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//========================================================================== // // sched/mlqueue.cxx // // Multi-level queue scheduler class implementation // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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 2 or (at your option) any later version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): nickg // Contributors: jlarmour // Date: 1999-02-17 // Purpose: Multilevel queue scheduler class implementation // Description: This file contains the implementations of // Cyg_Scheduler_Implementation and // Cyg_SchedThread_Implementation. // // //####DESCRIPTIONEND#### // //========================================================================== #include <pkgconf/kernel.h> #include <cyg/kernel/ktypes.h> // base kernel types #include <cyg/infra/cyg_trac.h> // tracing macros #include <cyg/infra/cyg_ass.h> // assertion macros #include <cyg/kernel/sched.hxx> // our header #include <cyg/hal/hal_arch.h> // Architecture specific definitions #include <cyg/kernel/thread.inl> // thread inlines #include <cyg/kernel/sched.inl> // scheduler inlines #ifdef CYGSEM_KERNEL_SCHED_MLQUEUE //========================================================================== // Cyg_Scheduler_Implementation class static members #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE cyg_ucount32 Cyg_Scheduler_Implementation::timeslice_count[CYGNUM_KERNEL_CPU_MAX]; #endif //========================================================================== // Cyg_Scheduler_Implementation class members // ------------------------------------------------------------------------- // Constructor. Cyg_Scheduler_Implementation::Cyg_Scheduler_Implementation() { CYG_REPORT_FUNCTION(); queue_map = 0; #ifdef CYGPKG_KERNEL_SMP_SUPPORT pending_map = 0; for( int i = 0; i < CYGNUM_KERNEL_SCHED_PRIORITIES; i++ ) pending[i] = 0; #endif for( int i = 0; i < CYGNUM_KERNEL_CPU_MAX; i++ ) { #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE timeslice_count[i] = CYGNUM_KERNEL_SCHED_TIMESLICE_TICKS; #endif need_reschedule[i] = true; } CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Choose the best thread to run next Cyg_Thread * Cyg_Scheduler_Implementation::schedule(void) { CYG_REPORT_FUNCTYPE("returning thread %08x"); // The run queue may _never_ be empty, there is always // an idle thread at the lowest priority. CYG_ASSERT( queue_map != 0, "Run queue empty"); CYG_ASSERT( queue_map & (1<<CYG_THREAD_MIN_PRIORITY), "Idle thread vanished!!!"); CYG_ASSERT( !run_queue[CYG_THREAD_MIN_PRIORITY].empty(), "Idle thread vanished!!!"); #ifdef CYGPKG_KERNEL_SMP_SUPPORT Cyg_Thread *current = get_current_thread(); register cyg_uint32 index; CYG_ASSERT( current->cpu != CYG_KERNEL_CPU_NONE, "Current thread does not have CPU set!"); // If the current thread is still runnable, return it to pending // state so that it can be considered alongside any other threads // for execution. if( current->get_state() == Cyg_Thread::RUNNING ) { current->cpu = CYG_KERNEL_CPU_NONE; pending[current->priority]++; pending_map |= (1<<current->priority); } else { // Otherwise, ensure that the thread is no longer marked as // running. current->cpu = CYG_KERNEL_CPU_NONE; } HAL_LSBIT_INDEX(index, pending_map); Cyg_RunQueue *queue = &run_queue[index]; CYG_ASSERT( !queue->empty(), "Queue for index empty"); CYG_ASSERT( pending[index] > 0, "Pending array and map disagree"); Cyg_Thread *thread = queue->get_head(); // We know there is a runnable thread in this queue, If the thread // we got is not it, scan until we find it. While not constant time, // this search has an upper bound of the number of CPUs in the system. while( thread->cpu != CYG_KERNEL_CPU_NONE ) thread = thread->get_next(); // Take newly scheduled thread out of pending map thread->cpu = CYG_KERNEL_CPU_THIS(); if( --pending[index] == 0 ) pending_map &= ~(1<<index); #else register cyg_uint32 index; HAL_LSBIT_INDEX(index, queue_map); Cyg_RunQueue *queue = &run_queue[index]; CYG_ASSERT( !queue->empty(), "Queue for index empty"); Cyg_Thread *thread = queue->get_head(); #endif CYG_INSTRUMENT_MLQ( SCHEDULE, thread, index); CYG_ASSERT( thread != NULL , "No threads in run queue"); CYG_ASSERT( thread->queue == NULL , "Runnable thread on a queue!"); CYG_REPORT_RETVAL(thread); return thread; } // ------------------------------------------------------------------------- void Cyg_Scheduler_Implementation::add_thread(Cyg_Thread *thread) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); cyg_priority pri = thread->priority; Cyg_RunQueue *queue = &run_queue[pri]; CYG_INSTRUMENT_MLQ( ADD, thread, pri); CYG_ASSERT((CYG_THREAD_MIN_PRIORITY >= pri) && (CYG_THREAD_MAX_PRIORITY <= pri), "Priority out of range!"); CYG_ASSERT( ((queue_map & (1<<pri))!