source: trunk/kernel/libk/remote_barrier.c @ 24

/*
 * remote_barrier.c - Access a POSIX barrier.
 * 
 * Author   Alain Greiner (2016,2017)
 *
 * Copyright (c) UPMC Sorbonne Universites
 *
 * This file is part of ALMOS-MKH.
 *
 * ALMOS-MKH 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; version 2.0 of the License.
 *
 * ALMOS-MKH 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 ALMOS-MKH; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
 */

#include <hal_types.h>
#include <hal_remote.h>
#include <hal_irqmask.h>
#include <remote_spinlock.h>
#include <thread.h>
#include <kmem.h>
#include <printk.h>
#include <process.h>
#include <vmm.h>
#include <remote_barrier.h>

/////////////////////////////////////////////////
inline void remote_barrier( xptr_t    barrier_xp,
                            uint32_t  count ) 
{
    uint32_t  expected;

    remote_barrier_t * ptr = (remote_barrier_t *)GET_PTR( barrier_xp );
    cxy_t              cxy = GET_CXY( barrier_xp );

    // get barrier sense value
    uint32_t sense = hal_remote_lw( XPTR( cxy , &ptr->sense ) );

        // compute expected value
    if ( sense == 0 ) expected = 1;
    else              expected = 0;

    // atomically increment current 
    uint32_t current = hal_remote_atomic_add( XPTR( cxy , &ptr->current ) , 1 );

    // last task reset current and toggle sense
    if( current == (count-1) ) 
    {
        hal_remote_sw( XPTR( cxy , &ptr->current) , 0 );  
        hal_remote_sw( XPTR( cxy , &ptr->sense  ) , expected );  
    }
    else   // other tasks poll the sense 
    {
        while( hal_remote_lw( XPTR( cxy , &ptr->sense ) ) != expected ) asm volatile ("nop");
    }
}

///////////////////////////////////////////////////
xptr_t remote_barrier_from_ident( intptr_t  ident )
{
    // get pointer on local process_descriptor
    process_t * process = CURRENT_THREAD->process;

    // get extended pointer on reference process
    xptr_t      ref_xp = process->ref_xp;

    // get cluster and local pointer on reference process 
    cxy_t          ref_cxy = GET_CXY( ref_xp );
    process_t    * ref_ptr = (process_t *)GET_PTR( ref_xp );

    // get extended pointer on root of barriers list 
    xptr_t root_xp = XPTR( ref_cxy , &ref_ptr->barrier_root );
   
    // scan reference process barriers list
    xptr_t             iter_xp;
    xptr_t             barrier_xp;
    cxy_t              barrier_cxy;
    remote_barrier_t * barrier_ptr;
    intptr_t           current;
    bool_t             found = false;
            
    XLIST_FOREACH( root_xp , iter_xp )
    {
        barrier_xp  = XLIST_ELEMENT( iter_xp , remote_barrier_t , list );
        barrier_cxy = GET_CXY( barrier_xp );
        barrier_ptr = (remote_barrier_t *)GET_PTR( barrier_xp );
        current     = (intptr_t)hal_remote_lpt( XPTR( barrier_cxy , &barrier_ptr->ident ) );   
        if( ident == current )
        {
            found = true;
            break;
        }
    }

    if( found == false )  return XPTR_NULL;
    else                  return barrier_xp;

}  // end remote_barrier_from_ident()

//////////////////////////////////////////////
error_t remote_barrier_create( intptr_t ident,
                               uint32_t count )
{
    xptr_t             barrier_xp;
    remote_barrier_t * barrier_ptr;

    // get pointer on local process descriptor
    process_t * process = CURRENT_THREAD->process;

    // get extended pointer on reference process
    xptr_t      ref_xp = process->ref_xp;

    // get reference process cluster and local pointer
    cxy_t       ref_cxy = GET_CXY( ref_xp );
    process_t * ref_ptr = (process_t *)GET_PTR( ref_xp );

    // allocate memory for barrier descriptor
    if( ref_cxy == local_cxy )                  // local cluster is the reference 
    {
        kmem_req_t req;   
        req.type      = KMEM_BARRIER;
        req.flags     = AF_ZERO;
        barrier_ptr   = kmem_alloc( &req );
        barrier_xp    = XPTR( local_cxy , barrier_ptr );
    }
    else                                       // reference is remote
    {
        rpc_kcm_alloc_client( ref_cxy , KMEM_BARRIER , &barrier_xp );
        barrier_ptr = (remote_barrier_t *)GET_PTR( barrier_xp );
    }

    if( barrier_ptr == NULL ) return ENOMEM;

    // initialise barrier 
    hal_remote_sw ( XPTR( ref_cxy , &barrier_ptr->nb_threads ) , count );
    hal_remote_sw ( XPTR( ref_cxy , &barrier_ptr->current    ) , 0 );
    hal_remote_sw ( XPTR( ref_cxy , &barrier_ptr->sense      ) , 0 );
    hal_remote_spt( XPTR( ref_cxy , &barrier_ptr->ident      ) , (void*)ident );

    xlist_entry_init( XPTR( ref_cxy , &barrier_ptr->list ) );

