cond_, NULL); if (err != 0) gold_fatal(_("pthread_cond_init failed: %s"), strerror(err)); } Condvar_impl_threads::~Condvar_impl_threads() { int err = pthread_cond_destroy(&this->cond_); if (err != 0) gold_fatal(_("pthread_cond_destroy failed: %s"), strerror(err)); } void Condvar_impl_threads::wait(Lock_impl* li) { Lock_impl_threads* lit = static_cast<Lock_impl_threads*>(li); int err = pthread_cond_wait(&this->cond_, &lit->mutex_); if (err != 0) gold_fatal(_("pthread_cond_wait failed: %s"), strerror(err)); } void Condvar_impl_threads::signal() { int err = pthread_cond_signal(&this->cond_); if (err != 0) gold_fatal(_("pthread_cond_signal failed: %s"), strerror(err)); } void Condvar_impl_threads::broadcast() { int err = pthread_cond_broadcast(&this->cond_); if (err != 0) gold_fatal(_("pthread_cond_broadcast failed: %s"), strerror(err)); } #endif // defined(ENABLE_THREADS) // Methods for Condvar class. Condvar::Condvar(Lock& lock) : lock_(lock) { if (!parameters->options().threads()) this->condvar_ = new Condvar_impl_nothreads; else { #ifdef ENABLE_THREADS this->condvar_ = new Condvar_impl_threads; #else gold_unreachable(); #endif } } Condvar::~Condvar() { delete this->condvar_; } #ifdef ENABLE_THREADS // Class Once_initialize. This exists to hold a pthread_once_t // structure for Once. class Once_initialize { public: Once_initialize() : once_(PTHREAD_ONCE_INIT) { } // Return a pointer to the pthread_once_t variable. pthread_once_t* once_control() { return &this->once_; } private: pthread_once_t once_; }; #endif // defined(ENABLE_THREADS) #ifdef ENABLE_THREADS // A single lock which controls access to once_pointer. This is used // because we can't pass parameters to functions passed to // pthread_once. static pthread_mutex_t once_pointer_control = PTHREAD_MUTEX_INITIALIZER; // A pointer to Once structure we want to run. Access to this is // controlled by once_pointer_control. static Once* once_pointer; // The argument to pass to the Once structure. Access to this is // controlled by once_pointer_control. static void* once_arg; // A routine passed to pthread_once which runs the Once pointer. extern "C" { static void c_run_once(void) { once_pointer->internal_run(once_arg); } } #endif // defined(ENABLE_THREADS) // Class Once. Once::Once() : was_run_(false), was_run_lock_(0) { #ifndef ENABLE_THREADS this->once_ = NULL; #else this->once_ = new Once_initialize(); #endif } // Run the function once. void Once::run_once(void* arg) { #ifndef ENABLE_THREADS // If there is no threads support, we don't need to use pthread_once. if (!this->was_run_) this->internal_run(arg); #else // defined(ENABLE_THREADS) if (parameters->options_valid() && !parameters->options().threads()) { // If we are not using threads, we don't need to lock. if (!this->was_run_) this->internal_run(arg); return; } // If we have the sync builtins, use them to skip the lock if the // value has already been initialized. #ifdef __GCC_HAVE_SYNC_COMPARE_AND_SWAP_4 while (true) { if (__sync_bool_compare_and_swap(&this->was_run_lock_, 0, 1)) break; } bool was_run = this->was_run_; while (true) { if (__sync_bool_compare_and_swap(&this->was_run_lock_, 1, 0)) break; } if (was_run) return; #endif // Since we can't pass parameters to routines called by // pthread_once, we use a static variable: once_pointer. This in // turns means that we need to use a mutex to control access to // once_pointer. int err = pthread_mutex_lock(&once_pointer_control); if (err != 0) gold_fatal(_("pthread_mutex_lock failed: %s"), strerror(err)); once_pointer = this; once_arg = arg; err = pthread_once(this->once_->once_control(), c_run_once); if (err != 0) gold_fatal(_("pthread_once failed: %s"), strerror(err)); once_pointer = NULL; once_arg = NULL; err = pthread_mutex_unlock(&once_pointer_control); if (err != 0) gold_fatal(_("pthread_mutex_unlock failed: %s"), strerror(err)); #endif // defined(ENABLE_THREADS) } // Actually run the function in the child class. This function will // be run only once. void Once::internal_run(void* arg) { this->do_run_once(arg); this->was_run_ = true; } // Class Initialize_lock. // Initialize the lock. bool Initialize_lock::initialize() { // We can't initialize the lock until we have read the options. if (!parameters->options_valid()) return false; else { this->run_once(NULL); return true; } } // Initialize the lock exactly once. void Initialize_lock::do_run_once(void*) { *this->pplock_ = new Lock(); } } // End namespace gold.
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