Changeset 669 for trunk

Timestamp:

Nov 19, 2020, 11:44:34 PM (3 years ago)

Author:

alain

Message:

1) Introduce up to 4 command lines arguments in the KSH "load" command.
These arguments are transfered to the user process through the
argc/argv mechanism, using the user space "args" vseg.

2) Introduce the named and anonymous "pipes", for inter-process communication
through the pipe() and mkfifo() syscalls.

3) Introduce the "chat" application to validate the two above mechanisms.

4) Improve printk() and assert() fonctions in printk.c.

Location:

trunk/kernel/kern

Files:

• alarm.c (modified) (2 diffs)
• alarm.h (modified) (2 diffs)
• chdev.c (modified) (2 diffs)
• chdev.h (modified) (2 diffs)
• cluster.c (modified) (2 diffs)
• core.c (modified) (4 diffs)
• core.h (modified) (6 diffs)
• do_syscall.c (modified) (3 diffs)
• dqdt.c (modified) (3 diffs)
• kernel_init.c (modified) (6 diffs)
• ksocket.c (modified) (59 diffs)
• ksocket.h (modified) (3 diffs)
• pipe.c (added)
• pipe.h (added)
• printk.c (modified) (15 diffs)
• printk.h (modified) (2 diffs)
• process.c (modified) (59 diffs)
• process.h (modified) (13 diffs)
• rpc.c (modified) (2 diffs)
• scheduler.c (modified) (8 diffs)
• thread.c (modified) (18 diffs)
• thread.h (modified) (6 diffs)

trunk/kernel/kern/alarm.c

@@ -1 +1 @@
 /*
- * kern/time.c - thread time related management
- * 
- * Copyright (c) 2008,2009,2010,2011,2012 Ghassan Almaless
- * Copyright (c) 2011,2012 UPMC Sorbonne Universites
+ * alarm.c - timer based kernel alarm implementation            
  *
- * This file is part of ALMOS-kernel.
+ * Author     Alain Greiner (2016,2017,2018,2019,2020)
  *
- * ALMOS-kernel is free software; you can redistribute it and/or modify it
+ * 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-kernel is distributed in the hope that it will be useful, but
+ * 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
@@ -17 +18 @@
  *
  * You should have received a copy of the GNU General Public License
- * along with ALMOS-kernel; if not, write to the Free Software Foundation,
+ * along with ALMOS-MKH; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
  */
 
-#include <types.h>
+#include <kernel_config.h>
+#include <hal_kernel_types.h>
+#include <printk.h>
+#include <list.h>
 #include <thread.h>
-#include <task.h>
-#include <scheduler.h>
-#include <time.h>
-#include <list.h>
-#include <rt_timer.h>
-#include <kmagics.h>
+#include <core.h>
+#include <alarm.h>
 
-error_t alarm_wait(struct alarm_info_s *info, uint_t msec)
+////////////////////////////////////////////////////////////////////////////////////////////
+// This static function registers the alarm identified ny the <new_alarm> argument 
+// in the list of alarms rooted in the core identified by the <core> argument.
+// When the existing list of alarms is not empty, it scan the list to insert the new
+// alarm in the right place to respect the absolute dates ordering. 
+////////////////////////////////////////////////////////////////////////////////////////////
+// @ new_alarm  : local pointer on the new alarm.
+// @ core       : local pointer on the target core.
+////////////////////////////////////////////////////////////////////////////////////////////
+static void alarm_register( alarm_t * new_alarm,
+                            core_t  * core )
 {
-        register uint_t tm_now;
-        struct cpu_s *cpu;
-        struct alarm_s *alarm_mgr;
-        struct list_entry *iter;
-        struct alarm_info_s *current;
-        uint_t irq_state;
+    list_entry_t * current;          // pointer on current list_entry in existing list
+    list_entry_t * previous;         // pointer on previous list_entry in existing list
+    alarm_t      * current_alarm;    // pointer on current alarm in existing list
+    cycle_t        current_date;     // date of current alarm in existing list
 
-        cpu       = current_cpu;
-        alarm_mgr = &cpu->alarm_mgr;
+    bool_t         done = false;
 
-        cpu_disable_all_irq(&irq_state);
+    // get pointers on root of alarms and lock
+    list_entry_t * root = &core->alarms_root;
+    busylock_t   * lock = &core->alarms_lock;
 
-        tm_now          = cpu_get_ticks(cpu) * MSEC_PER_TICK;
-        info->signature = ALRM_INFO_ID;
-        info->tm_wakeup = tm_now + msec;
+    // get pointer on new_alarm list_entry 
+    list_entry_t * new_entry = &new_alarm->list;
 
-        if(list_empty(&alarm_mgr->wait_queue))
-                list_add_first(&alarm_mgr->wait_queue, &info->list);
-        else
-        {
-                list_foreach_forward(&alarm_mgr->wait_queue, iter)
-                {
-                        current = list_element(iter, struct alarm_info_s, list);
-      
-                        if(info->tm_wakeup <= current->tm_wakeup) 
-                        {
-                                list_add_pred(iter, &info->list);
-                                goto NEXT_TRAITMENT;
-                        }
-                }
-                list_add_last(&alarm_mgr->wait_queue, &info->list);
-        }
+    // get new_alarm date
+    cycle_t        new_date = new_alarm->date;
 
-NEXT_TRAITMENT:
-        cpu_restore_irq(irq_state);
-        return 0;
-}
+    // take the lock
+    busylock_acquire( lock );
 
-void alarm_clock(struct alarm_s *alarm, uint_t ticks_nr)
+    // insert new alarm to respect dates order
+    if( list_is_empty( root ) )                     // list empty
+    {
+        list_add_first( root , new_entry ); 
+    }
+    else                                            // list non empty
+    {
+        for( current = root->next ;
+             (current != root) && (done == false) ;
+             current = current->next )
+        {
+            // get pointer on previous entry in existing list
+            previous = current->pred;
+
+            // get pointer on current alarm 
+            current_alarm = LIST_ELEMENT( current , alarm_t , list );
+
+            // get date for current alarm 
+            current_date  = current_alarm->date;
+
+            if( current_date > new_date )  // insert new alarm just before current
+            {
+                new_entry->next = current;
+                new_entry->pred = previous;
+
+                current->pred  = new_entry;
+                previous->next = new_entry;
+                
+                done = true;
+            }
+        }  // end for
+        
+        if( done == false ) // new_date is larger than all registered dates
+        {
+            list_add_last( root , new_entry );
+        }
+    }
+
+    // release the lock
+    busylock_release( lock );
+
+}  // end alarm_register()
+
+//////////////////////////////////////
+void alarm_start( cycle_t    date,
+                  void     * func_ptr,
+                  xptr_t     args_xp,
+                  thread_t * thread )
 {
-        register uint_t tm_msec;
-        register struct list_entry *iter;
-        register struct alarm_info_s *info;
-  
-        tm_msec = ticks_nr * MSEC_PER_TICK;
+    // get pointer on alarm
+    alarm_t * alarm = &thread->alarm;
 
-        list_foreach_forward(&alarm->wait_queue, iter)
-        {
-                info = list_element(iter, struct alarm_info_s, list);
+    // initialize alarm descriptor
+    alarm->date     = date;
+    alarm->func_ptr = func_ptr;
+    alarm->args_xp = args_xp;
+    
+    // register alarm in core list
+    alarm_register( alarm , thread->core );
 
-                assert((info->signature == ALRM_INFO_ID), "Not an ALRM info object");
+}  // end alarm_start()
 
-                if(tm_msec < info->tm_wakeup)
-                        break;
+/////////////////////////////////////
+void alarm_update( thread_t * thread,
+                   cycle_t    new_date )
+{
+    // get pointer on alarm
+    alarm_t * alarm = &thread->alarm;
+
+    // get pointer on core 
+    core_t   * core = thread->core;
+
+    // get pointer on lock protecting the alarms list
+    busylock_t   * lock = &core->alarms_lock;
+
+    // unlink the alarm from the core list
+    busylock_acquire( lock );
+    list_unlink( &alarm->list );
+    busylock_release( lock );
+
+    // update the alarm date
+    alarm->date = new_date;
+
+    // register alarm in core list
+    alarm_register( alarm , core );
     
-                list_unlink(iter);
-                event_send(info->event, current_cpu->gid);
-        }
-}
+}  // end alarm_update()
 
-error_t alarm_manager_init(struct alarm_s *alarm)
+////////////////////////////////////
+void alarm_stop( thread_t * thread )
 {
-        list_root_init(&alarm->wait_queue);
-        return 0;
-}
+    // get pointer on alarm
+    alarm_t * alarm = &thread->alarm;
 
+    // get pointer on core 
+    core_t * core = thread->core;
 
-#if CONFIG_THREAD_TIME_STAT
+    // get pointer on lock protecting the alarms list
+    busylock_t * lock = &core->alarms_lock;
 
-inline void tm_sleep_compute(struct thread_s *thread)
-{
-        uint_t tm_now;
+    // unlink the alarm from the list rooted in core
+    busylock_acquire( lock );
+    list_unlink( &alarm->list );
+    busylock_release( lock );
 
-        if(thread->type == TH_IDLE)
-                return;
+}  // end alarm_stop()
 
-        rt_timer_read(&tm_now);
-        thread->info.tm_sleep += (tm_now - thread->info.tm_tmp);
-        thread->info.tm_tmp    = tm_now;
-}
-
-inline void tm_usr_compute(struct thread_s *thread)
-{ 
-        uint_t tm_now;
-
-        rt_timer_read(&tm_now);
-        thread->info.tm_usr += (tm_now - thread->info.tm_tmp);
-        thread->info.tm_tmp  = tm_now;
-}
-
-inline void tm_sys_compute(struct thread_s *thread)
-{ 
-        uint_t tm_now;
-
-        rt_timer_read(&tm_now);
-        thread->info.tm_sys += (tm_now - thread->info.tm_tmp);
-        thread->info.tm_tmp  = tm_now;
-}
-
-inline void tm_wait_compute(struct thread_s *thread)
-{
-        uint_t tm_now;
-
-        if(thread->type == TH_IDLE)
-                return;
-
-        rt_timer_read(&tm_now);
-        thread->info.tm_wait += (tm_now - thread->info.tm_tmp);
-        thread->info.tm_tmp   = tm_now;
-        thread->info.tm_exec  = tm_now;
-}
-
-inline void tm_exit_compute(struct thread_s *thread)
-{
-        uint_t tm_now;
-  
-        rt_timer_read(&tm_now);
-        thread->info.tm_sys += tm_now - thread->info.tm_tmp;
-        thread->info.tm_dead = tm_now;
-}
-
-inline void tm_born_compute(struct thread_s *thread)
-{
-        uint_t tm_now;
-  
-        rt_timer_read(&tm_now);
-        thread->info.tm_born = tm_now;
-        thread->info.tm_tmp  = tm_now;
-        thread->info.tm_exec = tm_now;
-}
-
-inline void tm_create_compute(struct thread_s *thread)
-{
-        rt_timer_read(&thread->info.tm_create);
-}
-
-
-#endif  /* CONFIG_THREAD_TIME_STAT */

trunk/kernel/kern/alarm.h

@@ -1 +1 @@
 /*
- * time.h: thread time related management
- * 
- * Copyright (c) 2008,2009,2010,2011,2012 Ghassan Almaless
- * Copyright (c) 2011,2012 UPMC Sorbonne Universites
+ * alarm.h - timer based kernel alarm specification            
  *
- * This file is part of ALMOS-kernel.
+ * Author     Alain Greiner (2016,2017,2018,2019,2020)
  *
- * ALMOS-kernel is free software; you can redistribute it and/or modify it
+ * 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-kernel is distributed in the hope that it will be useful, but
+ * 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
@@ -17 +18 @@
  *
  * You should have received a copy of the GNU General Public License
- * along with ALMOS-kernel; if not, write to the Free Software Foundation,
+ * along with ALMOS-MKH; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
  */
 
-#ifndef _TIME_H_
-#define _TIME_H_
 
-#include <types.h>
+#ifndef _ALARM_H_
+#define _ALARM_H_
+
+#include <hal_kernel_types.h>
 #include <list.h>
-#include <device.h>
 
-struct event_s;
+/****  Forward declarations  ****/
 
-struct alarm_info_s 
+struct  thread_s;
+
+/******************************************************************************************
+ *   This structure defines a generic, timer based, kernel alarm.
+ *
+ * - An alarm being attached to a given thread, the alarm descriptor is embedded in the
+ *   thread descriptor. A client thread can use the alarm_start() function to dynamically
+ *   activate the alarm. It can use the alarm_stop() function to desactivate this alarm.
+ * - This kernel alarm is generic, as the alarm handler (executed when the alarm rings),
+ *   and the handler arguments are defined by two pointers <func_ptr> and <args_xp>.
+ * - When an alarm is created by a client thread, it is registered in the list of alarms
+ *   rooted in the core running the client thread. When it is stopped, the alarm is simply
+ *   removed from this list.
+ * - When creating an alarm, the client thread must define an absolute date (in cycles),
+ *   the func_ptr local pointer, and the args_xp extended pointer.
+ * - The list of alarms is ordered by increasing dates. At each TICK received by a core,
+ *   the date of the first registered alarm is compared to the current date (in the 
+ *   core_clock() function). The alarm handler is executed when current_date >= alarm_date.
+ * - It is the handler responsability to stop a ringing alarm, or update the date.  
+ * 
+ * This mechanism is used bi the almos_mkh implementation of the TCP protocoL.
+ ******************************************************************************************/
+
+typedef struct alarm_s
 {
-        uint_t signature;
+    cycle_t        date;           /*! absolute date for handler execution                */
+    void         * func_ptr;       /*! local pointer on alarm handler function            */
+    xptr_t         args_xp;        /*! local pointer on handler arguments                 */
+    list_entry_t   list;           /*! all alarms attached to the same core               */
+}
+alarm_t;
 
-        /* Public members */
-        struct event_s *event;
+/*******************************************************************************************
+ * This defines the generic prototype for an alarm handler.
+ ******************************************************************************************/
 
-        /* Private members */
-        uint_t tm_wakeup;
-        struct list_entry list;
-};
+typedef void (alarm_handler_t) ( xptr_t args_xp );
 
-struct alarm_s
-{ 
-        struct list_entry wait_queue;
-};
+/*******************************************************************************************
+ * This function initializes the alarm descriptor embedded in the thread identified by the
+ * <thread> argument from the <date>, <func_ptr>, <args_ptr> arguments, and registers it
+ * in the ordered list rooted in the core running this <thread>.
+ *******************************************************************************************
+ * @ date       : absolute date (in cycles).
+ * @ func_ptr   : local pointer on the handler to execute when the alarm rings.
+ * @ args_xp    : extended pointer on the handler arguments.
+ * @ thread     : local pointer on the client thread.
+ ******************************************************************************************/
+void alarm_start( cycle_t           date,
+                  void            * func_ptr,
+                  xptr_t            args_xp,
+                  struct thread_s * thread );
+
+/*******************************************************************************************
+ * This function updates the date of the alarm attached to the thread identified by the
+ * <thread> argument. The list of alarms rooted in the core running the client thread 
+ * is modified to respect the absolute dates ordering.
+ *******************************************************************************************
+ * @ thread     : local pointer on the client thread.
+ * @ new_date   : absolute new date (in cycles).
+ ******************************************************************************************/
+void alarm_update( struct thread_s * thread,
+                   cycle_t           new_date );
+
+/*******************************************************************************************
+ * This function unlink an alarm identified by the <thread> argument from the list of
+ * alarms rooted in the core descriptor.
+ *******************************************************************************************
+ * @ thread     : local pointer on the client thread.
+ ******************************************************************************************/
+void alarm_stop( struct thread_s * thread );
 
 
-struct timeb {
-        time_t         time;
-        unsigned short millitm;
-        short          timezone;
-        short          dstflag;
-};
-
-struct timeval {
-        clock_t tv_sec;    /* secondes */
-        clock_t tv_usec;   /* microsecondes */
-};
-
-struct timezone {
-        int tz_minuteswest;     /* minutes west of Greenwich */
-        int tz_dsttime;         /* type of DST correction */
-};
-
-
-struct tms 
-{
-       clock_t tms_utime;  /* user time */
-       clock_t tms_stime;  /* system time */
-       clock_t tms_cutime; /* user time of children */
-       clock_t tms_cstime; /* system time of children */
-};
-
-
-error_t alarm_manager_init(struct alarm_s *alarm);
-error_t alarm_wait(struct alarm_info_s *info, uint_t msec);
-
-void alarm_clock(struct alarm_s *alarm, uint_t ticks_nr);
-
-int sys_clock (uint64_t *val);
-int sys_alarm (unsigned nb_sec);
-int sys_ftime (struct timeb *utime);
-int sys_times(struct tms *utms);
-int sys_gettimeofday(struct timeval *tv, struct timezone *tz);
-
-#if CONFIG_THREAD_TIME_STAT
-struct thread_s;
-inline void tm_sleep_compute(struct thread_s *thread);
-inline void tm_usr_compute(struct thread_s *thread);
-inline void tm_sys_compute(struct thread_s *thread);
-inline void tm_wait_compute(struct thread_s *thread);
-inline void tm_exit_compute(struct thread_s *thread);
-inline void tm_born_compute(struct thread_s *thread);
-inline void tm_create_compute(struct thread_s *thread);
-
-#else
-
-#define tm_sleep_compute(thread)
-#define tm_usr_compute(thread)
-#define tm_sys_compute(thread)
-#define tm_wait_compute(thread)
-#define tm_exit_compute(thread)
-#define tm_born_compute(thread)
-#define tm_create_compute(thread)
-
-#endif  /* CONFIG_SCHED_STAT */
-
-#endif  /* _TIME_H_ */
+#endif  /* _ALARM_H_ */

trunk/kernel/kern/chdev.c

@@ -450 +450 @@
     chdev_t     * chdev_ptr;
 
-    assert( (file_xp != XPTR_NULL) ,
+    assert( __FUNCTION__, (file_xp != XPTR_NULL) ,
     "file_xp == XPTR_NULL\n" );
 
@@ -462 +462 @@
     inode_ptr  = (vfs_inode_t *)hal_remote_lpt( XPTR( file_cxy , &file_ptr->inode ) );
 
-    assert( (inode_type == INODE_TYPE_DEV) ,
-    "inode type %d is not INODE_TYPE_DEV\n", inode_type );
+    assert( __FUNCTION__, (inode_type == FILE_TYPE_DEV) ,
+    "inode type %d is not FILE_TYPE_DEV\n", inode_type );
 