    // register  barrier in reference process xlist
    xptr_t root_xp  = XPTR( ref_cxy , &ref_ptr->barrier_root );
    xptr_t entry_xp = XPTR( ref_cxy , &barrier_ptr->list );

    remote_spinlock_lock( XPTR( ref_cxy , &ref_ptr->sync_lock ) );
    xlist_add_first( root_xp , entry_xp );
    remote_spinlock_unlock( XPTR( ref_cxy , &ref_ptr->sync_lock ) );

    return 0;

}  // end remote_barrier_create()

////////////////////////////////////////////////
void remote_barrier_destroy( xptr_t barrier_xp )
{
    // get pointer on local process descriptor
    process_t * process = CURRENT_THREAD->process;

    // get extended pointer on reference process
    xptr_t      ref_xp = process->ref_xp;

    // get reference process cluster and local pointer
    cxy_t       ref_cxy = GET_CXY( ref_xp );
    process_t * ref_ptr = (process_t *)GET_PTR( ref_xp );

    // get barrier cluster and local pointer
    cxy_t              barrier_cxy = GET_CXY( barrier_xp );
    remote_barrier_t * barrier_ptr = (remote_barrier_t *)GET_PTR( barrier_xp );

    // remove barrier from reference process xlist
    remote_spinlock_lock( XPTR( ref_cxy , &ref_ptr->sync_lock ) );
    xlist_unlink( XPTR( barrier_cxy , &barrier_ptr->list ) );
    remote_spinlock_unlock( XPTR( ref_cxy , &ref_ptr->sync_lock ) );

    // release memory allocated for barrier descriptor
    if( barrier_cxy == local_cxy )                        // reference is local
    {
        kmem_req_t  req;
        req.type = KMEM_BARRIER;
        req.ptr  = barrier_ptr;
        kmem_free( &req );
    }
    else                                                  // reference is remote
    {
        rpc_kcm_free_client( barrier_cxy , barrier_ptr , KMEM_BARRIER );
    }

}  // end remote_barrier_destroy()

/////////////////////////////////////////////
void remote_barrier_wait( xptr_t barrier_xp )
{
    uint32_t  expected;
    uint32_t  current;
    uint32_t  count;
    uint32_t  sense;
    uint32_t  irq_state;
    xptr_t    root_xp;

    // get cluster and local pointer on calling thread
    cxy_t              thread_cxy = local_cxy;
    thread_t         * thread_ptr = CURRENT_THREAD;

    // get cluster and local pointer on remote barrier
    remote_barrier_t * barrier_ptr = (remote_barrier_t *)GET_PTR( barrier_xp );
    cxy_t              barrier_cxy = GET_CXY( barrier_xp );

    // get count and root fields from barrier descriptor
    count   = hal_remote_lw ( XPTR( barrier_cxy , &barrier_ptr->nb_threads ) );
    root_xp = hal_remote_lwd( XPTR( barrier_cxy , &barrier_ptr->root ) );

    // get barrier sense value
    sense = hal_remote_lw( XPTR( barrier_cxy , &barrier_ptr->sense ) );

        // compute expected value
    if ( sense == 0 ) expected = 1;
    else              expected = 0;

    // atomically increment current 
    current = hal_remote_atomic_add( XPTR( barrier_cxy , &barrier_ptr->current ) , 1 );

    // last thread reset current, toggle sense, and activate all waiting threads
    // other threads block, register in queue, and deschedule 

    if( current == (count-1) )                       // last thread
    {
        hal_remote_sw( XPTR( barrier_cxy , &barrier_ptr->current) , 0 );  
        hal_remote_sw( XPTR( barrier_cxy , &barrier_ptr->sense  ) , expected );  

        // activate waiting threads if required
        if( xlist_is_empty( root_xp ) == false )  
        {
            // disable interrupts
                hal_disable_irq( &irq_state );
  
            xptr_t  iter_xp;
            xptr_t  thread_xp;
            XLIST_FOREACH( root_xp , iter_xp )
            {
                // get extended pointer on waiting thread
                thread_xp = XLIST_ELEMENT( iter_xp , thread_t , wait_list );
        
                // remove waiting thread from queue
                remote_spinlock_lock( XPTR( barrier_cxy , &barrier_ptr->lock ) );
                xlist_unlink( XPTR( barrier_cxy , &barrier_ptr->list ) );
                remote_spinlock_unlock( XPTR( barrier_cxy , &barrier_ptr->lock ) );

                // unblock waiting thread
                thread_unblock( thread_xp , THREAD_BLOCKED_USERSYNC ); 
            }

            // restore interrupts
            hal_restore_irq( irq_state );
        }
    }
    else                                             // not the last thread  
    {
        // disable interrupts
            hal_disable_irq( &irq_state );
  
        // register calling thread in barrier waiting queue
        xptr_t entry_xp = XPTR( thread_cxy , &thread_ptr->wait_list );

        remote_spinlock_lock( XPTR( barrier_cxy , &barrier_ptr->lock ) ); 
        xlist_add_last( root_xp , entry_xp );
        remote_spinlock_unlock( XPTR( barrier_cxy , &barrier_ptr->lock ) ); 

        // block & deschedule the calling thread   
        thread_block( thread_ptr , THREAD_BLOCKED_USERSYNC );
        sched_yield();

        // restore interrupts
        hal_restore_irq( irq_state );
    }
}  // end remote_barrier_wait()