=0) == ((!run_queue[pri].empty())!=0), "Map and queue disagree"); // If the thread is on some other queue, remove it // here. if( thread->queue != NULL ) { thread->queue->remove(thread); } if( queue->empty() ) { // set the map bit and ask for a reschedule if this is a // new highest priority thread. queue_map |= (1<<pri); } // else the queue already has an occupant, queue behind him queue->add_tail(thread); // If the new thread is higher priority than any // current thread, request a reschedule. set_need_reschedule(thread); #ifdef CYGPKG_KERNEL_SMP_SUPPORT // If the thread is not currently running, increment the pending // count for the priority, and if necessary set the bit in the // pending map. if( thread->cpu == CYG_KERNEL_CPU_NONE ) { if( pending[pri]++ == 0 ) pending_map |= (1<<pri); } // Otherwise the pending count will be dealt with in schedule(). #endif CYG_ASSERT( thread->queue == NULL , "Runnable thread on a queue!"); CYG_ASSERT( queue_map != 0, "Run queue empty"); CYG_ASSERT( queue_map & (1<<pri), "Queue map bit not set for pri"); CYG_ASSERT( !run_queue[pri].empty(), "Queue for pri empty"); CYG_ASSERT( ((queue_map & (1<<pri))!=0) == ((!run_queue[pri].empty())!=0), "Map and queue disagree"); CYG_ASSERT( queue_map & (1<<CYG_THREAD_MIN_PRIORITY), "Idle thread vanished!!!"); CYG_ASSERT( !run_queue[CYG_THREAD_MIN_PRIORITY].empty(), "Idle thread vanished!!!"); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- void Cyg_Scheduler_Implementation::rem_thread(Cyg_Thread *thread) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); CYG_ASSERT( queue_map != 0, "Run queue empty"); cyg_priority pri = thread->priority; Cyg_RunQueue *queue = &run_queue[pri]; CYG_INSTRUMENT_MLQ( REM, thread, pri); CYG_ASSERT( pri != CYG_THREAD_MIN_PRIORITY, "Idle thread trying to sleep!"); CYG_ASSERT( !run_queue[CYG_THREAD_MIN_PRIORITY].empty(), "Idle thread vanished!!!"); #ifdef CYGPKG_KERNEL_SMP_SUPPORT if( thread->cpu == CYG_KERNEL_CPU_NONE ) { // If the thread is not running, then we need to adjust the // pending count array and map if necessary. if( --pending[pri] == 0 ) pending_map &= ~(1<<pri); } else { // If the target thread is currently running on a different // CPU, send a reschedule interrupt there to deschedule it. if( thread->cpu != CYG_KERNEL_CPU_THIS() ) CYG_KERNEL_CPU_RESCHEDULE_INTERRUPT( thread->cpu, 0 ); } // If the thread is current running on this CPU, then the pending // count will be dealt with in schedule(). #endif CYG_ASSERT( queue_map & (1<<pri), "Queue map bit not set for pri"); CYG_ASSERT( !run_queue[pri].empty(), "Queue for pri empty"); // remove thread from queue queue->remove(thread); if( queue->empty() ) { // If this was only thread in // queue, clear map. queue_map &= ~(1<<pri); } CYG_ASSERT( queue_map != 0, "Run queue empty"); CYG_ASSERT( queue_map & (1<<CYG_THREAD_MIN_PRIORITY), "Idle thread vanished!!!"); CYG_ASSERT( !run_queue[CYG_THREAD_MIN_PRIORITY].empty(), "Idle thread vanished!!!"); CYG_ASSERT( ((queue_map & (1<<pri))!=0) == ((!run_queue[pri].empty())!