     // get chdev local pointer from inode extension

trunk/kernel/kern/chdev.h

@@ -66 +66 @@
 
 /****************************************************************************************
- * This define the generic prototypes for the three functions that must be defined
- * by the drivers implementing a generic device:
+ * This defines the generic prototypes for the functions that must be defined
+ * by all drivers implementing a generic device:
  * - "cmd"     : start a blocking I/O operation.
  * - "isr"     : complete an I/O operation.
@@ -272 +272 @@
 /****************************************************************************************
  * This function returns an extended pointer on the chdev associated to a pseudo file
- * descriptor (type INODE_TYPE_DEV) identified by the <file_xp> argument.
+ * descriptor (type FILE_TYPE_DEV) identified by the <file_xp> argument.
  * It can be called by a thread running in any cluster.
  * It enters kernel panic if the inode has not the expected type.

trunk/kernel/kern/cluster.c

@@ -533 +533 @@
 
     // check lpid 
-    assert( (lpid < CONFIG_MAX_PROCESS_PER_CLUSTER),
+    assert( __FUNCTION__, (lpid < CONFIG_MAX_PROCESS_PER_CLUSTER),
     "illegal LPID = %d" , lpid );
 
     // check owner cluster
-    assert( (owner_cxy == local_cxy) ,
+    assert( __FUNCTION__, (owner_cxy == local_cxy) ,
     "local_cluster %x !=  owner_cluster %x" , local_cxy , owner_cxy );
 
@@ -732 +732 @@
     uint32_t      pref_nr;       // number of owned processes in cluster cxy
 
-assert( (cluster_is_active( cxy ) ), "illegal cluster index" );
+assert( __FUNCTION__, (cluster_is_active( cxy ) ), "illegal cluster index" );
 
     // get extended pointer on root and lock for local process list in cluster

trunk/kernel/kern/core.c

@@ -26 +26 @@
 #include <hal_kernel_types.h>
 #include <hal_special.h>
-#include <errno.h>
 #include <printk.h>
 #include <thread.h>
 #include <chdev.h>
+#include <alarm.h>
 #include <dev_pic.h>
 #include <rpc.h>
 #include <cluster.h>
 #include <kmem.h>
-#include <dqdt.h>
 #include <core.h>
 
@@ -52 +51 @@
         core->rand_last         = hal_time_stamp() & 0xFFF;
 
-    // initialize scheduler
+    // initialize the scheduler
         sched_init( core );
+
+    // initialise the alarms lock
+    busylock_init( &core->alarms_lock , LOCK_CORE_ALARMS );
+
+    // initialise the alarms list 
+    list_root_init( &core->alarms_root );
 }
+
+///////////////////////////////////////
+void core_check_alarms( core_t * core )
+{
+    alarm_handler_t * handler;
+
+    // get pointer on root of alarms list
+    list_entry_t * root = &core->alarms_root;
+
+    // does nothing if list is empty
+    if( list_is_empty( root ) ) return;
+
+    // get pointer on first alarm when list non empty
+    alarm_t * alarm = LIST_FIRST( root , alarm_t , list );
+
+    // get first alarm date
+    cycle_t alarm_date = alarm->date; 
+
+    // get current date
+    cycle_t current_date = hal_get_cycles();
+
+    if( current_date >= alarm_date )
+    {
+        // get pointer on registered alarm handler
+        handler = (alarm_handler_t *)alarm->func_ptr;
+
+        // call alarm handler
+        handler( alarm->args_xp );
+    }
+}   // end core_check_alarms()
 
 //////////////////////
@@ -73 +108 @@
     }
 
-    assert( false , "core not found" );
+    assert( __FUNCTION__, false , "core not found" );
+
+    return 0;
 }
 
@@ -104 +141 @@
         // handle scheduler
         if( (ticks % CONFIG_SCHED_TICKS_PER_QUANTUM) == 0 ) sched_yield( "TICK");
+
+    // handle alarms
+    core_check_alarms( core );
 }
 

trunk/kernel/kern/core.h

@@ -28 +28 @@
 #include <kernel_config.h>
 #include <hal_kernel_types.h>
+#include <busylock.h>
 #include <list.h>
 #include <rpc.h>
@@ -36 +37 @@
 struct thread_s;
 struct chdev_s;
-enum   pic_impl_e;
 
 /****************************************************************************************
@@ -54 +54 @@
         uint32_t            time_stamp;     /*! previous time stamp (read from register)   */
 
+    list_entry_t        alarms_root;    /*! root of list of attached alarms            */
+    busylock_t          alarms_lock;    /*! lock protecting the list of alarms         */
+
         uint32_t            ticks_nr;       /*! number of elapsed ticks                    */
         uint32_t            usage;          /*! cumulated busy_percent (idle / total)      */
@@ -70 +73 @@
  * It makes the association [gid] <=> [lid], as defined in arch_info, via the
  * boot_info_t structure build by the bootloader in each cluster.
- * It allocates memory for the PIC infrastructure specific core extension.
- * It does NOT initialize the <thread_idle> and the <pic_extend> fields, 
- * that must be completed later.
+ * It initializes the core scheduler structures, and the alarms list and lock.
+ * It allocates memory for the PIC infrastructure specific core extension,
+ * but it does NOT initialize the <pic_extend> fields, that must be completed later.
  ***************************************************************************************
  * @ core      : pointer on core descriptor to initialise.
@@ -84 +87 @@
 /***************************************************************************************
  * This function returns the calling core local index (lid), making an associative
- * in the local core_tbl[] array based on the hardwired (gid).
+ * search in the local core_tbl[] array, based on the hardwired (gid).
  ***************************************************************************************
  * @ returns always the lid value.
@@ -113 +116 @@
 /***************************************************************************************
  * This function must be called at each TICK.
- * It updates the  cycles and ticks counter in the calling core descriptor.
- * It handles all pending alarms depending on the ticks counter value.
- * It handles the scheduling, depending on the ticks counter value.
- * It handles the global DQDT update, depending on the ticks counter vakue.
+ * - it updates the ticks counter in the calling core descriptor.
+ * - it checks the registered alarms depending on the ticks counter value.
+ * - it calls the scheduler, depending on the ticks counter value.
  ***************************************************************************************
  * @ core       : pointer on core descriptor.

trunk/kernel/kern/do_syscall.c

@@ -37 +37 @@
 int sys_undefined( void )
 {
-    assert( false , "undefined system call" );
+    assert( __FUNCTION__, false , "undefined system call" );
     return 0;
 }
@@ -199 +199 @@
         int  error = 0;
         
-    assert( (this == CURRENT_THREAD),
+    assert( __FUNCTION__, (this == CURRENT_THREAD),
     "wrong <this> argument\n" );
 
@@ -223 +223 @@
 
     // check kernel stack overflow
-    assert( (CURRENT_THREAD->signature == THREAD_SIGNATURE),
+    assert( __FUNCTION__, (CURRENT_THREAD->signature == THREAD_SIGNATURE),
     "kernel stack overflow after for thread %x in cluster %x\n", CURRENT_THREAD, local_cxy );
 

trunk/kernel/kern/dqdt.c

@@ -119 +119 @@
                                   xptr_t   parent_xp )
 {
-    assert( (level <= 5) , __FUNCTION__, "illegal DQDT level %d\n", level );
+    assert( __FUNCTION__, (level <= 5) , "illegal DQDT level\n" );
   
     uint32_t node_x;         // node X coordinate
@@ -344 +344 @@
     uint32_t    y_size  = cluster->y_size;
 
-    assert( ((x_size <= 16) && (y_size <= 16)) , "illegal mesh size\n");
+    assert( __FUNCTION__, ((x_size <= 16) && (y_size <= 16)) , "illegal mesh size\n");
  
     // compute level_max
@@ -533 +533 @@
     uint32_t      current_level;
 
-assert( (level <= 5) , __FUNCTION__, "illegal DQDT level %d\n", level );
+assert( __FUNCTION__, (level <= 5) , "illegal DQDT level\n" );
 
 #if DEBUG_DQDT_GET_ROOT

trunk/kernel/kern/kernel_init.c

@@ -140 +140 @@
     "KHM_STATE",             //  6
     "HTAB_STATE",            //  7
-
-    "VFS_CTX",               //  8
-    "PPM_FREE",              //  9
-    "THREAD_JOIN",           // 10
-    "XHTAB_STATE",           // 11
-    "CHDEV_QUEUE",           // 12
-    "CHDEV_TXT0",            // 13
-    "CHDEV_TXTLIST",         // 14
-    "PAGE_STATE",            // 15
-    "MUTEX_STATE",           // 16
-    "CONDVAR_STATE",         // 17
-    "SEM_STATE",             // 18
-    "PROCESS_CWD",           // 19
-    "BARRIER_STATE",         // 20
-    "LISTEN_SOCKET",         // 21
-
-    "CLUSTER_PREFTBL",       // 22
-
-    "SOCKET_STATE",          // 23
-    "PPM_DIRTY",             // 24
-    "CLUSTER_LOCALS",        // 25
-    "CLUSTER_COPIES",        // 26
-    "PROCESS_CHILDREN",      // 27
-    "PROCESS_USERSYNC",      // 28
-    "PROCESS_FDARRAY",       // 29
-    "PROCESS_DIR",           // 30
-    "VMM_VSL",               // 31
-
-    "PROCESS_THTBL",         // 32
-
-    "MAPPER_STATE",          // 33
-    "VFS_SIZE",              // 34
-    "VFS_FILE",              // 35
-    "VFS_MAIN",              // 36
-    "FATFS_FAT",             // 37
-    "FBF_WINDOWS",           // 38
+    "CORE_ALARMS",           //  8
+
+    "VFS_CTX",               //  9
+    "PPM_FREE",              // 10
+    "THREAD_JOIN",           // 11
+    "XHTAB_STATE",           // 12
+    "CHDEV_QUEUE",           // 13
+    "CHDEV_TXT0",            // 14
+    "CHDEV_TXTLIST",         // 15
+    "PAGE_STATE",            // 16
+    "MUTEX_STATE",           // 17
+    "CONDVAR_STATE",         // 18
+    "SEM_STATE",             // 19
+    "PROCESS_CWD",           // 20
+    "BARRIER_STATE",         // 21
+    "LISTEN_SOCKET",         // 22
+
+    "CLUSTER_PREFTBL",       // 23
+
+    "SOCKET_STATE",          // 24
+    "PPM_DIRTY",             // 25
+    "CLUSTER_LOCALS",        // 26
+    "CLUSTER_COPIES",        // 27
+    "PROCESS_CHILDREN",      // 28
+    "PROCESS_USERSYNC",      // 29
+    "PROCESS_FDARRAY",       // 30
+    "PROCESS_DIR",           // 31
+    "VMM_VSL",               // 32
+
+    "PROCESS_THTBL",         // 33
+
+    "MAPPER_STATE",          // 34
+    "VFS_SIZE",              // 35
+    "VFS_FILE",              // 36
+    "VFS_MAIN",              // 37
+    "FATFS_FAT",             // 38
+    "FBF_WINDOWS",           // 39
 };        
 
@@ -303 +304 @@
                                   LOCK_CHDEV_TXT0 );
             
+            // make TXT specific initialisations 
+            dev_txt_init( &txt0_tx_chdev );                 
+
             // initialize TXT_RX[0] chdev
             txt0_rx_chdev.func    = func;
@@ -313 +317 @@
             
             // make TXT specific initialisations 
-            dev_txt_init( &txt0_tx_chdev );                 
             dev_txt_init( &txt0_rx_chdev );
 
@@ -1228 +1231 @@
 
             hal_remote_s32( XPTR( CONFIG_VFS_ROOT_CXY , &vfs_root_inode_ptr->type ),
-                            INODE_TYPE_DIR );
+                            FILE_TYPE_DIR );
 
             hal_remote_spt( XPTR( CONFIG_VFS_ROOT_CXY , &vfs_root_inode_ptr->extend ), 
@@ -1372 +1375 @@
 
 // check local FATFS and VFS context copies
-assert( (((fatfs_ctx_t *)vfs_fat_ctx_ptr->extend)->sectors_per_cluster == 8),
-"illegal FATFS context in cluster %x\n", local_cxy );
+assert( __FUNCTION__, (((fatfs_ctx_t *)vfs_fat_ctx_ptr->extend)->sectors_per_cluster == 8),
+"illegal FATFS context" );
 
         }
@@ -1468 +1471 @@
     if( (core_lid == 0) && (local_cxy == 0) ) 
     {
-       process_init_create();
+        process_init_create();
     }
 

trunk/kernel/kern/ksocket.c

@@ -34 +34 @@
 #include <thread.h>
 #include <vfs.h>
+#include <alarm.h>
+#include <dev_nic.h>
 #include <ksocket.h>
-#include <dev_nic.h>
 
 //////////////////////////////////////////////////////////////////////////////////////
@@ -127 +128 @@
 }
 
+///////////////////////////////////////////////////////////////////////////////////////////
+// This static function implements the alarm handler used by a TX client thread to
+// handle a retransmission timeout for a TX command (ACCEPT / CONNECT / CLOSE / SEND).
+// The <args_xp> argument is actually an extended pointer on the involved socket.
+// First, it updates the retransmission timeout. Then, it get the type of TX command, 
+// and request the NIC_TX server thread to re-send the unacknowledged segment. 
+///////////////////////////////////////////////////////////////////////////////////////////
+// @ args_xp    : extended pointer on the involved socket.
+///////////////////////////////////////////////////////////////////////////////////////////
+static void __attribute__((noinline)) socket_alarm_handler( xptr_t args_xp )
+{
+    // get cluster and local pointer on socket descriptor
+    socket_t * sock_ptr = GET_PTR( args_xp );
+    cxy_t      sock_cxy = GET_CXY( args_xp );
+
+    // get relevant infos from socket descriptor
+    uint32_t   tx_cmd    = hal_remote_l32( XPTR( sock_cxy , &sock_ptr->tx_cmd )); 
+    uint32_t   channel   = hal_remote_l32( XPTR( sock_cxy , &sock_ptr->nic_channel ));
+    xptr_t     thread_xp = hal_remote_l64( XPTR( sock_cxy , &sock_ptr->tx_client ));
+
+assert( __FUNCTION__, (thread_xp != XPTR_NULL), 
+"illegal tx_client field for a retransmission timeout" );
+
+    // get TX client thread cluster and local pointer
+    thread_t * thread_ptr = GET_PTR( thread_xp );
+    cxy_t      thread_cxy = GET_CXY( thread_xp );
+
+assert( __FUNCTION__, (thread_cxy == local_cxy),
+"the client thread must be running in the same cluster as the alarm handler" );
+
+    // get pointers on NIC_TX[index] chdev
+    xptr_t    tx_chdev_xp  = chdev_dir.nic_tx[channel];
+    chdev_t * tx_chdev_ptr = GET_PTR( tx_chdev_xp );
+    cxy_t     tx_chdev_cxy = GET_CXY( tx_chdev_xp );
+
+    // get pointers on NIC_TX[channel] server thread
+    thread_t * tx_server_ptr = hal_remote_lpt( XPTR( tx_chdev_cxy , &tx_chdev_ptr->server ));
+    xptr_t     tx_server_xp  = XPTR( tx_chdev_cxy , tx_server_ptr );
+
+    // update the date in alarm
+    alarm_update( thread_ptr , hal_get_cycles() + TCP_RETRANSMISSION_TIMEOUT );
+    
+    //////////////////////////////
+    if( tx_cmd == CMD_TX_CONNECT )  
+    {
+
+#if DEBUG_SOCKET_ALARM
+uint32_t cycle = (uint32_t)hal_get_cycles();
+printk("\n[%s] rings for TX_CONNECT : request a new SYN segment / cycle %d\n",
+__FUNCTION__ , cycle );
+#endif
+        // set tx_valid to request the NIC_TX server to send a new SYN segment
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->tx_valid ) , true );
+
+        // update socket state
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->state ) , TCP_STATE_BOUND );
+
+        // unblock the NIC_TX server thread 
+        thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
+    }
+    /////////////////////////////
+    if( tx_cmd == CMD_TX_ACCEPT )  
+    {
+
+#if DEBUG_SOCKET_ALARM
+uint32_t cycle = (uint32_t)hal_get_cycles();
+printk("\n[%s] rings for TX_ACCEPT : request a new SYN-ACK segment / cycle %d\n",
+__FUNCTION__ , cycle );
+#endif
+        // set tx_valid to request the NIC_TX server to send a new SYN-ACK segment
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->tx_valid ) , true );
+
+        // update socket state
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->state ) , TCP_STATE_SYN_RCVD );
+
+        // unblock the NIC_TX server thread 
+        thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
+    }
+    ////////////////////////////
+    if( tx_cmd == CMD_TX_CLOSE )
+    {
+
+#if DEBUG_SOCKET_ALARM
+uint32_t cycle = (uint32_t)hal_get_cycles();
+printk("\n[%s] rings for TX_CLOSE : request a new FIN-ACK segment / cycle %d\n",
+__FUNCTION__ , cycle );
+#endif
+        // set tx_valid to request the NIC_TX server to send a new FIN-ACK segment
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->tx_valid ) , true );
+
+        // update socket state
+        hal_remote_s32( XPTR( sock_cxy , &sock_ptr->state ) , TCP_STATE_ESTAB );
+
+        // unblock the NIC_TX server thread 
+        thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
+    }
+    ///////////////////////////
+    if( tx_cmd == CMD_TX_SEND )
+    {
+        // TODO build a new TX_SEND command
+    }
+}   // end socket_alarm_handler()
+
+///////////////////////////////////////////////////////////////////////////////////////////
+// This static function activates the alarm embedded in the calling thread descriptor,
+// using the <date> argument.
+///////////////////////////////////////////////////////////////////////////////////////////
+// @ delay   : number of cycles (from the current absolute date).
+///////////////////////////////////////////////////////////////////////////////////////////
+static void socket_alarm_start( xptr_t   socket_xp,
+                                uint32_t delay )
+{
+    // compute absolute date
+    cycle_t date = hal_get_cycles() + delay; 
+
+    // get pointer on calling threadf
+    thread_t * this = CURRENT_THREAD;
+
+    // start the alarm
+    alarm_start( date,
+                 &socket_alarm_handler,   // func_ptr
+                 socket_xp,               // args_xp
+                 this );
+}
+
+///////////////////////////////////////////////////////////////////////////////////////////
+// This static function activates the alarm embedded in the calling thread descriptor,
+// using the <date> argument.
+///////////////////////////////////////////////////////////////////////////////////////////
+// @ date   : absolute date for this alarm.
+///////////////////////////////////////////////////////////////////////////////////////////
+static void socket_alarm_stop( void )
+{
+    // get pointer on calling threadf
+    thread_t * this = CURRENT_THREAD;
+
+    // stop the alarm
+    alarm_stop( this );
+}
+
 /////////////////////////////////////////////////////////////////////////////////////////
 // This static function registers the socket defined by the <socket_xp> argument into
@@ -222 +363 @@
 
     // build various TX extended pointers 
-    xptr_t    tx_lock_xp = XPTR( tx_chdev_cxy , &tx_chdev_ptr->wait_lock );
-    xptr_t    tx_list_xp = XPTR( socket_cxy   , &socket_ptr->tx_list );
+    xptr_t    tx_lock_xp   = XPTR( tx_chdev_cxy , &tx_chdev_ptr->wait_lock );
+    xptr_t    tx_list_xp   = XPTR( socket_cxy   , &socket_ptr->tx_list );
+    xptr_t    tx_list_next = hal_remote_l64( tx_list_xp );
+    xptr_t    tx_list_pred = hal_remote_l64( tx_list_xp + sizeof(xptr_t) );
 
     // get pointers on NIC_RX[channel] chdev
@@ -231 +374 @@
 
     // build various RX extended pointers
-    xptr_t    rx_lock_xp = XPTR( rx_chdev_cxy , &rx_chdev_ptr->wait_lock );
-    xptr_t    rx_list_xp = XPTR( socket_cxy   , &socket_ptr->rx_list );
-
-    // remove socket from the NIC_TX[channel] chdev clients queue
-    remote_busylock_acquire( tx_lock_xp );
-    xlist_unlink( tx_list_xp );
-    remote_busylock_release( tx_lock_xp );
-
-    // remove socket from the NIC_RX[channel] chdev clients queue
-    remote_busylock_acquire( rx_lock_xp );
-    xlist_unlink( rx_list_xp );
-    remote_busylock_release( rx_lock_xp );
+    xptr_t    rx_lock_xp   = XPTR( rx_chdev_cxy , &rx_chdev_ptr->wait_lock );
+    xptr_t    rx_list_xp   = XPTR( socket_cxy   , &socket_ptr->rx_list );
+    xptr_t    rx_list_next = hal_remote_l64( rx_list_xp );
+    xptr_t    rx_list_pred = hal_remote_l64( rx_list_xp + sizeof(xptr_t) );
+
+    // remove socket from the NIC_TX[channel] chdev clients queue if registered
+    if( (tx_list_next != XPTR_NULL) || (tx_list_pred != XPTR_NULL) )
+    {
+        remote_busylock_acquire( tx_lock_xp );
+        xlist_unlink( tx_list_xp );
+        remote_busylock_release( tx_lock_xp );
+    }
+
+    // remove socket from the NIC_RX[channel] chdev clients queue if registered
+    if( (rx_list_next != XPTR_NULL) || (rx_list_pred != XPTR_NULL) )
+    {
+        remote_busylock_acquire( rx_lock_xp );
+        xlist_unlink( rx_list_xp );
+        remote_busylock_release( rx_lock_xp );
+    }
 
 #if DEBUG_SOCKET_LINK
@@ -253 +404 @@
 }  // end socket_unlink_from_servers()
         
+/////////////////////////////////////////////////////////////////////////////////////////
+// This function registers the socket defined by the <socket_xp> argument into the
+// list of listening sockets rooted in the nic_rx[0] chdev.
+/////////////////////////////////////////////////////////////////////////////////////////
+// @ socket_xp   : [in]  extended pointer on socket descriptor
+/////////////////////////////////////////////////////////////////////////////////////////
+static void socket_link_to_listen( xptr_t socket_xp )
+{
+    // get socket cluster and local pointer
+    socket_t * socket_ptr = GET_PTR( socket_xp );
+    cxy_t      socket_cxy = GET_CXY( socket_xp );
+
+    // get pointers on NIC_RX[0] chdev
+    xptr_t    rx0_chdev_xp  = chdev_dir.nic_rx[0];
+    chdev_t * rx0_chdev_ptr = GET_PTR( rx0_chdev_xp );
+    cxy_t     rx0_chdev_cxy = GET_CXY( rx0_chdev_xp );
+   
+    // build extended pointers on list of listening sockets
+    xptr_t    rx0_root_xp = XPTR( rx0_chdev_cxy , &rx0_chdev_ptr->ext.nic.root );
+    xptr_t    rx0_lock_xp = XPTR( rx0_chdev_cxy , &rx0_chdev_ptr->ext.nic.lock );
+
+    // build extended pointer on socket rx_list field
+    xptr_t    list_entry_xp = XPTR( socket_cxy , &socket_ptr->rx_list );
+
+    // register socket in listening sockets list
+    remote_busylock_acquire( rx0_lock_xp );
+    xlist_add_last( rx0_root_xp , list_entry_xp );
+    remote_busylock_release( rx0_lock_xp );
+
+}  // end socket_link_to_listen()
+
+/////////////////////////////////////////////////////////////////////////////////////////
+// This function removes the socket defined by the <socket_xp> argument from the
+// list of listening sockets rooted in the nic_rx[0] chdev.
+/////////////////////////////////////////////////////////////////////////////////////////
+// @ socket_xp   : [in]  extended pointer on socket descriptor
+/////////////////////////////////////////////////////////////////////////////////////////
+static void socket_unlink_from_listen( xptr_t socket_xp )
+{
+    // get socket cluster and local pointer
+    socket_t * socket_ptr = GET_PTR( socket_xp );
+    cxy_t      socket_cxy = GET_CXY( socket_xp );
+
+    // get pointers on NIC_RX[0] chdev
+    xptr_t    rx0_chdev_xp  = chdev_dir.nic_rx[0];
+    chdev_t * rx0_chdev_ptr = GET_PTR( rx0_chdev_xp );
+    cxy_t     rx0_chdev_cxy = GET_CXY( rx0_chdev_xp );
+   
+    // build extended pointers on lock protecting list of listening sockets
+    xptr_t    rx0_lock_xp = XPTR( rx0_chdev_cxy , &rx0_chdev_ptr->ext.nic.lock );
+
+    // build extended pointer on socket rx_list field
+    xptr_t    list_entry_xp = XPTR( socket_cxy , &socket_ptr->rx_list );
+
+    // register socket in listening sockets list
+    remote_busylock_acquire( rx0_lock_xp );
+    xlist_unlink( list_entry_xp );
+    remote_busylock_release( rx0_lock_xp );
+
+}  // end socket_unlink_from_listen()
+
 /////////////////////////////////////////////////////////////////////////////////////////
 // This static function is called by the socket_build() and socket_accept() functions.
@@ -276 +488 @@
                               uint32_t  * fdid_ptr )
 {
-    uint32_t    fdid;
-
-    thread_t  * this    = CURRENT_THREAD;
-    process_t * process = this->process;
-
+    uint32_t       fdid;
     kmem_req_t     req;
     socket_t     * socket;
@@ -287 +495 @@
     error_t        error;
 
+    thread_t  * this    = CURRENT_THREAD;
+    process_t * process = this->process;
+
 #if DEBUG_SOCKET_CREATE
 uint32_t cycle = (uint32_t)hal_get_cycles();
@@ -294 +505 @@
 #endif
    
-    // allocate memory for socket descriptor 
+    // 1. allocate memory for socket descriptor 
     req.type   = KMEM_KCM;
     req.order  = bits_log2( sizeof(socket_t) );
@@ -307 +518 @@
     }
 
-    // allocate memory for rx_buf buffer
+    // 2. allocate memory for rx_buf buffer
     error = remote_buf_init( XPTR( cxy , &socket->rx_buf ),
-                             NIC_RX_BUF_SIZE );
+                             bits_log2( CONFIG_SOCK_RX_BUF_SIZE ) );
 
     if( error )
@@ -321 +532 @@
     }
 
-    // allocate memory for r2tq queue 
+    // 3. allocate memory for r2tq queue 
     error = remote_buf_init( XPTR( cxy , &socket->r2tq ),
-                             NIC_R2T_QUEUE_SIZE );
+                             bits_log2( CONFIG_SOCK_R2T_BUF_SIZE ) );
     if( error )
     {
         printk("\n[ERROR] in %s : cannot allocate R2T queue / thread[%x,%x]\n",
         __FUNCTION__, process->pid, this->trdid );
-        remote_buf_destroy( XPTR( cxy , &socket->rx_buf ) );
+        remote_buf_release_data( XPTR( cxy , &socket->rx_buf ) );
         req.type = KMEM_KCM;
         req.ptr  = socket;
@@ -337 +548 @@
     // don't allocate memory for crqq queue, as it is done by the socket_listen function
 
-    //  allocate memory for file descriptor
+    //  4. allocate memory for file descriptor
         req.type  = KMEM_KCM;
         req.order = bits_log2( sizeof(vfs_file_t) );
@@ -347 +558 @@
         printk("\n[ERROR] in %s : cannot allocate file descriptor / thread[%x,%x]\n",
         __FUNCTION__, process->pid, this->trdid );
-        remote_buf_destroy( XPTR( cxy , &socket->r2tq ) );
-        remote_buf_destroy( XPTR( cxy , &socket->rx_buf ) );
+        remote_buf_release_data( XPTR( cxy , &socket->r2tq ) );
+        remote_buf_release_data( XPTR( cxy , &socket->rx_buf ) );
         req.type = KMEM_KCM;
         req.ptr  = socket;
@@ -355 +566 @@
     }
     
-    // get an fdid value, and register file descriptor in fd_array[]
+    // 5. get an fdid value, and register file descriptor in fd_array[]
     error = process_fd_register( process->ref_xp,
                                  XPTR( cxy , file ),
@@ -366 +577 @@
         req.ptr  = file;
         kmem_free( &req );
-        remote_buf_destroy( XPTR( cxy , &socket->r2tq ) );
-        remote_buf_destroy( XPTR( cxy , &socket->rx_buf ) );
+        remote_buf_release_data( XPTR( cxy , &socket->r2tq ) );
+        remote_buf_release_data( XPTR( cxy , &socket->rx_buf ) );
         req.ptr  = socket;
         kmem_free( &req );
@@ -388 +599 @@
 
     // initialize file descriptor 
-    hal_remote_s32( XPTR( cxy , &file->type        ) , INODE_TYPE_SOCK );
+    hal_remote_s32( XPTR( cxy , &file->type        ) , FILE_TYPE_SOCK );
     hal_remote_spt( XPTR( cxy , &file->socket      ) , socket );
-    hal_remote_s32( XPTR( cxy , &file->refcount    ) , 1 );
 
     // initialize socket lock
@@ -414 +624 @@
 // It remove the associated file from the reference process fd_array. It unlink the
 // socket from the NIC_TX [k] and NIC_RX[k] chdevs. It release all memory allocated 
-// for the structures associated to the target socket socket : file descriptor,
-// socket descriptor, RX buffer, R2T queue, CRQ queue.
+// for the structures associated to the target socket : file descriptor, socket 
+// descriptor, RX buffer, R2T queue, CRQ queue.
 /////////////////////////////////////////////////////////////////////////////////////////
 // @ file_xp  : extended pointer on the file descriptor.
@@ -427 +637 @@
 
 // check file_xp argument 
-assert( (file_xp != XPTR_NULL), "illegal argument\n" );
+assert( __FUNCTION__, (file_xp != XPTR_NULL), "illegal argument\n" );
 
     // get cluster & local pointer for file descriptor
     vfs_file_t * file_ptr = GET_PTR( file_xp );
     cxy_t        file_cxy = GET_CXY( file_xp );
-
-#if DEBUG_SOCKET_DESTROY
-uint32_t cycle = (uint32_t)hal_get_cycles();
-if( DEBUG_SOCKET_DESTROY < cycle )
-printk("\n[%s] thread[%x,%x] enter / file[%x,%x] / cycle %d\n",
-__FUNCTION__, process->pid, this->trdid, file_cxy, file_ptr, cycle );
-#endif
 
     // get local pointer for socket and file type
@@ -445 +648 @@
     
 // check file descriptor type
-assert( (file_type == INODE_TYPE_SOCK), "illegal file type\n" );
-
-    // get socket nic_channel and fdid
-    uint32_t channel = hal_remote_l32( XPTR( file_cxy , &socket_ptr->nic_channel ));
+assert( __FUNCTION__, (file_type == FILE_TYPE_SOCK), "illegal file type\n" );
+
+    // get socket nic_channel, state, pid and fdid
+    uint32_t state   = hal_remote_l32( XPTR( file_cxy , &socket_ptr->state ));
     uint32_t fdid    = hal_remote_l32( XPTR( file_cxy , &socket_ptr->fdid ));
-
-    // remove socket from NIC_TX & NIC_RX chdev queues when socket is connected
-    if( channel < LOCAL_CLUSTER->nb_nic_channels )
+    
+#if DEBUG_SOCKET_DESTROY
+uint32_t cycle = (uint32_t)hal_get_cycles();
+pid_t    pid   = hal_remote_l32( XPTR( file_cxy , &socket_ptr->pid ));
+if( DEBUG_SOCKET_DESTROY < cycle )
+printk("\n[%s] thread[%x,%x] enter / file[%x,%x] / cycle %d\n",
+__FUNCTION__, process->pid, this->trdid, pid, fdid, cycle );
+#endif
+
+    // remove socket from NIC_TX & NIC_RX chdev queues
+    //  or from the listening sockets list
+    if( state == TCP_STATE_LISTEN ) 
+    {
+        socket_unlink_from_listen( XPTR( file_cxy , socket_ptr ) );
+    }
+    else
     {
         socket_unlink_from_servers( XPTR( file_cxy , socket_ptr ) );
@@ -466 +682 @@
 
     // release memory allocated for buffers attached to socket descriptor
-    remote_buf_destroy( XPTR( file_cxy , &socket_ptr->crqq ) );
-    remote_buf_destroy( XPTR( file_cxy , &socket_ptr->r2tq ) );
-    remote_buf_destroy( XPTR( file_cxy , &socket_ptr->rx_buf ) );
+    remote_buf_release_data( XPTR( file_cxy , &socket_ptr->crqq ) );
+    remote_buf_release_data( XPTR( file_cxy , &socket_ptr->r2tq ) );
+    remote_buf_release_data( XPTR( file_cxy , &socket_ptr->rx_buf ) );
 
     // release memory allocated for socket descriptor
@@ -619 +835 @@
                  uint16_t  port )
 {
-    vfs_inode_type_t    file_type;
+    vfs_file_type_t    file_type;
     socket_t          * socket;
     uint32_t            socket_type;
@@ -651 +867 @@
 
     // check file descriptor type
-    if( file_type != INODE_TYPE_SOCK )
+    if( file_type != FILE_TYPE_SOCK )
     {
         printk("\n[ERROR] in %s : illegal file type %s / thread[%x,%x]",
@@ -691 +907 @@
     vfs_file_t        * file_ptr;
     cxy_t               file_cxy;
-    vfs_inode_type_t    file_type;
+    vfs_file_type_t    file_type;
     socket_t          * socket_ptr;
     uint32_t            socket_type;
@@ -726 +942 @@
 
     // check file descriptor type
-    if( file_type != INODE_TYPE_SOCK )
+    if( file_type != FILE_TYPE_SOCK )
     {
         printk("\n[ERROR] in %s : illegal file type %s / thread[%x,%x]\n",
@@ -733 +949 @@
     }
 
-    // get relevant infos from <fdid> socket descriptor
+    // get relevant infos from socket descriptor
     socket_type       = hal_remote_l32( XPTR( file_cxy , &socket_ptr->type )); 
     socket_state      = hal_remote_l32( XPTR( file_cxy , &socket_ptr->state )); 
@@ -755 +971 @@
     }
     
-    // compute CRQ queue depth : max( crq_depth , NIC_CRQ_QUEUE_SIZE )
-    uint32_t depth = ( crq_depth > NIC_CRQ_QUEUE_SIZE ) ? crq_depth : NIC_CRQ_QUEUE_SIZE;
+    // compute CRQ queue depth : max( crq_depth , CONFIG_SOCK_CRQ_BUF_SIZE )
+    uint32_t depth = ( crq_depth > CONFIG_SOCK_CRQ_BUF_SIZE ) ? 
+                     crq_depth : CONFIG_SOCK_CRQ_BUF_SIZE;
 
     // allocate memory for the CRQ queue
     error = remote_buf_init( XPTR( file_cxy , &socket_ptr->crqq ),
-                                   depth * sizeof(connect_request_t) );
+                                   bits_log2( depth * sizeof(connect_request_t)) );
     if( error )
     {
@@ -771 +988 @@
     hal_remote_s32( XPTR( file_cxy , &socket_ptr->state ) , TCP_STATE_LISTEN );
 
-    // get pointers on NIC_RX[0] chdev
-    xptr_t    rx0_chdev_xp  = chdev_dir.nic_rx[0];
-    chdev_t * rx0_chdev_ptr = GET_PTR( rx0_chdev_xp );
-    cxy_t     rx0_chdev_cxy = GET_CXY( rx0_chdev_xp );
-   
-    // build extended pointers on list of listening sockets
-    xptr_t    rx0_root_xp = XPTR( rx0_chdev_cxy , &rx0_chdev_ptr->ext.nic.root );
-    xptr_t    rx0_lock_xp = XPTR( rx0_chdev_cxy , &rx0_chdev_ptr->ext.nic.lock );
-
-    // build extended pointer on socket rx_list field
-    xptr_t    list_entry_xp = XPTR( file_cxy , &socket_ptr->rx_list );
-
-    // register  <fdid> socket in listening sockets list
-    remote_busylock_acquire( rx0_lock_xp );
-    xlist_add_last( rx0_root_xp , list_entry_xp );
-    remote_busylock_release( rx0_lock_xp );
+    // register socket in the list of listening socket
+    socket_link_to_listen( XPTR( file_cxy , socket_ptr ) );
 
 #if DEBUG_SOCKET_LISTEN
@@ -808 +1011 @@
     vfs_file_t        * file_ptr;
     cxy_t               file_cxy;
-    vfs_inode_type_t    file_type;           // file descriptor type
+    vfs_file_type_t    file_type;           // file descriptor type
     socket_t          * socket_ptr;          // local pointer on remote waiting socket
     uint32_t            socket_type;         // listening socket type    
@@ -866 +1069 @@
 
     // check file descriptor type
-    if( file_type != INODE_TYPE_SOCK )
+    if( file_type != FILE_TYPE_SOCK )
     {
         printk("\n[ERROR] in %s : illegal file type %s / thread[%x,%x]\n",
@@ -976 +1179 @@
         crq_status   = remote_buf_status( crq_xp );
 
-assert( (((crq_status > 0) || (cmd_status!= CMD_STS_SUCCESS)) && (cmd_valid == false)),
+assert( __FUNCTION__, (((crq_status > 0) || (cmd_status!= CMD_STS_SUCCESS)) && (cmd_valid == false)),
 "illegal socket state when client thread resumes after RX_ACCEPT" );
 
@@ -999 +1202 @@
                                     &new_remote_window );
 
-assert( (error == 0),
+assert( __FUNCTION__, (error == 0),
 "cannot get a connection request from a non-empty CRQ" ); 
 