=0), "Map and queue disagree"); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Set the need_reschedule flag // This function overrides the definition in Cyg_Scheduler_Base and tests // for a reschedule condition based on the priorities of the given thread // and the current thread(s). void Cyg_Scheduler_Implementation::set_need_reschedule(Cyg_Thread *thread) { #ifndef CYGPKG_KERNEL_SMP_SUPPORT if( current_thread[0]->priority > thread->priority || current_thread[0]->get_state() != Cyg_Thread::RUNNING ) need_reschedule[0] = true; #else HAL_SMP_CPU_TYPE cpu_this = CYG_KERNEL_CPU_THIS(); HAL_SMP_CPU_TYPE cpu_count = CYG_KERNEL_CPU_COUNT(); // Start with current CPU. If we can do the job locally then // that is most efficient. Only go on to other CPUs if that is // not possible. for(int i = 0; i < cpu_count; i++) { HAL_SMP_CPU_TYPE cpu = (i + cpu_this) % cpu_count; // If a CPU is not already marked for rescheduling, and its // current thread is of lower priority than _thread_, then // set its need_reschedule flag. Cyg_Thread *cur = current_thread[cpu]; if( (!need_reschedule[cpu]) && (cur->priority > thread->priority) ) { need_reschedule[cpu] = true; if( cpu != cpu_this ) { // All processors other than this one need to be sent // a reschedule interrupt. CYG_INSTRUMENT_SMP( RESCHED_SEND, cpu, 0 ); CYG_KERNEL_CPU_RESCHEDULE_INTERRUPT( cpu, 0 ); } // Having notionally rescheduled _thread_ onto the cpu, we // now see if we can reschedule the former current thread of // that CPU onto another. thread = cur; } } #endif } // ------------------------------------------------------------------------- // Set up initial idle thread void Cyg_Scheduler_Implementation::set_idle_thread( Cyg_Thread *thread, HAL_SMP_CPU_TYPE cpu ) { // Make the thread the current thread for this CPU. current_thread[cpu] = thread; // This will insert the thread in the run queues and make it // available to execute. thread->resume(); #ifdef CYGPKG_KERNEL_SMP_SUPPORT thread->cpu = cpu; // In SMP, we need to take this thread out of the pending array // and map. cyg_priority pri = thread->priority; if( --pending[pri] == 0 ) pending_map &= ~(1<<pri); #endif } // ------------------------------------------------------------------------- // register thread with scheduler void Cyg_Scheduler_Implementation::register_thread(Cyg_Thread *thread) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); // No registration necessary in this scheduler CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // deregister thread void Cyg_Scheduler_Implementation::deregister_thread(Cyg_Thread *thread) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); // No registration necessary in this scheduler CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Test the given priority for uniqueness cyg_bool Cyg_Scheduler_Implementation::unique( cyg_priority priority) { CYG_REPORT_FUNCTYPE("returning %d"); CYG_REPORT_FUNCARG1("priority=%d", priority); // Priorities are not unique CYG_REPORT_RETVAL(true); return true; } //========================================================================== // Support for timeslicing option #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE // ------------------------------------------------------------------------- void Cyg_Scheduler_Implementation::timeslice(void) { #ifdef CYGDBG_KERNEL_TRACE_TIMESLICE CYG_REPORT_FUNCTION(); #endif #ifdef CYGPKG_KERNEL_SMP_SUPPORT HAL_SMP_CPU_TYPE cpu; HAL_SMP_CPU_TYPE cpu_count = CYG_KERNEL_CPU_COUNT(); HAL_SMP_CPU_TYPE cpu_this = CYG_KERNEL_CPU_THIS(); for( cpu = 0; cpu < cpu_count; cpu++ ) { if( --timeslice_count[cpu] == 0 ) if( cpu == cpu_this ) timeslice_cpu(); else CYG_KERNEL_CPU_TIMESLICE_INTERRUPT( cpu, 0 ); } #else if( --timeslice_count[CYG_KERNEL_CPU_THIS()] == 0 ) timeslice_cpu(); #endif #ifdef CYGDBG_KERNEL_TRACE_TIMESLICE CYG_REPORT_RETURN(); #endif } // ------------------------------------------------------------------------- void Cyg_Scheduler_Implementation::timeslice_cpu(void) { #ifdef CYGDBG_KERNEL_TRACE_TIMESLICE CYG_REPORT_FUNCTION(); #endif Cyg_Thread *thread = get_current_thread(); HAL_SMP_CPU_TYPE cpu_this = CYG_KERNEL_CPU_THIS(); CYG_ASSERT( queue_map != 0, "Run queue empty"); CYG_ASSERT( queue_map & (1<<CYG_THREAD_MIN_PRIORITY), "Idle thread vanished!!!"); #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE_ENABLE if( thread->timeslice_enabled && timeslice_count[cpu_this] == 0 ) #else if( timeslice_count[cpu_this] == 0 ) #endif { CYG_INSTRUMENT_SCHED(TIMESLICE,0,0); #ifdef CYGDBG_KERNEL_TRACE_TIMESLICE CYG_TRACE0( true, "quantum consumed, time to reschedule" ); #endif CYG_ASSERT( get_sched_lock() > 0 , "Timeslice called with zero sched_lock"); // Only try to rotate the run queue if the current thread is running. // Otherwise