@@ -1082 +1285 @@
     // unblock NIC_TX server thread
     thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
- 
+  
+    // start retransmission timer
+    socket_alarm_start( new_socket_xp , TCP_RETRANSMISSION_TIMEOUT );
+
 #if DEBUG_SOCKET_ACCEPT
 cycle = (uint32_t)hal_get_cycles();
@@ -1100 +1306 @@
 __FUNCTION__, process->pid, this->trdid, process->pid, new_fdid, cycle );
 #endif
+
+    // stop retransmission timer
+    socket_alarm_stop();
 
     // get new socket state, tx_valid and tx_sts
@@ -1106 +1315 @@
     cmd_status = hal_remote_l32( XPTR( new_socket_cxy , &new_socket_ptr->tx_sts ));
 
-assert( (((new_state == TCP_STATE_ESTAB) || (cmd_status != CMD_STS_SUCCESS))
+assert( __FUNCTION__, (((new_state == TCP_STATE_ESTAB) || (cmd_status != CMD_STS_SUCCESS))
         && (cmd_valid == false)), 
 "illegal socket state when client thread resumes after TX_ACCEPT" ); 
@@ -1143 +1352 @@
                     uint16_t remote_port )
 {
-    vfs_inode_type_t    file_type;
-    socket_t          * socket_ptr;       // local pointer on thread descriptor
+    vfs_file_type_t    file_type;
+    xptr_t              socket_xp;        // extended pointer on socket descriptor
+    socket_t          * socket_ptr;       // local pointer on socket descriptor
     volatile uint32_t   socket_state;     // socket state (modified by the NIC_TX thread)
     uint32_t            socket_type;      // socket type  
@@ -1175 +1385 @@
     file_type  = hal_remote_l32( XPTR( file_cxy , &file_ptr->type ) );
     socket_ptr = hal_remote_lpt( XPTR( file_cxy , &file_ptr->socket ) );
+    socket_xp  = XPTR( file_cxy , socket_ptr );
 
 #if DEBUG_SOCKET_CONNECT
@@ -1184 +1395 @@
 
     // check file descriptor type
-    if( file_type != INODE_TYPE_SOCK )
+    if( file_type != FILE_TYPE_SOCK )
     {
         printk("\n[ERROR] in %s : illegal file type %s",
@@ -1263 +1474 @@
         thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
  
+        // start retransmission timer
+        socket_alarm_start( socket_xp , TCP_RETRANSMISSION_TIMEOUT );
+
 #if DEBUG_SOCKET_CONNECT
 cycle = (uint32_t)hal_get_cycles();
@@ -1279 +1493 @@
 __FUNCTION__, pid, trdid, pid, fdid, cycle );
 #endif
+
+        // stop retransmission timer
+        socket_alarm_stop();
 
         // get socket state, tx_valid and tx_sts
@@ -1285 +1502 @@
         socket_state = hal_remote_l32( XPTR( file_cxy , &socket_ptr->state ));
 
-assert( (((socket_state == TCP_STATE_ESTAB) || (cmd_status != CMD_STS_SUCCESS))
+assert( __FUNCTION__, (((socket_state == TCP_STATE_ESTAB) || (cmd_status != CMD_STS_SUCCESS))
         && (cmd_valid == false)),
 "illegal socket state when client thread resumes after TX_CONNECT" );
@@ -1331 +1548 @@
     trdid_t      trdid     = this->trdid;
 
-    // get pointer on socket descriptor
-    cxy_t        file_cxy    = GET_CXY( file_xp );
-    vfs_file_t * file_ptr    = GET_PTR( file_xp );
+    // get pointers on socket descriptor
+    cxy_t        file_cxy   = GET_CXY( file_xp );
+    vfs_file_t * file_ptr   = GET_PTR( file_xp );
     socket_t   * socket_ptr = hal_remote_lpt( XPTR( file_cxy , &file_ptr->socket ) );
-
-assert( (hal_remote_l32( XPTR( file_cxy , &socket_ptr->fdid )) == fdid),
+    xptr_t       socket_xp  = XPTR( file_cxy , socket_ptr );
+
+assert( __FUNCTION__, (hal_remote_l32( XPTR( file_cxy , &socket_ptr->fdid )) == fdid),
 "unconsistent file_xp & fdid arguments");
 
@@ -1380 +1598 @@
 cycle = (uint32_t)hal_get_cycles();
 if( cycle > DEBUG_DEV_NIC_TX )
-printk("\n[%s] thread[%x,%x] socket[%x,%d] %s / destroy socket / cycle %d\n",
+printk("\n[%s] thread[%x,%x] socket[%x,%d] %s => directly destroy socket / cycle %d\n",
 __FUNCTION__, pid, trdid, pid, fdid, socket_state_str( socket_state ), cycle );
 #endif
@@ -1396 +1614 @@
 cycle = (uint32_t)hal_get_cycles();
 if( cycle > DEBUG_DEV_NIC_TX )
-printk("\n[%s] thread[%x,%x] socket[%x,%d] %s / destroy socket / cycle %d\n",
+printk("\n[%s] thread[%x,%x] socket[%x,%d] %s => directly destroy socket / cycle %d\n",
 __FUNCTION__, pid, trdid, pid, fdid, socket_state_str( socket_state ), cycle );
 #endif
@@ -1420 +1638 @@
         hal_remote_s32( XPTR( file_cxy , &socket_ptr->tx_valid  ), true );
         
+        // release socket lock
+        remote_queuelock_release( socket_lock_xp );
+
         // unblock NIC_TX server thread
         thread_unblock( tx_server_xp , THREAD_BLOCKED_CLIENT );
- 
-        // release socket lock
-        remote_queuelock_release( socket_lock_xp );
+
+        // start retransmission timer
+        socket_alarm_start( socket_xp , TCP_RETRANSMISSION_TIMEOUT );
 
 #if DEBUG_SOCKET_CLOSE
 cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_SOCKET_CLOSE < cycle )
-printk("\n[%s] thread[%x,%x] socket[%x,%d] blocks on <IO> waiting close / cycle %d \n",
-__FUNCTION__, pid, trdid, pid, fdid, cycle );
-#endif
-        // block itself and deschedule
+printk("\n[%s] thread[%x,%x] socket[%x,%d] %s => blocks on <IO> waiting close / cycle %d \n",
+__FUNCTION__, pid, trdid, pid, fdid, socket_state_str( socket_state ), cycle );
+#endif
+        // client thread block itself and deschedule
         thread_block( client_xp , THREAD_BLOCKED_IO );
         sched_yield( "blocked in close" );
@@ -1442 +1663 @@
 __FUNCTION__, pid, trdid, pid, fdid, cycle );
 #endif
+        // stop retransmission timer
+        socket_alarm_stop();
+
         // take socket lock
         remote_queuelock_acquire( socket_lock_xp );
@@ -1450 +1674 @@
         cmd_valid    = hal_remote_l32( XPTR( file_cxy , &socket_ptr->tx_valid ) );
 
-assert( (((socket_state == TCP_STATE_CLOSED) || (cmd_status != CMD_STS_SUCCESS))
+assert( __FUNCTION__, (((socket_state == TCP_STATE_CLOSED) || (cmd_status != CMD_STS_SUCCESS))
          && (cmd_valid == false)),
 "illegal socket state when client thread resumes after TX_CLOSE\n"
@@ -1483 +1707 @@
 
 ////////////////////////////////////////////////////////////////////////////////////////
-// This static and blocking function is executed by an user thread calling one of the
-// four functions: socket_send() / socket_recv() / socket_sendto() / socket_recvfrom()
+// This static function is called by the two functions socket_send() & socket_recv().
 // It can be used for both UDP and TCP sockets.
 ////////////////////////////////////////////////////////////////////////////////////////
@@ -1491 +1714 @@
 // @ u_buf     : pointer on user buffer in user space.
 // @ length    : number of bytes.
-// @ explicit  : explicit remote IP address and port when true.
 ////////////////////////////////////////////////////////////////////////////////////////
 // Implementation note : The behavior is different for SEND & RECV
@@ -1512 +1734 @@
                       uint32_t   fdid,
                       uint8_t  * u_buf,
-                      uint32_t   length,
-                      bool_t     explicit,
-                      uint32_t   explicit_addr,
-                      uint32_t   explicit_port )
-{
-    vfs_inode_type_t    file_type;       // file descriptor type
+                      uint32_t   length )
+{
+    vfs_file_type_t    file_type;       // file descriptor type
+    xptr_t              socket_xp;       // extended pointer on socket descriptor
     socket_t          * socket_ptr;      // local pointer on socket descriptor
     uint32_t            socket_state;    // current socket state
@@ -1529 +1749 @@
     chdev_t           * chdev_ptr;
     cxy_t               chdev_cxy;
-    uint32_t            remote_addr;
-    uint32_t            remote_port;
     uint32_t            buf_status;      // number of bytes in rx_buf
     int32_t             moved_bytes;     // total number of moved bytes (fot return)
@@ -1562 +1780 @@
     file_type  = hal_remote_l32( XPTR( file_cxy , &file_ptr->type ) );
 
-    // get local pointer on socket
+    // get pointers on socket
     socket_ptr = hal_remote_lpt( XPTR( file_cxy , &file_ptr->socket ) );
+    socket_xp  = XPTR( file_cxy , socket_ptr );
 
     // check file descriptor type
-    if( file_type != INODE_TYPE_SOCK )
+    if( file_type != FILE_TYPE_SOCK )
     {
         printk("\n[ERROR] in %s : illegal file type %s / socket[%x,%d]\n",
@@ -1584 +1803 @@
     nic_channel  = hal_remote_l32( XPTR( file_cxy , &socket_ptr->nic_channel ));
 
-    // handle the explicit remote address and port
-    if( socket_type == SOCK_DGRAM )                  // UDP socket
-    {
-        if( socket_state == UDP_STATE_UNBOUND )
-        {
-            // release socket lock
-            remote_queuelock_release( socket_lock_xp );
-                    
-            printk("\n[ERROR] in %s : SEND/RECV for socket[%x,%d] in state %s\n",
-            __FUNCTION__, process->pid, fdid, socket_state_str(socket_state) );
-            return -1;
-        }
-
-        if( explicit )
-        {
-            // update remote IP address and port into socket descriptor
-            hal_remote_s32( XPTR( file_cxy , &socket_ptr->remote_addr ), explicit_addr );
-            hal_remote_s32( XPTR( file_cxy , &socket_ptr->remote_port ), explicit_port );
-
-            // update socket state if required
-            if( socket_state == UDP_STATE_BOUND )
-            {
-                hal_remote_s32( XPTR( file_cxy , &socket_ptr->state ), UDP_STATE_ESTAB );
-            }
-        }
-    }
-    else                                            // TCP socket
-    {
-        if( explicit )
-        {
-            // get remote IP address and port from socket descriptor
-            remote_addr = hal_remote_l32( XPTR( file_cxy , &socket_ptr->remote_addr ));
-            remote_port = hal_remote_l32( XPTR( file_cxy , &socket_ptr->remote_port ));
-
-            if( (remote_addr != explicit_addr) || (remote_port != explicit_port) )
-            {
-                // release socket lock
-                remote_queuelock_release( socket_lock_xp );
-                    
-                printk("\n[ERROR] in %s : wrong expliciy access for socket[%x,%d]\n",
-                __FUNCTION__, process->pid, fdid );
-                return -1;
-            }
-        }
-    }
-
-    ///////////////////////////////////////////////////////
-    if( is_send )                       // TX_SEND command
+    /////////////
+    if( is_send )                       // SEND command
     {
 
@@ -1696 +1869 @@
         thread_unblock( server_xp , THREAD_BLOCKED_CLIENT );
 
+        // start retransmission timer
+        socket_alarm_start( socket_xp , TCP_RETRANSMISSION_TIMEOUT );
+
 #if DEBUG_SOCKET_SEND   
 cycle = (uint32_t)hal_get_cycles();
@@ -1712 +1888 @@
 __FUNCTION__, process->pid, this->trdid, process->pid, fdid, cycle );
 #endif
+        // stop retransmission timer
+        socket_alarm_stop();
+
         // take socket lock
         remote_queuelock_acquire( socket_lock_xp );
@@ -1727 +1906 @@
       
 // check SEND command completed when TX client thread resumes
-assert( (((tx_todo == 0) || (cmd_status != CMD_STS_SUCCESS)) && (cmd_valid == false)),
+assert( __FUNCTION__, (((tx_todo == 0) || (cmd_status != CMD_STS_SUCCESS)) && (cmd_valid == false)),
 "illegal socket state when client thread resumes after TX_SEND\n"
 " tx_todo = %d / tx_status = %d / tx_valid = %d\n",
@@ -1759 +1938 @@
         }
 
-    }  // end TX_SEND command
-
-    ////////////////////////////////////////////////////////
-    else                                 // RX_RECV command
+    }  // end SEND command
+
+    ////
+    else                                 // RECV command
     {
 
@@ -1837 +2016 @@
             buf_status = remote_buf_status( rx_buf_xp );
         
-assert( (((buf_status != 0) || (cmd_status != CMD_STS_SUCCESS)) && (cmd_valid == false)),
+assert( __FUNCTION__, (((buf_status != 0) || (cmd_status != CMD_STS_SUCCESS)) && (cmd_valid == false)),
 "illegal socket state when client thread resumes after RX_RECV\n"
 " buf_status = %d / rx_sts = %d / rx_valid = %d\n",
@@ -1891 +2070 @@
         return moved_bytes;
 
-    }  // end RX_RECV command
+    }  // end RECV command
 } // end socket_move_data()
-
 
 ///////////////////////////////////
@@ -1900 +2078 @@
                  uint32_t    length )
 {
-    int nbytes = socket_move_data( true,           // SEND
-                                   fdid,
-                                   u_buf,
-                                   length,
-                                   false, 0, 0 );  // no explicit remote socket
-    return nbytes;
-
+    return socket_move_data( true,           // SEND
+                             fdid,
+                             u_buf,
+                             length );
 }  // end socket_send()
-
-/////////////////////////////////////
-int socket_sendto( uint32_t    fdid,
-                   uint8_t   * u_buf,
-                   uint32_t    length,
-                   uint32_t    remote_addr,
-                   uint32_t    remote_port )
-{
-    int nbytes = socket_move_data( true,          // SEND
-                                   fdid,
-                                   u_buf,
-                                   length,
-                                   true,          // explicit remote socket
-                                   remote_addr,
-                                   remote_port );
-    return nbytes;
-
-}  // end socket_sendto()
 
 ///////////////////////////////////
@@ -1932 +2089 @@
                  uint32_t    length )
 {
-    int nbytes = socket_move_data( false,          // RECV
-                                   fdid,
-                                   u_buf,
-                                   length,
-                                   false, 0, 0 );  // no explicit remote socket
-    return nbytes;
-
+    return socket_move_data( false,          // RECV
+                             fdid,
+                             u_buf,
+                             length );
 } // end socket_recv()
-
-
-///////////////////////////////////////
-int socket_recvfrom( uint32_t    fdid,
-                     uint8_t   * u_buf,
-                     uint32_t    length,
-                     uint32_t    remote_addr,
-                     uint32_t    remote_port )
-{
-    int nbytes = socket_move_data( false,         // RECV
-                                   fdid,
-                                   u_buf,
-                                   length,
-                                   true,          // explicit remote socket
-                                   remote_addr,
-                                   remote_port );
-    return nbytes;
-
-}  // end socket_recvfrom()
 
 ////////////////////////////////////////////

trunk/kernel/kern/ksocket.h

@@ -440 +440 @@
  * @ fdid      : [in] file descriptor index identifying the local server socket.
  * @ crq_depth : [in] depth of CRQ queue of pending connection requests.
+ * @ return 0 if success / return -1 if failure
  ***************************************************************************************/
 int socket_listen( uint32_t fdid,
@@ -549 +550 @@
 
 /****************************************************************************************
- * This blocking function implements the sendto() syscall. 
- * It registers the <remote_addr> and <remote_port> arguments in the local socket
- * descriptor, and does the same thing as the socket_send() function above, 
- * but can be called  on an unconnected UDP socket.
- ****************************************************************************************
- * @ fdid        : [in] file descriptor index identifying the socket.
- * @ u_buf       : [in] pointer on buffer containing packet in user space.
- * @ length      : [in] packet size in bytes.
- * @ remote_addr : [in] destination IP address.
- * @ remote_port : [in] destination port.
- * @ return number of sent bytes if success / return -1 if failure.
- ***************************************************************************************/
-int socket_sendto( uint32_t    fdid,
-                   uint8_t   * u_buf,
-                   uint32_t    length,
-                   uint32_t    remote_addr,
-                   uint32_t    remote_port );
-
-/****************************************************************************************
  * This blocking function implements the recv() syscall.
  * It is used to receive data that has been stored by the NIC_RX server thread in the
@@ -594 +576 @@
 
 /****************************************************************************************
- * This blocking function implements the recvfrom() syscall.
- * It registers the <remote_addr> and <remote_port> arguments in the local socket
- * descriptor, and does the same thing as the socket_recv() function above, 
- * but can be called on an unconnected UDP socket.
- ****************************************************************************************
- * @ fdid        : [in] file descriptor index identifying the socket.
- * @ u_buf       : [in] pointer on buffer containing packet in user space.
- * @ length      : [in] packet size in bytes.
- * @ remote_addr : [in] destination IP address.
- * @ remote_port : [in] destination port.
- * @ return number of received bytes if success / return -1 if failure.
- ***************************************************************************************/
-int socket_recvfrom( uint32_t    fdid,
-                     uint8_t   * u_buf,
-                     uint32_t    length,
-                     uint32_t    remote_addr,
-                     uint32_t    remote_port );
-
-/****************************************************************************************
  * This blocking function implements the close() syscall for a socket.
  * - For a UDP socket, it simply calls the static socket_destroy() function to release 

trunk/kernel/kern/printk.c

@@ -2 +2 @@
  * printk.c - Kernel Log & debug messages API implementation.
  * 
- * authors  Alain Greiner (2016,2017,2018)
+ * authors  Alain Greiner (2016,2017,2018,2019,2020)
  *
  * Copyright (c) UPMC Sorbonne Universites
@@ -34 +34 @@
 
 ///////////////////////////////////////////////////////////////////////////////////
-//      Extern variables
+//      Extern 
 ///////////////////////////////////////////////////////////////////////////////////
 
 extern chdev_directory_t  chdev_dir;  // defined in chdev.h / allocated in kernel_init.c
 
-/////////////////////////////////////
-uint32_t snprintf( char     * string,
-                   uint32_t   length,
-                   char     * format, ... )
-{
-
-#define TO_STREAM(x) do { string[ps] = (x); ps++; if(ps==length) return -1; } while(0);
-
-    va_list    args;      // printf arguments
-    uint32_t   ps;        // pointer to the string buffer
-
-    ps = 0;   
-    va_start( args , format );
-
-xprintf_text:
-
+//////////////////////////////////////////////////////////////////////////////////////
+// This static function is called by printk(), nolock_printk(), and snprintk(),
+// functions to build a string from a printf-like format, and stores it 
+// in the buffer defined by the <string> and <length> arguments.
+// It does NOT add a terminating NUL character in the <string> buffer.
+// If success, it returns the number of bytes actually copied in the string buffer.
+// It returns -2 in case of illegal format, it returns -1 if the formated string 
+// exceeds the length argument. 
+//////////////////////////////////////////////////////////////////////////////////////
+// @ string    : buffer allocated by caller.
+// @ length    : buffer size in bytes
+// @ format    : printf like format.
+// @ args      : va_list of arguments.
+// @ return string length if success / -1 if buffer too small / -2 if illegal format. 
+//////////////////////////////////////////////////////////////////////////////////////
+static int32_t format_to_string( char       * string,
+                                 uint32_t     length,
+                                 const char * format, 
+                                 va_list    * args ) 
+{
+
+#define TO_STRING(x) do { string[ps] = (x); ps++; if(ps==length) return -1; } while(0);
+
+    uint32_t   ps = 0;        // index in string buffer
+
+format_to_string_text:
+
+    // handle one character per iteration
     while ( *format != 0 ) 
     {
@@ -60 +72 @@
         {
             format++;
-            goto xprintf_arguments;
+            goto format_to_string_arguments;
         }
         else                  // copy one char to string
         {
-            TO_STREAM( *format );
+            TO_STRING( *format );
             format++;
         }
     }
 
-    va_end( args );
-    
-    // add terminating NUL chracter
-    TO_STREAM( 0 );
+    TO_STRING( 0 );
     return ps;
 
-xprintf_arguments:
+format_to_string_arguments:
 
     {
@@ -84 +93 @@
         uint32_t          i;
         
-        // Ignore fields width and precision 
-        for ( ; (*format >= '0' && *format <= '9') || (*format == '.') ; format++ );
-
         switch (*format) 
         {
             case ('c'):             // char conversion 
             {
-                int val = va_arg( args, int );
-                buf[0] = val;
+                int val = va_arg( *args , int );
+                buf[0] = (char)val;
                 pbuf   = buf;
                 len    = 1;
                 break;
             }
-            case ('b'):             // excactly 2 digits hexadecimal integer
-            {
-                int  val = va_arg( args, int );
-                int  val_lsb = val & 0xF;
-                int  val_msb = (val >> 4) & 0xF;
-                buf[0] = HexaTab[val_msb];
-                buf[1] = HexaTab[val_lsb];
-                len  = 2;
-                pbuf = buf;
-                break;
-            }
             case ('d'):             // up to 10 digits decimal signed integer
             {
-                int val = va_arg( args, int );
+                int32_t val = va_arg( *args , int32_t );
                 if (val < 0) 
                 {
-                    TO_STREAM( '-' );
+                    TO_STRING( '-' );
                     val = -val;
                 }
@@ -127 +122 @@
             case ('u'):             // up to 10 digits decimal unsigned integer
             {
-                uint32_t val = va_arg( args, uint32_t );
-                for(i = 0; i < 10; i++) 
-                {
-                    buf[9 - i] = HexaTab[val % 10];
-                    if (!(val /= 10)) break;
-                }
-                len =  i + 1;
-                pbuf = &buf[9 - i];
-                break;
-            }
-            case ('x'):             // up to 8 digits hexadecimal 
-            case ('l'):             // up to 16 digits hexadecimal 
-            {
-                uint32_t imax;
-                uint64_t val;
-                
-                if ( *format == 'l' )   // 64 bits
-                {
-                    val = va_arg( args, uint64_t);
-                    imax = 16;
-                }
-                else                    // 32 bits
-                {
-                    val = va_arg( args, uint32_t);
-                    imax = 8;
-                }
-                
-                TO_STREAM( '0' );
-                TO_STREAM( 'x' );
-                
-                for(i = 0; i < imax; i++) 
-                {
-                    buf[(imax-1) - i] = HexaTab[val % 16];
-                    if (!(val /= 16))  break;
-                }
-                len =  i + 1;
-                pbuf = &buf[(imax-1) - i];
-                break;
-            }
-            case ('X'):             // exactly 8 digits hexadecimal
-            {
-                uint32_t val = va_arg( args , uint32_t );
-                for(i = 0; i < 8; i++) 
-                {
-                    buf[7 - i] = HexaTab[val % 16];
-                    val = (val>>4);
-                }
-                len =  8;
-                pbuf = buf;
-                break;
-            }
-            case ('s'):             /* string */
-            {
-                char* str = va_arg( args, char* );
-                while (str[len]) { len++; }
-                pbuf = str;
-                break;
-            }
-            default:       // unsupported argument type
-            {
-                return -1;
-            }
-        }  // end switch on  argument type
-
-        format++;
-
-        // copy argument to string
-        for( i = 0 ; i < len ; i++ )
-        {
-            TO_STREAM( pbuf[i] );
-        }
-        
-        goto xprintf_text;
-    }
-} // end snprintf()
-
-//////////////////////////////////////////////////////////////////////////////////////
-// This static function is called by printk(), assert() and nolock_printk()
-// to display a formated string on TXT0, using a busy waiting policy.
-//////////////////////////////////////////////////////////////////////////////////////
-// @ format    : printf like format.
-// @ args      : va_list of arguments.
-//////////////////////////////////////////////////////////////////////////////////////
-static void kernel_printf( const char * format, 
-                           va_list    * args ) 
-{
-
-printf_text:
-
-    while (*format) 
-    {
-        uint32_t i;
-        for (i = 0 ; format[i] && (format[i] != '%') ; i++);
-        if (i) 
-        {
-            dev_txt_sync_write( format, i );
-            format += i;
-        }
-        if (*format == '%') 
-        {
-            format++;
-            goto printf_arguments;
-        }
-    }
-
-    return;
-
-printf_arguments:
-
-    {
-        char      buf[20];
-        char    * pbuf = NULL;
-        uint32_t  len  = 0;
-        static const char HexaTab[] = "0123456789ABCDEF";
-        uint32_t i;
-
-        switch (*format++) 
-        {
-            case ('c'):             /* char conversion */
-            {
-                int  val = va_arg( *args , int );
-                len = 1;
-                buf[0] = (char)val;
-                pbuf = &buf[0];
-                break;
-            }
-            case ('b'):             /* exactly 2 digits hexadecimal */
-            {
-                int  val = va_arg( *args, int );
-                int  val_lsb = val & 0xF;
-                int  val_msb = (val >> 4) & 0xF;
-                buf[0] = HexaTab[val_msb];
-                buf[1] = HexaTab[val_lsb];
-                len  = 2;
-                pbuf = buf;
-                break;
-            }
-            case ('d'):             /* up to 10 digits signed decimal */
-            {
-                int val = va_arg( *args , int );
-                if (val < 0) 
-                {
-                    val = -val;
-                    dev_txt_sync_write( "-" , 1 );
-                }
-                for(i = 0; i < 10; i++) 
-                {
-                    buf[9 - i] = HexaTab[val % 10];
-                    if (!(val /= 10)) break;
-                }
-                len =  i + 1;
-                pbuf = &buf[9 - i];
-                break;
-            }
-            case ('u'):             /* up to 10 digits unsigned decimal */
-            {
                 uint32_t val = va_arg( *args , uint32_t );
                 for(i = 0; i < 10; i++) 
@@ -293 +132 @@
                 break;
             }
-            case ('x'):             /* up to 8 digits hexadecimal */
+            case ('x'):             // up to 8 digits hexad after "0x"
+            case ('X'):             // exactly 8 digits hexa after "0x"
             {
                 uint32_t val = va_arg( *args , uint32_t );
-                dev_txt_sync_write( "0x" , 2 );
-                for(i = 0; i < 8; i++) 
+                TO_STRING( '0' );
+                TO_STRING( 'x' );
+                for(i = 0 ; i < 8 ; i++) 
                 {
                     buf[7 - i] = HexaTab[val & 0xF];
-                    if (!(val = (val>>4)))  break;
+                    if( (*format == 'x') && ((val >> 4) == 0) )  break;
+                    val = val >> 4;
                 }
                 len =  i + 1;
@@ -306 +148 @@
                 break;
             }
-            case ('X'):             /* exactly 8 digits hexadecimal */
+            case ('l'):             // up to 16 digits hexa after "0x"
+            case ('L'):             // exactly 16 digits hexa after "0x"
             {
-                uint32_t val = va_arg( *args , uint32_t );
-                dev_txt_sync_write( "0x" , 2 );
-                for(i = 0; i < 8; i++) 
-                {
-                    buf[7 - i] = HexaTab[val & 0xF];
-                    val = (val>>4);
-                }
-                len =  8;
-                pbuf = buf;
-                break;
-            }
-            case ('l'):            /* up to 16 digits hexadecimal */
-            {
-                uint64_t val = va_arg( *args , uint64_t );
-                dev_txt_sync_write( "0x" , 2 );
-                for(i = 0; i < 16; i++) 
+                uint64_t val = (((uint64_t)va_arg( *args, uint32_t)) << 32) |
+                               ((uint64_t)va_arg( *args, uint32_t));
+                TO_STRING( '0' );
+                TO_STRING( 'x' );
+                for(i = 0 ; i < 16 ; i++) 
                 {
                     buf[15 - i] = HexaTab[val & 0xF];
-                    if (!(val = (val>>4)))  break;
+                    if( (*format == 'l') && ((val >> 4) == 0) )  break;
+                    val = val >> 4;
                 }
                 len =  i + 1;
@@ -332 +165 @@
                 break;
             }
-            case ('L'):           /* exactly 16 digits hexadecimal */ 
-            {
-                uint64_t val = va_arg( *args , uint64_t );
-                dev_txt_sync_write( "0x" , 2 );
-                for(i = 0; i < 16; i++) 
-                {
-                    buf[15 - i] = HexaTab[val & 0xF];
-                    val = (val>>4);
-                }
-                len =  16;
-                pbuf = buf;
-                break;
-            }
             case ('s'):             /* string */
             {
                 char* str = va_arg( *args , char* );
-                while (str[len]) 
-                {
-                    len++;
-                }
+                while (str[len]) { len++; }
                 pbuf = str;
                 break;
             }
-            default:
+            default:       // unsupported argument type
             {
-                dev_txt_sync_write( "\n[PANIC] in kernel_printf() : illegal format\n", 45 );
+                return -2;
             }
-        }
-
-        if( pbuf != NULL ) dev_txt_sync_write( pbuf, len );
+        }  // end switch on  argument type
+
+        format++;
+
+        // copy argument sub-string to the string buffer
+        for( i = 0 ; i < len ; i++ )
+        {
+            TO_STRING( pbuf[i] );
+        }
         
-        goto printf_text;
-    }
-
-}  // end kernel_printf()
+        goto format_to_string_text;
+    }
+}   // end format_to_string()
 
 //////////////////////////////////
 void printk( char * format , ... )
 {
+    char          buffer[CONFIG_PRINTK_BUF_SIZE];
     va_list       args;
+    int32_t       length;
+
+    // build args va_list
+    va_start( args , format );
 
     // get pointers on TXT0 chdev
@@ -384 +211 @@
     remote_busylock_acquire( lock_xp );
 
-    // display format on TXT0 in busy waiting mode
-    va_start( args , format );
-    kernel_printf( format , &args );
+    // build a string from format
+    length = format_to_string( buffer,
+                      CONFIG_PRINTK_BUF_SIZE,
+                      format,
+                      &args );
     va_end( args );
+
+    if( length > 0  )        // call TXT driver to display formated string on TXT0
+    {
+        dev_txt_sync_write( buffer , length );
+    }
+    else if( length == -2 )  // illegal format => display a warning on TXT0
+    {
+        thread_t * this = CURRENT_THREAD;
+
+        nolock_printk("\n[PANIC] from printk : illegal format\n"
+                      "thread[%x,%x] on core[%x,%d] at cycle %l\n",
+                      this->process->pid, this->trdid,
+                      local_cxy, this->core->lid, hal_get_cycles() );
+    }
+    else                     // format too long => display a warning on TXT0
+    {
+        thread_t * this = CURRENT_THREAD;
+
+        nolock_printk("\n[PANIC] from printk : formated string too long\n"
+                      "thread[%x,%x] on core[%x,%d] at cycle %l\n",
+                      this->process->pid, this->trdid,
+                      local_cxy, this->core->lid, hal_get_cycles() );
+    }
 
     // release TXT0 lock
     remote_busylock_release( lock_xp );
-}
+
+}   // end printk()
 
 /////////////////////////////////////////
 void nolock_printk( char * format , ... )
 {
+    char          buffer[CONFIG_PRINTK_BUF_SIZE];
     va_list       args;
-
-    // call kernel_printf on TXT0, in busy waiting mode
+    int32_t       length;
+
+    // build args va_list
     va_start( args , format );
-    kernel_printf( format , &args );
+
+    // build a string from format
+    length = format_to_string( buffer,
+                      CONFIG_PRINTK_BUF_SIZE,
+                      format,
+                      &args );
     va_end( args );
-}
-
-////////////////////////////////////
-void panic( const char * function_name,
-            uint32_t     line,
-            cycle_t      cycle,
-            const char * format,
-            ... )
-{
-    // get pointers on TXT0 chdev
-    xptr_t    txt0_xp = chdev_dir.txt_tx[0];
-    cxy_t     txt0_cxy = GET_CXY(txt0_xp);
-    chdev_t * txt0_ptr = GET_PTR(txt0_xp);
-
-    // get extended pointer on remote TXT0 lock
-    xptr_t lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
-
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
-
-    // get calling thread
-    thread_t * current = CURRENT_THREAD;
-
-    // print generic infos
-    nolock_printk("\n\n[PANIC] in %s: line %d | cycle %d\n"
-                  "core[%x,%d] | thread %x (%x) | process %x (%x)\n",
-                  function_name, line, (uint32_t)cycle,
-                  local_cxy, current->core->lid, 
-                  current->trdid, current,
-                  current->process->pid, current->process );
-
-    // call kernel_printf to print format
-    va_list args;
-    va_start(args, format);
-    kernel_printf(format, &args);
-    va_end(args);
-
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-
-    // suicide
-    hal_core_sleep();
-}
-
-//////////////////////////
-void puts( char * string ) 
+
+    if( length > 0  )        // call TXT driver to display formated string on TXT0
+    {
+        dev_txt_sync_write( buffer , length );
+    }
+    else if( length == -2 )  // illegal format => display a warning on TXT0
+    {
+        thread_t * this = CURRENT_THREAD;
+
+        nolock_printk("\n[PANIC] from print : illegal format\n"
+                      "thread[%x,%x] on core[%x,%d] at cycle %l\n",
+                      this->process->pid, this->trdid,
+                      local_cxy, this->core->lid, hal_get_cycles() );
+    }
+    else                  // buffer too small => display a warning on TXT0
+    {
+        thread_t * this = CURRENT_THREAD;
+
+        nolock_printk("\n[PANIC] from printk : formated string too long\n"
+                      "thread[%x,%x] on core[%x,%d] at cycle %l\n",
+                      this->process->pid, this->trdid,
+                      local_cxy, this->core->lid, hal_get_cycles() );
+    }
+
+}   // end nolock_printk()
+
+//////////////////////////////////////
+void assert( const char   * func_name,
+             bool_t         expr,
+             char         * format , ... )
+{
+    if( expr == false )
+    {
+        thread_t * this  = CURRENT_THREAD;
+        trdid_t    trdid = this->trdid;
+        pid_t      pid   = this->process->pid;
+        uint32_t   lid   = this->core->lid;
+        uint32_t   cycle = (uint32_t)hal_get_cycles();
+
+        char       buffer[CONFIG_PRINTK_BUF_SIZE];
+        va_list    args;
+
+        va_start( args , format );
+
+        // build a string from format
+        int32_t   length = format_to_string( buffer,
+                                             CONFIG_PRINTK_BUF_SIZE,
+                                             format,
+                                             &args );
+        va_end( args );
+
+        if( length > 0  )  // display panic message on TXT0, including formated string
+        {
+            printk("\n[ASSERT] in %s / core[%x,%d] / thread[%x,%x] / cycle %d\n       %s\n",
+            func_name, local_cxy, lid, pid, trdid, cycle, buffer );
+        }
+        else              // display minimal panic message on TXT0
+        {
+            printk("\n[ASSERT] in %s / core[%x,%d] / thread[%x,%x] / cycle %d\n",
+            func_name, local_cxy, lid, pid, trdid, cycle );
+        }
+    }
+}   // end assert( __FUNCTION__,)
+   
+//////////////////////////////////////
+int32_t snprintk( char       * buffer,
+                  uint32_t     size,
+                  char       * format, ... )
+{
+    va_list       args;
+    int32_t       string_length;
+
+    // build args va_list
+    va_start( args , format );
+
+    // build a string from format
+    string_length = format_to_string( buffer , size , format , &args );
+    va_end( args );
+
+    if( (string_length < 0) || (string_length == (int32_t)size) )  // failure
+    {
+        return -1;
+    }
+    else                                                           // success
+    {
+        // add NUL character
+        buffer[string_length] = 0;
+
+        return string_length;
+    }
+}   // end snprintk()
+
+////////////////////////////////
+void puts( const char * string ) 
 {
     uint32_t   n = 0;
@@ -459 +367 @@
     chdev_t * txt0_ptr = GET_PTR( txt0_xp );
 
-    // get extended pointer on remote TXT0 lock
-    xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
-
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
+    if( txt0_xp != XPTR_NULL )
+    {
+        // get extended pointer on remote TXT0 lock
+        xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
+
+        // display string on TTY0
+        remote_busylock_acquire( lock_xp );
+        dev_txt_sync_write( string , n );
+        remote_busylock_release( lock_xp );
+    }
+}   // end puts()
+
+///////////////////////////////////////
+void nolock_puts( const char * string ) 
+{
+    uint32_t   n = 0;
+
+    // compute string length
+    while ( string[n] > 0 ) n++;
 
     // display string on TTY0
     dev_txt_sync_write( string , n );
-
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-}
+  
+}   // end nolock_puts()
+
 
 
@@ -496 +417 @@
     chdev_t * txt0_ptr = GET_PTR( txt0_xp );
 
-    // get extended pointer on remote TXT0 chdev lock
-    xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
-
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
+    if( txt0_xp != XPTR_NULL )
+    {
+        // get extended pointer on remote TXT0 chdev lock
+        xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
+
+        // display buf on TTY0
+        remote_busylock_acquire( lock_xp );
+        dev_txt_sync_write( buf , 10 );
+        remote_busylock_release( lock_xp );
+    }
+}   // end putx()
+
+////////////////////////////////
+void nolock_putx( uint32_t val )
+{
+    static const char HexaTab[] = "0123456789ABCDEF";
+
+    char      buf[10];
+    uint32_t  c;
+
+    buf[0] = '0';
+    buf[1] = 'x';
+
+    // build buffer
+    for (c = 0; c < 8; c++) 
+    { 
+        buf[9 - c] = HexaTab[val & 0xF];
+        val = val >> 4;
+    }
 