we are going to reschedule anyway. if( thread->get_state() == Cyg_Thread::RUNNING ) { Cyg_Scheduler *sched = &Cyg_Scheduler::scheduler; CYG_INSTRUMENT_MLQ( TIMESLICE, thread, 0); CYG_ASSERTCLASS( thread, "Bad current thread"); CYG_ASSERTCLASS( sched, "Bad scheduler"); cyg_priority pri = thread->priority; Cyg_RunQueue *queue = &sched->run_queue[pri]; #ifdef CYGPKG_KERNEL_SMP_SUPPORT // In SMP systems we set the head of the queue to point to // the thread immediately after the current // thread. schedule() will then pick that thread, or one // after it to run next. queue->to_head( thread->get_next() ); #else queue->rotate(); #endif if( queue->get_head() != thread ) sched->set_need_reschedule(); timeslice_count[cpu_this] = CYGNUM_KERNEL_SCHED_TIMESLICE_TICKS; } } CYG_ASSERT( queue_map & (1<<CYG_THREAD_MIN_PRIORITY), "Idle thread vanished!!!"); CYG_ASSERT( !run_queue[CYG_THREAD_MIN_PRIORITY].empty(), "Idle thread vanished!!!"); #ifdef CYGDBG_KERNEL_TRACE_TIMESLICE CYG_REPORT_RETURN(); #endif } // ------------------------------------------------------------------------- __externC void cyg_scheduler_timeslice_cpu(void) { Cyg_Scheduler::scheduler.timeslice_cpu(); } #endif //========================================================================== // Cyg_SchedThread_Implementation class members Cyg_SchedThread_Implementation::Cyg_SchedThread_Implementation ( CYG_ADDRWORD sched_info ) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("sched_info=%08x", sched_info); // Set priority to the supplied value. priority = (cyg_priority)sched_info; #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE_ENABLE // If timeslice_enabled exists, set it true by default timeslice_enabled = true; #endif #ifdef CYGPKG_KERNEL_SMP_SUPPORT cpu = CYG_KERNEL_CPU_NONE; #endif CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Yield the processor to another thread void Cyg_SchedThread_Implementation::yield(void) { CYG_REPORT_FUNCTION(); // Prevent preemption Cyg_Scheduler::lock(); Cyg_Thread *thread = CYG_CLASSFROMBASE(Cyg_Thread, Cyg_SchedThread_Implementation, this); // Only do this if this thread is running. If it is not, there // is no point. if( thread->get_state() == Cyg_Thread::RUNNING ) { // To yield we simply rotate the appropriate // run queue to the next thread and reschedule. CYG_INSTRUMENT_MLQ( YIELD, thread, 0); CYG_ASSERTCLASS( thread, "Bad current thread"); Cyg_Scheduler *sched = &Cyg_Scheduler::scheduler; CYG_ASSERTCLASS( sched, "Bad scheduler"); cyg_priority pri = thread->priority; Cyg_RunQueue *queue = &sched->run_queue[pri]; #ifdef CYGPKG_KERNEL_SMP_SUPPORT // In SMP systems we set the head of the queue to point to // the thread immediately after the current // thread. schedule() will then pick that thread, or one // after it to run next. queue->to_head( thread->get_next() ); #else queue->rotate(); #endif if( queue->get_head() != thread ) sched->set_need_reschedule(); #ifdef CYGSEM_KERNEL_SCHED_TIMESLICE // Reset the timeslice counter so that this thread gets a full // quantum. else Cyg_Scheduler::reset_timeslice_count(); #endif } // Unlock the scheduler and switch threads #ifdef CYGDBG_USE_ASSERTS // This test keeps the assertions in unlock_inner() happy if // need_reschedule was not set above. if( !Cyg_Scheduler::get_need_reschedule() ) Cyg_Scheduler::unlock(); else #endif Cyg_Scheduler::unlock_reschedule(); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Rotate the run queue at a specified priority. // (pri is the decider, not this, so the routine is static) void Cyg_SchedThread_Implementation::rotate_queue( cyg_priority pri ) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("priority=%d", pri); // Prevent preemption Cyg_Scheduler::lock(); Cyg_Scheduler *sched = &Cyg_Scheduler::scheduler; CYG_ASSERTCLASS( sched, "Bad scheduler"); Cyg_RunQueue *queue = &sched->run_queue[pri]; if ( !queue->empty() ) { queue->rotate(); sched->set_need_reschedule(); } // Unlock the scheduler and switch threads Cyg_Scheduler::unlock(); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- // Move this thread to the head of its queue // (not necessarily a scheduler queue) void Cyg_SchedThread_Implementation::to_queue_head( void ) { CYG_REPORT_FUNCTION(); // Prevent preemption Cyg_Scheduler::lock(); Cyg_Thread *thread = CYG_CLASSFROMBASE(Cyg_Thread, Cyg_SchedThread_Implementation, this); CYG_ASSERTCLASS( thread, "Bad current thread"); Cyg_ThreadQueue *q = thread->get_current_queue(); if( q != NULL ) q->to_head( thread ); else if( thread->in_list() ) { // If the queue pointer is NULL then it is on a run // queue. Move the thread to the head of it's priority list // and force a reschedule. Cyg_Scheduler *sched = &Cyg_Scheduler::scheduler; sched->run_queue[thread->priority].to_head( thread ); sched->set_need_reschedule( thread ); } // Unlock the scheduler and switch threads Cyg_Scheduler::unlock(); CYG_REPORT_RETURN(); } //========================================================================== // Cyg_ThreadQueue_Implementation class members // ------------------------------------------------------------------------- void Cyg_ThreadQueue_Implementation::enqueue(Cyg_Thread *thread) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); CYG_INSTRUMENT_MLQ( ENQUEUE, this, thread ); #ifdef CYGIMP_KERNEL_SCHED_SORTED_QUEUES // Insert the thread into the queue in priority order. Cyg_Thread *qhead = get_head(); if( qhead == NULL ) add_tail( thread ); else if( qhead == qhead->get_next() ) { // There is currently only one thread in the queue, join it // and adjust the queue pointer to point to the highest // priority of the two. If they are the same priority, // leave the pointer pointing to the oldest. qhead->insert( thread ); if( thread->priority < qhead->priority ) to_head(thread); } else { // There is more than one thread in the queue. First check // whether we are of higher priority than the head and if // so just jump in at the front. Also check whether we are // lower priority than the tail and jump onto the end. // Otherwise we really have to search the queue to find // our place. if( thread->priority < qhead->priority ) { qhead->insert( thread ); to_head(thread); } else if( thread->priority > get_tail()->priority ) { // We are lower priority than any thread in the queue, // go in at the end. add_tail( thread ); } else { // Search the queue. We do this backwards so that we // always add new threads after any that have the same // priority. // Because of the previous tests we know that this // search will terminate before we hit the head of the // queue, hence we do not need to check for that // condition. Cyg_Thread *qtmp = get_tail(); // Scan the queue until we find a higher or equal // priority thread. while( thread->priority > qtmp->priority ) qtmp = qtmp->get_prev(); // Append ourself after the node pointed to by qtmp. qtmp->append( thread ); } } #else // Just add the thread to the tail of the list add_tail( thread ); #endif thread->queue = CYG_CLASSFROMBASE(Cyg_ThreadQueue, Cyg_ThreadQueue_Implementation, this); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- Cyg_Thread * Cyg_ThreadQueue_Implementation::dequeue(void) { CYG_REPORT_FUNCTYPE("returning thread %08x"); Cyg_Thread *thread = rem_head(); CYG_INSTRUMENT_MLQ( DEQUEUE, this, thread ); if( thread != NULL ) thread->queue = NULL; CYG_REPORT_RETVAL(thread); return thread; } // ------------------------------------------------------------------------- void Cyg_ThreadQueue_Implementation::remove( Cyg_Thread *thread ) { CYG_REPORT_FUNCTION(); CYG_REPORT_FUNCARG1("thread=%08x", thread); CYG_INSTRUMENT_MLQ( REMOVE, this, thread ); thread->queue = NULL; Cyg_CList_T<Cyg_Thread>::remove( thread ); CYG_REPORT_RETURN(); } // ------------------------------------------------------------------------- Cyg_Thread * Cyg_ThreadQueue_Implementation::highpri(void) { CYG_REPORT_FUNCTYPE("returning thread %08x"); CYG_REPORT_RETVAL(get_head()); return get_head(); } // ------------------------------------------------------------------------- inline void Cyg_ThreadQueue_Implementation::set_thread_queue(Cyg_Thread *thread, Cyg_ThreadQueue *tq ) { thread->queue = tq; } // ------------------------------------------------------------------------- #endif // ------------------------------------------------------------------------- // EOF sched/mlqueue.cxx
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