     // display buf on TTY0
     dev_txt_sync_write( buf , 10 );
 
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-}
+}   // end nilock_putx()
 
 ////////////////////////
@@ -525 +468 @@
     xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
 
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
+    if( txt0_xp != XPTR_NULL )
+    {
+        // get TXT0 lock 
+        remote_busylock_acquire( lock_xp );
+
+        if (val < 0) 
+        {
+            val = -val;
+            dev_txt_sync_write( "-" , 1 );
+        }
+
+        for(i = 0; i < 10 ; i++) 
+        {
+            buf[9 - i] = HexaTab[val % 10];
+            if (!(val /= 10)) break;
+        }
+
+        // display buf on TTY0
+        dev_txt_sync_write( &buf[9-i] , i+1 );
+
+        // release TXT0 lock
+        remote_busylock_release( lock_xp );
+    }
+}   // end putd()
+
+///////////////////////////////
+void nolock_putd( int32_t val )
+{
+    static const char HexaTab[] = "0123456789ABCDEF";
+
+    char      buf[10];
+    uint32_t  i;
 
     if (val < 0) 
@@ -543 +516 @@
     dev_txt_sync_write( &buf[9-i] , i+1 );
 
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-}
+}   // end nolock_putd()
 
 /////////////////////////
@@ -570 +541 @@
     chdev_t * txt0_ptr = GET_PTR( txt0_xp );
 
-    // get extended pointer on remote TXT0 chdev lock
-    xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
-
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
+    if( txt0_xp != XPTR_NULL )
+    {
+        // get extended pointer on remote TXT0 chdev lock
+        xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
+
+        // display string on TTY0
+        remote_busylock_acquire( lock_xp );
+        dev_txt_sync_write( buf , 18 );
+        remote_busylock_release( lock_xp );
+    }
+}   // end putl()
+
+////////////////////////////////
+void nolock_putl( uint64_t val )
+{
+    static const char HexaTab[] = "0123456789ABCDEF";
+
+    char      buf[18];
+    uint32_t  c;
+
+    buf[0] = '0';
+    buf[1] = 'x';
+
+    // build buffer
+    for (c = 0; c < 16; c++) 
+    { 
+        buf[17 - c] = HexaTab[(unsigned int)val & 0xF];
+        val = val >> 4;
+    }
 
     // display string on TTY0
     dev_txt_sync_write( buf , 18 );
 
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-}
+}   // end nolock_putl()
 
 /////////////////////////////
@@ -603 +596 @@
     xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
 
-    // get TXT0 lock 
-    remote_busylock_acquire( lock_xp );
-
-    // display string on TTY0
-    nolock_printk("\n***** %s *****\n", string );
-
-    for ( line = 0 , byte = 0 ; line < nlines ; line++ )
-    {
-         nolock_printk(" %X | %b %b %b %b | %b %b %b %b | %b %b %b %b | %b %b %b %b |\n",
-         buffer + byte,
-         buffer[byte+ 0],buffer[byte+ 1],buffer[byte+ 2],buffer[byte+ 3],
-         buffer[byte+ 4],buffer[byte+ 5],buffer[byte+ 6],buffer[byte+ 7],
-         buffer[byte+ 8],buffer[byte+ 9],buffer[byte+10],buffer[byte+11],
-         buffer[byte+12],buffer[byte+13],buffer[byte+14],buffer[byte+15] );
-
-         byte += 16;
-    }
-
-    // release TXT0 lock
-    remote_busylock_release( lock_xp );
-}
+    if( txt0_xp != XPTR_NULL )
+    {
+        // get TXT0 lock 
+        remote_busylock_acquire( lock_xp );
+
+        // display string on TTY0
+        nolock_printk("\n***** %s *****\n", string );
+
+        for ( line = 0 , byte = 0 ; line < nlines ; line++ )
+        {
+            nolock_printk(" %X | %b %b %b %b | %b %b %b %b | %b %b %b %b | %b %b %b %b |\n",
+            buffer + byte,
+            buffer[byte+ 0],buffer[byte+ 1],buffer[byte+ 2],buffer[byte+ 3],
+            buffer[byte+ 4],buffer[byte+ 5],buffer[byte+ 6],buffer[byte+ 7],
+            buffer[byte+ 8],buffer[byte+ 9],buffer[byte+10],buffer[byte+11],
+            buffer[byte+12],buffer[byte+13],buffer[byte+14],buffer[byte+15] );
+
+            byte += 16;
+        }
+
+        // release TXT0 lock
+        remote_busylock_release( lock_xp );
+    }
+}   // end putb()
 
 

trunk/kernel/kern/printk.h

@@ -26 +26 @@
 // to display messages on the kernel terminal TXT0, using a busy waiting policy. 
 // It calls synchronously the TXT0 driver, without descheduling.
+//
+// For the formated string, the supported formats are defined below :
+//   %c : single ascii character (8 bits)
+//   %d : up to 10 digits decimal integer (32 bits)
+//   %u : up to 10 digits unsigned decimal (32 bits) 
+//   %x : up to 8 digits hexadecimal integer (32 bits) 
+//   %X : exactly 8 digits hexadecimal integer (32 bits) 
+//   %l : up to 16 digits hexadecimal integer (64 bits)
+//   %L : exactly 16 digits hexadecimal integer (64 bits)
+//   %s : NUL terminated character string
 ///////////////////////////////////////////////////////////////////////////////////
 
@@ -37 +47 @@
 
 /**********************************************************************************
- * This function build a formatted string.
- * The supported formats are defined below :
- *   %b : exactly 2 digits hexadecimal integer (8 bits)
- *   %c : single ascii character (8 bits)
- *   %d : up to 10 digits decimal integer (32 bits)
- *   %u : up to 10 digits unsigned decimal (32 bits) 
- *   %x : up to 8 digits hexadecimal integer (32 bits) 
- *   %X : exactly 8 digits hexadecimal integer (32 bits) 
- *   %l : up to 16 digits hexadecimal integer (64 bits)
- *   %L : exactly 16 digits hexadecimal integer (64 bits)
- *   %s : NUL terminated character string
+ * These debug functions display a formated string defined by the <format,...>
+ * argument on the kernel terminal TXT0, with or without taking the TXT0 lock. 
  **********************************************************************************
- * @ string     : pointer on target buffer (allocated by caller).
- * @ length     : target buffer length (number of bytes).
- * @ format     : format respecting the printf syntax.
- * @ returns the string length (including NUL) if success / return -1 if error.
- *********************************************************************************/
-uint32_t snprintf( char     * string,
-                   uint32_t   length,
-                   char     * format, ... );
-
-/**********************************************************************************
- * This function displays a formatted string on the kernel terminal TXT0,
- * after taking the TXT0 lock.
- * It uses a busy waiting policy, calling directly the relevant TXT driver,
+ * Implementation note:
+ * It uses a buffer allocated in the stack, defined by CONFIG_PRINTK_BUFFER_SIZE.
+ * It calls the snprintk() function to build a printable string in this buffer, 
+ * and calls directly the dev_txt_sync_write() driver function without using the
+ * TXT server thread.
+ * It displays a [PANIC] message on kernel TXT0 terminal if the formated string
+ * exceeds the buffer size, or if the format is undefined. 
  **********************************************************************************
  * @ format     : formatted string.
  *********************************************************************************/
-void printk( char* format, ... );
+void printk       ( char * format, ... );
+void nolock_printk( char * format, ... );
 
 /**********************************************************************************
- * This function displays a formatted string on the kernel terminal TXT0,
- * without taking the TXT0 lock.
- * It uses a busy waiting policy, calling directly the relevant TXT driver,
+ * This debug function displays a [ASSERT] message on kernel TXT0 terminal
+ * if Boolean expression <expr> is false. It prints a detailed message including:
+ * - the calling core [cxy,lpid]
+ * - the calling thread[pid,trdid]
+ * - the current cycle
+ * - the <func_name> argument
+ * - the <string> argument
  **********************************************************************************
- * @ format     : formatted string.
+ * @ func_name  : calling function name.
+ * @ expr       : Boolean expression to be checked.
+ * @ format     : formated message argument.
  *********************************************************************************/
-void nolock_printk( char* format, ... );
-
+void assert( const char   * func_name,
+             bool_t         expr,
+             char         * format , ... );
 
 /**********************************************************************************
- * This function is called in case of kernel panic. It printt a detailed message
- * on the TXT0 terminal after taking the TXT0 lock, and call the hal_core_sleep()
- * function to block the calling core.  It is used by the assert macro (below).
+ * This function build a formated string in a buffer defined by the <buffer> 
+ * and <buf_size> arguments, from the format defined by the <format,...> argument.
+ * This function set the NUL terminating character in target <buffer>.
  **********************************************************************************
- * @ file_name     : File where the assert macro was invoked
- * @ function_name : Name of the calling function.
- * @ line          : Line number where the assert macro was invoked
- * @ cycle         : Cycle where the macro was invoked
- * @ format        : Formatted string
- * ...             : arguments of the format string
- *
- * See assert macro documentation for information about printed information.
+ * @ buffer     : pointer on target buffer (allocated by caller).
+ * @ buf_size   : target buffer length (number of bytes).
+ * @ format     : format respecting the printf syntax.
+ * @ returns  string length (not including NUL) if success / -1 if error.
  *********************************************************************************/
-void panic( const char * function_name,
-            uint32_t     line,
-            cycle_t      cycle,
-            const char * format,
-            ... ) __attribute__((__noreturn__));
+int32_t snprintk( char       * buffer,
+                  uint32_t     buf_size,
+                  char       * format, ... );
 
 /**********************************************************************************
- * This macro displays a formated message on kernel TXT0 terminal,
- * and forces the calling core in sleeping mode if a Boolean condition is false.
- * Actually used to debug the kernel.
- *
- * Extra information printed by assert:
- * - Current thread, process, and core
- * - Function name / line number in file / cycle
+ * These functions displays a non-formated string on TXT0 terminal.
+ * They are actually used for low level debug, and call directly the TXT driver,
+ * without using the TXT server thread.
  **********************************************************************************
- * @ condition     : condition that must be true.
- * @ format        : formatted string
+ * @ string   : non-formatted, NUL terminated string.
  *********************************************************************************/
-#define assert( expr, format, ... )                                               \
-{                                                                                 \
-    uint32_t __line_at_expansion = __LINE__;                                      \
-    const volatile cycle_t __assert_cycle = hal_get_cycles();                     \
-    if ( ( expr ) == false )                                                      \
-    {                                                                             \
-        panic( __FUNCTION__,                                                      \
-               __line_at_expansion,                                               \
-               __assert_cycle,                                                    \
-               ( format ), ##__VA_ARGS__ );                                       \
-    }                                                                             \
-}
+void puts( const char * string );
+void nolock_puts( const char * string );
 
 /**********************************************************************************
- * This debug function displays a non-formated message on TXT0 terminal.
- * This function is actually used to debug the assembly level kernel functions.
- **********************************************************************************
- * @ string   : non-formatted string.
- *********************************************************************************/
-void puts( char * string );
-
-/**********************************************************************************
- * This debug function displays a 32 bits value in hexadecimal on TXT0 terminal.
- * This function is actually used to debug the assembly level kernel functions.
+ * These functions display a 32 bits value in hexadecimal on TXT0 terminal.
+ * They are actually used for low level debug, and call directly the TXT driver,
+ * without using the TXT server thread.
  **********************************************************************************
  * @ val   : 32 bits unsigned value.
  *********************************************************************************/
 void putx( uint32_t val );
+void nolock_putx( uint32_t val );
 
 /**********************************************************************************
- * This debug function displays a 32 bits signed value in decimal on TXT0 terminal.
- * This function is actually used to debug the assembly level kernel functions.
+ * These functions display a 32 bits signed value in decimal on TXT0 terminal.
+ * They are actually used for low level debug, and call directly the TXT driver,
+ * without using the TXT server thread.
  **********************************************************************************
  * @ val   : 32 bits signed value.
  *********************************************************************************/
 void putd( int32_t val );
+void nolock_putd( int32_t val );
 
 /**********************************************************************************
- * This debug function displays a 64 bits value in hexadecimal on TXT0 terminal.
- * This function is actually used to debug the assembly level kernel functions.
+ * These functions display a 64 bits value in hexadecimal on TXT0 terminal.
+ * They are actually used low level debug, and call directly the TXT driver,
+ * without using the TXT server thread.
  **********************************************************************************
  * @ val   : 64 bits unsigned value.
  *********************************************************************************/
 void putl( uint64_t val );
+void nolock_putl( uint64_t val );
 
 /**********************************************************************************

trunk/kernel/kern/process.c

@@ -41 +41 @@
 #include <thread.h>
 #include <chdev.h>
+#include <ksocket.h>
 #include <list.h>
 #include <string.h>
@@ -72 +73 @@
 process_t * process_alloc( void )
 {
+
+assert( __FUNCTION__, (sizeof(process_t) < CONFIG_PPM_PAGE_SIZE),
+"process descriptor exceeds 1 page" );
+
         kmem_req_t req;
 
-    req.type  = KMEM_KCM;
-        req.order = bits_log2( sizeof(process_t) );
-        req.flags = AF_KERNEL;
-
+    req.type  = KMEM_PPM;
+        req.order = 0;
+        req.flags = AF_KERNEL | AF_ZERO;
     return kmem_alloc( &req );
 }
@@ -86 +90 @@
     kmem_req_t  req;
 
-        req.type = KMEM_KCM;
+        req.type = KMEM_PPM;
         req.ptr  = process;
         kmem_free( &req );
@@ -109 +113 @@
     char        rx_path[40];
     char        tx_path[40];
-    xptr_t      file_xp;
-    xptr_t      chdev_xp;
-    chdev_t   * chdev_ptr;
-    cxy_t       chdev_cxy;
     pid_t       parent_pid;
     vmm_t     * vmm;
@@ -211 +211 @@
 
         // attach process to TXT
-        process_txt_attach( process , txt_id ); 
+        process_txt_attach( process_xp , txt_id ); 
 
 #if (DEBUG_PROCESS_REFERENCE_INIT & 1)
@@ -220 +220 @@
 #endif
         // build path to TXT_RX[i] and TXT_TX[i] chdevs
-        snprintf( rx_path , 40 , "/dev/external/txt%d_rx", txt_id );
-        snprintf( tx_path , 40 , "/dev/external/txt%d_tx", txt_id );
+        snprintk( rx_path , 40 , "/dev/external/txt%d_rx", txt_id );
+        snprintk( tx_path , 40 , "/dev/external/txt%d_tx", txt_id );
 
         // create stdin pseudo file          
@@ -237 +237 @@
         }
 
-assert( (stdin_id == 0) , "stdin index must be 0" );
+assert( __FUNCTION__, (stdin_id == 0) , "stdin index must be 0" );
 
 #if (DEBUG_PROCESS_REFERENCE_INIT & 1)
@@ -260 +260 @@
         }
 
-assert( (stdout_id == 1) , "stdout index must be 1" );
+assert( __FUNCTION__, (stdout_id == 1) , "stdout index must be 1" );
 
 #if (DEBUG_PROCESS_REFERENCE_INIT & 1)
@@ -283 +283 @@
         }
 
-assert( (stderr_id == 2) , "stderr index must be 2" );
+assert( __FUNCTION__, (stderr_id == 2) , "stderr index must be 2" );
 
 #if (DEBUG_PROCESS_REFERENCE_INIT & 1)
@@ -295 +295 @@
     else                                            // normal user process 
     {
-        // get extended pointer on stdin pseudo file in parent process
-        file_xp = (xptr_t)hal_remote_l64( XPTR( parent_cxy,
-                                                &parent_ptr->fd_array.array[0] ) );
-
-        // get extended pointer on parent process TXT chdev
-        chdev_xp = chdev_from_file( file_xp );
- 
-        // get cluster and local pointer on chdev
-        chdev_cxy = GET_CXY( chdev_xp );
-        chdev_ptr = GET_PTR( chdev_xp );
- 
-        // get parent process TXT terminal index
-        txt_id = hal_remote_l32( XPTR( chdev_cxy , &chdev_ptr->channel ) );
-
-        // attach child process to parent process TXT terminal
-        process_txt_attach( process , txt_id ); 
-
-        // copy all open files from parent process fd_array to this process
-        process_fd_remote_copy( XPTR( local_cxy , &process->fd_array ),
-                                XPTR( parent_cxy , &parent_ptr->fd_array ) );
+        // get parent process TXT index
+        txt_id = process_txt_get_index( parent_xp );
+
+        // attach child process to same TXT terminal as parent
+        process_txt_attach( process_xp , txt_id ); 
+
+        // recreate all open files from parent process fd_array to child process fd_array
+        process_fd_replicate( process_xp , parent_xp );
     }
 
     // initialize lock protecting CWD changes
-    remote_busylock_init( XPTR( local_cxy , 
-                                &process->cwd_lock ), LOCK_PROCESS_CWD );
+    remote_busylock_init( XPTR( local_cxy , &process->cwd_lock ), LOCK_PROCESS_CWD );
 
 #if (DEBUG_PROCESS_REFERENCE_INIT & 1)
@@ -415 +402 @@
 
 // check user process
-assert( (local_process->pid != 0), "LPID cannot be 0" );
+assert( __FUNCTION__, (local_process->pid != 0), "LPID cannot be 0" );
 
     // initialize VSL as empty
@@ -520 +507 @@
 
 // check no more threads
-assert( (process->th_nr == 0),
+assert( __FUNCTION__, (process->th_nr == 0),
 "process %x in cluster %x contains threads", pid , local_cxy );
 
@@ -616 +603 @@
 cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_DESTROY < cycle )
-printk("\n[%s] thread[%x,%x] exit / process %x in cluster %x / cycle %d\n",
+printk("\n[%s] thread[%x,%x] exit for process %x in cluster %x / cycle %d\n",
 __FUNCTION__, this->process->pid, this->trdid, pid, local_cxy, cycle );
 #endif
@@ -683 +670 @@
 
 // check action type
-assert( ((type == DELETE_ALL_THREADS ) ||
+assert( __FUNCTION__, ((type == DELETE_ALL_THREADS ) ||
          (type == BLOCK_ALL_THREADS )  ||
          (type == UNBLOCK_ALL_THREADS )), "illegal action type" );
@@ -809 +796 @@
 
 // check target process is an user process
-assert( (LPID_FROM_PID( process->pid ) != 0 ),
+assert( __FUNCTION__, (LPID_FROM_PID( process->pid ) != 0 ),
 "process %x is not an user process\n", process->pid );
 
@@ -894 +881 @@
 
 // check target process is an user process
-assert( (LPID_FROM_PID( process->pid ) != 0),
+assert( __FUNCTION__, (LPID_FROM_PID( process->pid ) != 0),
 "process %x is not an user process\n", process->pid );
 
@@ -916 +903 @@
             {
                 // mark target thread for delete and block it
-                thread_delete( target_xp , true );                   // forced 
+                thread_delete_request( target_xp , true );                   // forced 
             }
         }
@@ -950 +937 @@
 
 // check target process is an user process
-assert( ( LPID_FROM_PID( process->pid ) != 0 ),
+assert( __FUNCTION__, ( LPID_FROM_PID( process->pid ) != 0 ),
 "process %x is not an user process\n", process->pid );
 
@@ -1027 +1014 @@
         xptr_t ref_xp = cluster_get_reference_process_from_pid( pid );
 
-        assert( (ref_xp != XPTR_NULL) , "illegal pid\n" );
+        assert( __FUNCTION__, (ref_xp != XPTR_NULL) , "illegal pid\n" );
 
         // allocate memory for local process descriptor
@@ -1081 +1068 @@
     switch( type )
     {
-        case INODE_TYPE_FILE : return "FILE";
-        case INODE_TYPE_DIR  : return "DIR";
-        case INODE_TYPE_FIFO : return "FIFO";
-        case INODE_TYPE_PIPE : return "PIPE";
-        case INODE_TYPE_SOCK : return "SOCK";
-        case INODE_TYPE_DEV  : return "DEV";
-        case INODE_TYPE_BLK  : return "BLK";
-        case INODE_TYPE_SYML : return "SYML";
+        case FILE_TYPE_REG : return "FILE";
+        case FILE_TYPE_DIR  : return "DIR";
+        case FILE_TYPE_FIFO : return "FIFO";
+        case FILE_TYPE_PIPE : return "PIPE";
+        case FILE_TYPE_SOCK : return "SOCK";
+        case FILE_TYPE_DEV  : return "DEV";
+        case FILE_TYPE_BLK  : return "BLK";
+        case FILE_TYPE_SYML : return "SYML";
         
         default              : return "undefined";
@@ -1129 +1116 @@
 
 // check target process is owner process
-assert( (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ) ) ),
+assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ) ) ),
 "process must be owner process\n" );
 
@@ -1145 +1132 @@
     max_xp  = XPTR( process_cxy , &process_ptr->fd_array.max );
 
-    // take lock protecting reference fd_array
+    // take lock protecting fd_array
         remote_queuelock_acquire( lock_xp );
 
@@ -1158 +1145 @@
         entry_xp = hal_remote_l64( XPTR( process_cxy , &process_ptr->fd_array.array[id] ) );
         
+        // take the first empty slot
         if ( entry_xp == XPTR_NULL )
         {
@@ -1165 +1153 @@
             // update max when required
             if( id > max ) hal_remote_s32( max_xp , id );
-
-            // increase file refcount
-            vfs_file_count_up( file_xp );
 
             // exit loop
@@ -1208 +1193 @@
 
 // check target process is owner process
-assert( (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ) ) ),
+assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ) ) ),
 "process must be owner process\n" );
 
@@ -1253 +1238 @@
         // release the fd_array entry in process copy
         hal_remote_s64( XPTR( copy_cxy , &copy_ptr->fd_array.array[fdid] ), XPTR_NULL );
-
-        // decrease file refcount
-        vfs_file_count_down( file_xp );
     }
 
@@ -1261 +1243 @@
     if( fdid == max ) hal_remote_s32( fd_max_xp , max-1 );
 
-    // release the lock protecting reference fd_array
+    // release the lock protecting fd_array
         remote_queuelock_release( fd_lock_xp );
 
@@ -1279 +1261 @@
 void process_fd_clean_all( xptr_t process_xp )
 {
-    uint32_t  id;
+    uint32_t  fdid;
     xptr_t    file_xp;         // one fd_array entry
     xptr_t    lock_xp;         // extendad pointer on lock protecting fd_array
     uint32_t  max;             // number of registered files
-    error_t   error;
 
     // get process cluster, local pointer and PID
     process_t * process_ptr = GET_PTR( process_xp );
     cxy_t       process_cxy = GET_CXY( process_xp );
-    pid_t       pid         = hal_remote_l32( XPTR( process_cxy , &process_ptr->pid) );
 
 // check target process is owner process
-assert( (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp )) ),
+assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp )) ),
 "process must be owner process\n" );
 
@@ -1298 +1278 @@
 uint32_t   cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_FD_CLEAN_ALL < cycle )
-printk("\n[%s] thread[%x,%x] enter for process %x / cycle %d\n",
-__FUNCTION__, this->process->pid, this->trdid, pid, cycle );
+printk("\n[%s] thread[%x,%x] enter / cycle %d\n",
+__FUNCTION__, this->process->pid, this->trdid, cycle );
 
 process_fd_display( process_xp );
@@ -1313 +1293 @@
         remote_queuelock_acquire( lock_xp );
 
-    for ( id = 0; id <= max ; id++ )
+    for( fdid = 0 ; fdid <= max ; fdid++ )
     {
         // get fd_array entry
-        file_xp = hal_remote_l64( XPTR( process_cxy , &process_ptr->fd_array.array[id] ) );
+        file_xp = hal_remote_l64( XPTR( process_cxy , &process_ptr->fd_array.array[fdid] ) );
         
         if ( file_xp != XPTR_NULL )
         {
-            // close the file or socket
-            error = sys_close( id );
-
-            if( error )
-            printk("/n[ERROR] in %s : cannot close the file %d for process %x\n",
-            __FUNCTION__, id, pid );
+            vfs_file_t * file_ptr = GET_PTR( file_xp );
+            cxy_t        file_cxy = GET_CXY( file_xp );
+
+            // get file type
+            uint32_t file_type = hal_remote_l32( XPTR( file_cxy , &file_ptr->type ));
+ 
+            if( file_type == FILE_TYPE_REG )
+            {
+                vfs_close( file_xp , fdid );
+            }
+            if( file_type == FILE_TYPE_SOCK )
+            {
+                socket_close( file_xp , fdid );
+            }
         }
     }
@@ -1348 +1336 @@
     process_t * process_ptr = GET_PTR( process_xp );
 
-assert( (hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp )) == process_xp),
+assert( __FUNCTION__, (hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp )) == process_xp),
 "process_xp argument must be the owner process" );
 
@@ -1379 +1367 @@
             remote_queuelock_acquire( lock_xp );
 
-        // access reference process descriptor
+        // access owner process descriptor
         file_xp = hal_remote_l64( XPTR( owner_cxy , &owner_ptr->fd_array.array[fdid] ) );
 
@@ -1386 +1374 @@
            // update local fd_array 
             process->fd_array.array[fdid] = file_xp;
-        
-            // increase file refcount
-            vfs_file_count_up( file_xp );
         }
 
@@ -1399 +1384 @@
 }  // end process_fd_get_xptr_from_local()
 
-///////////////////////////////////////////
-void process_fd_remote_copy( xptr_t dst_xp,
-                             xptr_t src_xp )
-{
-    uint32_t fd;
-    xptr_t   entry;
-
-    // get cluster and local pointer for src fd_array
-    cxy_t        src_cxy = GET_CXY( src_xp );
-    fd_array_t * src_ptr = GET_PTR( src_xp );
-
-    // get cluster and local pointer for dst fd_array
-    cxy_t        dst_cxy = GET_CXY( dst_xp );
-    fd_array_t * dst_ptr = GET_PTR( dst_xp );
+/////////////////////////////////////////
+void process_fd_replicate( xptr_t dst_xp,
+                           xptr_t src_xp )
+{
+    uint32_t fdid;      // current file descriptor index
+    xptr_t   old_xp;    // extended pointer on a file descriptor (stored in SRC fd_array) 
+    xptr_t   new_xp;    // extended pointer on a file descriptor (stored in DST fd_array)
+    error_t  error;
+
+    // get cluster and local pointer for SRC process
+    cxy_t       src_cxy = GET_CXY( src_xp );
+    process_t * src_ptr = GET_PTR( src_xp );
+
+assert( __FUNCTION__, (src_xp == hal_remote_l64( XPTR( src_cxy , &src_ptr->owner_xp ))),
+"src_xp process not in owner cluster" );
+
+    // get cluster and local pointer for DST fd_array
+    cxy_t       dst_cxy = GET_CXY( dst_xp );
+    process_t * dst_ptr = GET_PTR( dst_xp );
+
+assert( __FUNCTION__, (dst_xp == hal_remote_l64( XPTR( dst_cxy , &dst_ptr->owner_xp ))),
+"dst_xp process not in owner cluster" );
+
+    // build extende pointers on SRC fd_array lock and max fields
+    xptr_t  src_lock_xp = XPTR( src_cxy , &src_ptr->fd_array.lock );
+    xptr_t  src_max_xp  = XPTR( src_cxy , &src_ptr->fd_array.max );
 
     // get the remote lock protecting the src fd_array
-        remote_queuelock_acquire( XPTR( src_cxy , &src_ptr->lock ) );
-
-    // loop on all fd_array entries
-    for( fd = 0 ; fd < CONFIG_PROCESS_FILE_MAX_NR ; fd++ )
+        remote_queuelock_acquire( src_lock_xp );
+ 
+    // loop on fd_array entries
+    for( fdid = 0 ; fdid <= hal_remote_l32( src_max_xp ) ; fdid++ )
         {
-                entry = (xptr_t)hal_remote_l64( XPTR( src_cxy , &src_ptr->array[fd] ) );
-
-                if( entry != XPTR_NULL )
+                old_xp = (xptr_t)hal_remote_l64( XPTR( src_cxy , &src_ptr->fd_array.array[fdid] ) );
+
+                if( old_xp != XPTR_NULL )
                 {
-            // increment file descriptor refcount
-            vfs_file_count_up( entry );
-
-                        // copy entry in destination process fd_array
-                        hal_remote_s64( XPTR( dst_cxy , &dst_ptr->array[fd] ) , entry );
+            // get the existing file descriptor cluster and local pointer
+            vfs_file_t * old_ptr = GET_PTR( old_xp );
+            cxy_t        old_cxy = GET_CXY( old_xp );
+
+            // get existing file attributes and local pointer on inode
+            uint32_t      attr      = hal_remote_l32( XPTR( old_cxy , &old_ptr->attr ) );
+            vfs_inode_t * inode_ptr = hal_remote_lpt( XPTR( old_cxy , &old_ptr->inode ) );
+
+            // create a new file descriptor in same cluster as the existing one
+            error = vfs_file_create( XPTR( old_cxy , inode_ptr ),
+                                     attr,
+                                     &new_xp );
+            if( error )
+            {
+                printk("\n[ERROR] in %s : cannot create new file\n", __FUNCTION__ );
+                return;
+            }
+
+                        // register new_xp in DST fd_array
+                        hal_remote_s64( XPTR( dst_cxy , &dst_ptr->fd_array.array[fdid] ) , new_xp );
                 }
         }
 
     // release lock on source process fd_array
-        remote_queuelock_release( XPTR( src_cxy , &src_ptr->lock ) );
-
-}  // end process_fd_remote_copy()
+        remote_queuelock_release( src_lock_xp );
+
+}  // end process_fd_replicate()
 
 
@@ -1497 +1509 @@
             file_type = hal_remote_l32( XPTR( file_cxy , &file_ptr->type )); 
 
-            // get file name for a true file
-            if( file_type == INODE_TYPE_FILE )
+            // get file name if inode exist
+            if( (file_type != FILE_TYPE_PIPE) && (file_type != FILE_TYPE_SOCK) )
             {
                 // get inode pointers 
@@ -1507 +1519 @@
                 vfs_inode_get_name( inode_xp , name );
 
-                // display relevant file decriptor info
-                printk(" - %d : type %s (%s)\n",
-                fdid , process_fd_type_str(file_type), name );
+                // display relevant file descriptor info
+                printk(" - %d : type %s / ptr %x (%s)\n",
+                fdid, process_fd_type_str(file_type), file_ptr, name );
             }
-            else
+            else    // PIPE or SOCK types
             {
                 // display relevant file decriptor info
-                printk(" - %d : type %s\n",
-                fdid , process_fd_type_str(file_type) );
+                printk(" - %d : type %s / ptr %x\n",
+                fdid , process_fd_type_str(file_type), file_ptr );
             }
         }
         else
         {
-            // display relevant file decriptor info
             printk(" - %d : empty slot\n",
             fdid );
@@ -1540 +1551 @@
  
 // check arguments
-assert( (process != NULL) , "process argument is NULL" );
-assert( (thread != NULL) , "thread argument is NULL" );
+assert( __FUNCTION__, (process != NULL) , "process argument is NULL" );
+assert( __FUNCTION__, (thread != NULL) , "thread argument is NULL" );
 
     // get the lock protecting th_tbl for all threads
@@ -1580 +1591 @@
 
 // check thread
-assert( (thread != NULL) , "thread argument is NULL" );
+assert( __FUNCTION__, (thread != NULL) , "thread argument is NULL" );
 
     process_t * process = thread->process;
@@ -1594 +1605 @@
 
 // check th_nr value
-assert( (count > 0) , "process th_nr cannot be 0" );
+assert( __FUNCTION__, (count > 0) , "process th_nr cannot be 0" );
 
     // remove thread from th_tbl[]
@@ -1633 +1644 @@
 
 // check parent process is the reference process
-assert( (parent_process_xp == ref_xp ) ,
+assert( __FUNCTION__, (parent_process_xp == ref_xp ) ,
 "parent process must be the reference process" );
 
@@ -1711 +1722 @@
 cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_FORK < cycle )
-printk("\n[%s] thread[%x,%x] copied VMM from parent to child / cycle %d\n",
-__FUNCTION__, pid, trdid, cycle );
-hal_vmm_display( XPTR( local_cxy , process ) , true );
+{
+    printk("\n[%s] thread[%x,%x] copied VMM from parent to child / cycle %d\n",
+    __FUNCTION__, pid, trdid, cycle );
+    hal_vmm_display( XPTR( local_cxy , process ) , true );
+}
 #endif
 
@@ -1748 +1761 @@
 
 // check main thread LTID
-assert( (LTID_FROM_TRDID(thread->trdid) == 0) ,
+assert( __FUNCTION__, (LTID_FROM_TRDID(thread->trdid) == 0) ,
 "main thread must have LTID == 0" );
 
@@ -1806 +1819 @@
 }   // end process_make_fork()
 
-/////////////////////////////////////////////////////
-error_t process_make_exec( exec_info_t  * exec_info )
-{
-    thread_t       * thread;                  // local pointer on this thread
+////////////////////////////////////////////////i//////////////////////////////////////
+// This static function is called by the thread_user_exec() function :
+// - to register the main() arguments (args) in the <exec_info> structure.
+// - to register the environment variables (envs) in the <exec_info> structure.
+// In both cases the input is an array of NULL terminated string pointers in user
+// space, and the strings can be dispatched anywhere in the user process space.
+// This array of pointers is defined by the <u_pointers> argument. The empty slots 
+// contain the NULL value, and the N non-empty slots are indexed from 0 to (N-1).
+// - The max number of envs, and the max number of args are defined by the
+//   CONFIG_PROCESS_ARGS_NR and CONFIG_PROCESS_ENVS_MAX_NR parameters. 
+// - The numbers of pages to store the (args) and (envs) strings are defined by the
+//   CONFIG_VMM_ENVS_SIZE and CONFIG_VMM_STACK_SIZE parameters.
+///////////////////////////////////////////////////////////////////////////////////////
+// Implementation note:
+// It allocates a kernel buffer to store a kernel copy of both the array of pointers,
+// and the strings. It set the pointers and copies the strings in this kernel buffer.
+// Finally, it registers the buffer & the actual number of strings in the process
+// exec_info structure  (defined in the <process.h> file).
+///////////////////////////////////////////////////////////////////////////////////////
+// @ is_args     : [in]    true if called for (args) / false if called for (envs).
+// @ u_pointers  : [in]    array of pointers on the strings (in user space).
+// @ exec_info   : [out]   pointer on the exec_info structure.
+// @ return 0 if success / non-zero if too many strings or no memory.
+///////////////////////////////////////////////////////////////////////////////////////
+error_t process_exec_get_strings( bool_t         is_args,
+                                  char        ** u_pointers,
+                                  exec_info_t  * exec_info )
+{
+    uint32_t     index;           // slot index in pointers array
+    uint32_t     length;          // string length (in bytes)
+    uint32_t     pointers_bytes;  // number of bytes to store pointers
+    uint32_t     max_index;       // max size of pointers array
+    char      ** k_pointers;      // base of kernel array of pointers
+    char       * k_buf_ptr;       // pointer on first empty slot in strings buffer
+    uint32_t     k_buf_space;     // number of bytes available in string buffer
+    kmem_req_t   req;             // kernel memory allocator request
+    char       * k_buf;           // kernel buffer for both pointers & strings 
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+thread_t * this  = CURRENT_THREAD;
+uint32_t   cycle = (uint32_t)hal_get_cycles();
+#endif
+
+    // Allocate one block of physical memory for both the pointers and the strings
+    // as defined by the CONFIG_VMM_ARGS_SIZE and CONFIG_VMM_ENVS_SIZE parameters
+    // - the array of pointers is stored in the first bytes of the kernel buffer
+    // - the strings themselve are stored in the next bytes of this buffer
+    // Set the k_pointers, k_buf_ptr, k_buf_space, and max_index
+
+    if( is_args )
+    {
+        req.type   = KMEM_PPM;
+        req.order  = bits_log2( CONFIG_VMM_ARGS_SIZE );
+        req.flags  = AF_KERNEL | AF_ZERO;
+        k_buf      = kmem_alloc( &req );
+
+        pointers_bytes = CONFIG_PROCESS_ARGS_MAX_NR * sizeof(char *);
+        k_pointers     = (char **)k_buf;
+        k_buf_ptr      = k_buf + pointers_bytes;
+        k_buf_space    = (CONFIG_VMM_ARGS_SIZE * CONFIG_PPM_PAGE_SIZE) - pointers_bytes;
+        max_index      = CONFIG_PROCESS_ARGS_MAX_NR;
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+if( DEBUG_PROCESS_EXEC_GET_STRINGS < cycle )
+printk("\n[%s] thread[%x,%x] for args / u_buf %x / k_buf %x\n",
+__FUNCTION__, this->process->pid, this->trdid, u_pointers, k_buf );
+#endif
+
+    }
+    else
+    {
+        req.type   = KMEM_PPM;
+        req.order  = bits_log2( CONFIG_VMM_ENVS_SIZE );
+        req.flags  = AF_KERNEL | AF_ZERO;
+        k_buf      = kmem_alloc( &req );
+
+        pointers_bytes = CONFIG_PROCESS_ENVS_MAX_NR * sizeof(char *);
+        k_pointers     = (char **)k_buf;
+        k_buf_ptr      = k_buf + pointers_bytes;
+        k_buf_space    = (CONFIG_VMM_ENVS_SIZE * CONFIG_PPM_PAGE_SIZE) - pointers_bytes;
+        max_index      = CONFIG_PROCESS_ENVS_MAX_NR;
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+if( DEBUG_PROCESS_EXEC_GET_STRINGS < cycle )
+printk("\n[%s] thread[%x,%x] for envs / u_buf %x / k_buf %x\n",
+__FUNCTION__, this->process->pid, this->trdid, u_pointers, k_buf );
+#endif
+
+    }
+
+    // copy the user array of pointers to kernel buffer
+    hal_copy_from_uspace( XPTR( local_cxy , k_pointers ),
+                          u_pointers,
+                          pointers_bytes );
+
+    // WARNING : the pointers copied in the k_pointers[] array are user pointers,
+    // after the loop below, the k_pointers[] array contains kernel pointers.
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+if( DEBUG_PROCESS_EXEC_GET_STRINGS < cycle )
+printk("\n[%s] thread[%x,%x] copied u_ptr array to k_ptr array\n"
+"    p0 = %x / p1 = %x / p2 = %x / p3 = %x\n",
+__FUNCTION__, this->process->pid, this->trdid,
+k_pointers[0], k_pointers[1], k_pointers[2], k_pointers[3] );
+#endif
+
+    // scan kernel array of pointers to copy strings to kernel buffer
+    for( index = 0 ; index < max_index ; index++ )
+    {
+        // exit loop if (k_pointers[] == NUll)
+        if( k_pointers[index] == NULL ) break;
+
+        // compute string length 
+        length = hal_strlen_from_uspace( k_pointers[index] ) + 1;
+
+        // return error if overflow in kernel buffer
+        if( length > k_buf_space ) return -1;
+
+        // copy the string to kernel buffer
+        hal_copy_from_uspace( XPTR( local_cxy , k_buf_ptr ),
+                              k_pointers[index],
+                              length );
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+if( DEBUG_PROCESS_EXEC_GET_STRINGS < cycle )
+printk("\n[%s] thread[%x,%x] copied string[%d] <%s> to kernel buffer / length %d\n",
+__FUNCTION__, this->process->pid, this->trdid, index, k_buf_ptr, length );
+#endif
+
+        // replace the user pointer by a kernel pointer in the k_pointer[] array
+        k_pointers[index] = k_buf_ptr;
+
+        // increment loop variables
+        k_buf_ptr   += length;
+        k_buf_space -= length;
+
+    }  // end loop on index
+
+    // update into exec_info structure
+    if( is_args )
+    {
+        exec_info->args_pointers  =  k_pointers;
+        exec_info->args_nr        =  index;
+    }
+    else
+    {
+        exec_info->envs_pointers  =  k_pointers;
+        exec_info->envs_buf_free  =  k_buf_ptr;
+        exec_info->envs_nr        =  index;
+    }
+
+#if DEBUG_PROCESS_EXEC_GET_STRINGS 
+if( DEBUG_PROCESS_EXEC_GET_STRINGS < cycle )
+printk("\n[%s] thread[%x,%x] copied %d strings to kernel buffer\n",
+__FUNCTION__, this->process->pid, this->trdid, index );
+#endif
+
+    return 0;
+
+} // end process_exec_get_strings()
+
+/////////////////////////////////
+error_t process_make_exec( void )
+{
+    thread_t       * this;                    // local pointer on this thread
     process_t      * process;                 // local pointer on this process
     pid_t            pid;                     // this process identifier
+    trdid_t          trdid;                   // this thread identifier
     xptr_t           ref_xp;                  // reference process for this process
         error_t          error;                   // value returned by called functions
-    char           * path;                    // path to .elf file
+    char           * elf_path;                // path to .elf file
     xptr_t           file_xp;                 // extended pointer on .elf file descriptor
     uint32_t         file_id;                 // file index in fd_array
-    uint32_t         args_nr;                 // number of main thread arguments
-    char          ** args_pointers;           // array of pointers on main thread arguments
-
-    // get calling thread, process, pid and ref_xp 
-    thread  = CURRENT_THREAD;
-    process = thread->process;
+    vseg_t         * vseg;                    // local pointer on created vseg(s)
+    uint32_t         n;                       // index for loops
+
+    uint32_t         args_nr;                 // actual number of args (from exec_info)
+    intptr_t         args_base;               // args vseg base address in user space
+    uint32_t         args_size;               // args vseg size (bytes)
+
+    uint32_t         envs_nr;                 // actual number of envs (from exec_info)
+    intptr_t         envs_base;               // envs vseg base address in user space
+    uint32_t         envs_size;               // envs vseg size (bytes)
+
+    // get calling thread, process, pid, trdid, and ref_xp 
+    this    = CURRENT_THREAD;
+    process = this->process;
     pid     = process->pid;
+    trdid   = this->trdid;
     ref_xp  = process->ref_xp;
 
-        // get relevant infos from exec_info
-        path          = exec_info->path;
-    args_nr       = exec_info->args_nr;
-    args_pointers = exec_info->args_pointers;
+        // get .elf pathname from exec_info structure
+        elf_path      = process->exec_info.path;
 
 #if DEBUG_PROCESS_MAKE_EXEC
 uint32_t cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] enters for %s / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, path, cycle );
-#endif
-
-    // open the file identified by <path>
+printk("\n[%s] thread[%x,%x] enters for <%s> / cycle %d\n",
+__FUNCTION__, pid, trdid, elf_path, cycle );
+#endif
+
+    // 1. open the file identified by <path>
     file_xp = XPTR_NULL;
     file_id = 0xFFFFFFFF;
         error   = vfs_open( process->vfs_root_xp,
-                            path,
+                            elf_path,
                         ref_xp,
                             O_RDONLY,
@@ -1850 +2032 @@
         if( error )
         {
-                printk("\n[ERROR] in %s : failed to open file <%s>\n", __FUNCTION__ , path );
+                printk("\n[ERROR] in %s : thread[%x,%x] failed to open file <%s>\n",
+        __FUNCTION__, pid, trdid, elf_path );
                 return -1;
         }
 
 #if (DEBUG_PROCESS_MAKE_EXEC & 1)
-cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] opened file <%s> / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, path, cycle );
-#endif
-
-    // delete all threads other than this main thread in all clusters
+printk("\n[%s] thread[%x,%x] opened file <%s>\n",
+__FUNCTION__, pid, trdid, elf_path );
+#endif
+
+    // 2. delete all threads other than this main thread in all clusters
     process_sigaction( pid , DELETE_ALL_THREADS );
 
 #if (DEBUG_PROCESS_MAKE_EXEC & 1)
-cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] deleted existing threads / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, cycle );
-#endif
-
-    // reset calling process VMM
+printk("\n[%s] thread[%x,%x] deleted existing threads\n",
+__FUNCTION__, pid, trdid );
+#endif
+
+    // 3. reset calling process VMM
     vmm_user_reset( process );
 
 #if( DEBUG_PROCESS_MAKE_EXEC & 1 )
-cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] completed VMM reset / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, cycle );
-#endif
-
-    // re-initialize the VMM (args/envs vsegs registration)
-    error = vmm_user_init( process );
-    if( error )
-    {
-        printk("\n[ERROR] in %s : cannot initialise VMM for %s\n", __FUNCTION__ , path );
-        vfs_close( file_xp , file_id );
-        // FIXME restore old process VMM [AG]
-        return -1;
-    }
-    
+{
+    printk("\n[%s] thread[%x,%x] completed VMM reset\n",
+    __FUNCTION__, pid, trdid );
+    hal_vmm_display( ref_xp , true );
+}
+#endif
+
+    // 4. register the "args" vseg in VSL and map it in GPT, if required
+    // this vseg contains both the array of pointers and the strings
+    args_nr = process->exec_info.args_nr;
+
+    if( args_nr > 0 )
+    {
+        // get args vseg base and size in user space
+        args_base = CONFIG_VMM_UTILS_BASE << CONFIG_PPM_PAGE_SHIFT;
+        args_size = CONFIG_VMM_ARGS_SIZE << CONFIG_PPM_PAGE_SHIFT;
+
+        // create and register args vseg in VMM
+        vseg = vmm_create_vseg( process,
+                                VSEG_TYPE_DATA,
+                                args_base,
+                                args_size,
+                                0,                 // file_offset unused for DATA type
+                                0,                 // file_size unused for DATA type
+                                XPTR_NULL,         // mapper_xp unused for DATA type
+                                0 );               // cxy unused for DATA type
+        if( vseg == NULL )
+        {
+                 printk("\n[ERROR] in %s : thread[%x,%x] cannot get args vseg for <%s>\n",
+             __FUNCTION__, pid, trdid, elf_path );
+                     return -1;
+        }
+
 #if( DEBUG_PROCESS_MAKE_EXEC & 1 )
-cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] registered args/envs vsegs / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, cycle );
-#endif
-
-    // register code & data vsegs as well as entry-point in process VMM,
-    // and register extended pointer on .elf file in process descriptor
+{
+    printk("\n[%s] thread[%x,%x] args vseg registered in new process VSL\n",
+    __FUNCTION__, pid, trdid );
+    hal_vmm_display( ref_xp , true );
+}
+#endif
+        // map all pages for this "args" vseg
+        uint32_t fake_attr;   // required for hal_gpt_lock_pte()
+        ppn_t    fake_ppn;    // required for hal_gpt_lock_pte()
+
+        xptr_t   gpt  = XPTR( local_cxy , &process->vmm.gpt );
+        uint32_t attr = GPT_MAPPED | GPT_SMALL | GPT_READABLE | GPT_USER | GPT_CACHABLE;
+        vpn_t    vpn  = CONFIG_VMM_UTILS_BASE;
+        ppn_t    ppn  = ((ppn_t)process->exec_info.args_pointers >> CONFIG_PPM_PAGE_SHIFT);
+
+        for( n = 0 ; n < CONFIG_VMM_ARGS_SIZE ; n++ )  
+        {
+            // lock the PTE
+            if (hal_gpt_lock_pte( gpt , vpn , &fake_attr , &fake_ppn ) )
+            {
+                printk("\n[ERROR] in %s : thread[%x,%x] cannot map args vpn %x for <%s>\n",
+                __FUNCTION__, pid, trdid, vpn, elf_path );
+                        return -1;
+            }
+
+            // map and unlock the PTE
+            hal_gpt_set_pte( gpt , vpn + n , attr , ppn + n );
+        }
+
+#if( DEBUG_PROCESS_MAKE_EXEC & 1 )
+if( DEBUG_PROCESS_MAKE_EXEC < cycle )
+{
+    printk("\n[%s] thread[%x,%x] args vseg mapped in new process GPT\n",
+    __FUNCTION__, pid, trdid );
+    hal_vmm_display( ref_xp , true );
+}
+#endif
+
+        // set user space pointers in array of pointers
+        char  ** ptr    = process->exec_info.args_pointers;
+
+        for( n = 0 ; n < args_nr ; n++ )
+        {
+            ptr[n] = ptr[n] + args_base - (intptr_t)ptr;
+        } 
+    }
+
+    // 5. register the "envs" vseg in VSL and map it in GPT, if required
+    // this vseg contains both the array of pointers and the strings
+    envs_nr = process->exec_info.envs_nr;
+
+    if( envs_nr > 0 )
+    {
+        // get envs vseg base and size in user space from config
+        envs_base = (CONFIG_VMM_UTILS_BASE + CONFIG_VMM_ARGS_SIZE) << CONFIG_PPM_PAGE_SHIFT;
+        envs_size = CONFIG_VMM_ENVS_SIZE << CONFIG_PPM_PAGE_SHIFT;
+
+        // TODO (inspired from args)
+    }
+
+
+    // 6. register code & data vsegs, and entry-point in process VMM,
+    // register extended pointer on .elf file in process descriptor
         error = elf_load_process( file_xp , process );
     if( error )
         {
-                printk("\n[ERROR] in %s : failed to access <%s>\n", __FUNCTION__ , path );
-        vfs_close( file_xp , file_id );
-        // FIXME restore old process VMM [AG]
+                printk("\n[ERROR] in %s : thread[%x,%x] failed to access <%s>\n",
+        __FUNCTION__, pid, trdid, elf_path );
         return -1;
         }
 
 #if( DEBUG_PROCESS_MAKE_EXEC & 1 )
-cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_PROCESS_MAKE_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] registered code/data vsegs / cycle %d\n",
-__FUNCTION__, pid, thread->trdid, cycle );
-#endif
-
-    // update the existing main thread descriptor... and jump to user code 
-    error = thread_user_exec( (void *)process->vmm.entry_point,
-                              args_nr,
-                              args_pointers );
+{
+    printk("\n[%s] thread[%x,%x] registered code/data vsegs / entry %x\n",
+    __FUNCTION__, pid, trdid, process->vmm.entry_point );
+    hal_vmm_display( ref_xp , true );
+}
+#endif
+
+    // 7. allocate an user stack vseg for main thread
+    vseg = vmm_create_vseg( process,
+                            VSEG_TYPE_STACK,
+                            LTID_FROM_TRDID( trdid ),
+                            0,                 // length unused
+                            0,                 // file_offset unused
+                            0,                 // file_size unused
+                            XPTR_NULL,         // mapper_xp unused
+                            local_cxy );
+    if( vseg == NULL )
+    {
+            printk("\n[ERROR] in %s : thread[%x,%x] cannot set u_stack vseg for <%s>\n",
+        __FUNCTION__, pid, trdid, elf_path );
+                return -1;
+    }
+
+#if( DEBUG_PROCESS_MAKE_EXEC & 1 )
+if( DEBUG_PROCESS_MAKE_EXEC < cycle )
+{
+    printk("\n[%s] thread[%x,%x] registered stack vseg\n",
+    __FUNCTION__, pid, trdid );
+    hal_vmm_display( ref_xp , true );
+}
+#endif
+
+    // update user stack in thread descriptor
+    this->user_stack_vseg = vseg;
+
+    // 8. update the main thread descriptor ... and jumps (one way) to user code 
+    thread_user_exec( args_nr , args_base );
+
     if( error )
     {
-        printk("\n[ERROR] in %s : cannot update main thread for %s\n", __FUNCTION__ , path );
-        vfs_close( file_xp , file_id );
-        // FIXME restore old process VMM 
+        printk("\n[ERROR] in %s : thread[%x,%x] cannot update thread for <%s>\n",
+        __FUNCTION__ , pid, trdid, elf_path );
         return -1;
     }
 
-    assert( false, "we should not execute this code");
- 
         return 0;
 
@@ -2153 +2433 @@
 #if(DEBUG_PROCESS_INIT_CREATE & 1)
 if( DEBUG_PROCESS_INIT_CREATE < cycle )
-printk("\n[%s] thread[%x,%x] registered code/data vsegs in VMM\n",
-__FUNCTION__, this->process->pid, this->trdid );
-#endif
-
-#if (DEBUG_PROCESS_INIT_CREATE & 1)
-hal_vmm_display( XPTR( local_cxy , process ) , true );
+{
+    printk("\n[%s] thread[%x,%x] registered code/data vsegs in VMM\n",
+    __FUNCTION__, this->process->pid, this->trdid );
+    hal_vmm_display( XPTR( local_cxy , process ) , true );
+}
 #endif
 
@@ -2291 +2570 @@
         txt_file_xp = hal_remote_l64( XPTR( owner_cxy , &owner_ptr->fd_array.array[0] ) );
 
-        assert( (txt_file_xp != XPTR_NULL) ,
+        assert( __FUNCTION__, (txt_file_xp != XPTR_NULL) ,
         "process must be attached to one TXT terminal" ); 
 
@@ -2363 +2642 @@
     }
 
-    assert( false , "no free TXT terminal found" );
+    assert( __FUNCTION__, false , "no free TXT terminal found" );
 
     return -1;
@@ -2370 +2649 @@
 
 /////////////////////////////////////////////
-void process_txt_attach( process_t * process,
-                         uint32_t    txt_id )
+void process_txt_attach( xptr_t   process_xp,
+                         uint32_t txt_id )
 {
     xptr_t      chdev_xp;     // extended pointer on TXT_RX chdev
@@ -2379 +2658 @@
     xptr_t      lock_xp;      // extended pointer on list lock in chdev
 
+    process_t * process_ptr = GET_PTR(process_xp );
+    cxy_t       process_cxy = GET_CXY(process_xp );
+
 // check process is in owner cluster
-assert( (CXY_FROM_PID( process->pid ) == local_cxy) ,
+assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ))),
 "process descriptor not in owner cluster" );
 
 // check terminal index
-assert( (txt_id < LOCAL_CLUSTER->nb_txt_channels) ,
+assert( __FUNCTION__, (txt_id < LOCAL_CLUSTER->nb_txt_channels) ,
 "illegal TXT terminal index" );
 
@@ -2399 +2681 @@
     remote_busylock_acquire( lock_xp );
 
-    // insert process in attached process list
-    xlist_add_last( root_xp , XPTR( local_cxy , &process->txt_list ) );
+    // insert owner process in list of attached processes to same TXT
+    xlist_add_last( root_xp , XPTR( process_cxy , &process_ptr->txt_list ) );
 
     // release lock protecting list of processes attached to TXT
@@ -2410 +2692 @@
 if( DEBUG_PROCESS_TXT < cycle )
 printk("\n[%s] thread[%x,%x] attached process %x to TXT %d / cycle %d\n",
-__FUNCTION__, this->process->pid, this->trdid, process->pid, txt_id , cycle );
+__FUNCTION__, this->process->pid, this->trdid,
+hal_remote_l32( XPTR( process_cxy , &process_ptr->pid, txt_id , cycle );
 #endif
 
@@ -2433 +2716 @@
 
 // check process descriptor in owner cluster
-assert( (CXY_FROM_PID( process_pid ) == process_cxy ) ,
+assert( __FUNCTION__, (CXY_FROM_PID( process_pid ) == process_cxy ) ,
 "process descriptor not in owner cluster" );
 
@@ -2471 +2754 @@
 
 ///////////////////////////////////////////////////
+uint32_t process_txt_get_index( xptr_t process_xp )
+{
+
+    // get target process cluster and local pointer
+    process_t * process_ptr = GET_PTR( process_xp );
+    cxy_t       process_cxy = GET_CXY( process_xp );
+
+assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp))),
+"process descriptor not in owner cluster" );
+
+    // get extended pointer on STDIN pseudo file in owner process descriptor
+    xptr_t file_xp = hal_remote_l64( XPTR( process_cxy , &process_ptr->fd_array.array[0]));
+
+assert( __FUNCTION__, (file_xp != XPTR_NULL),
+"STDIN pseudo-file undefined in fd_array for process %x\n",
+hal_remote_l32( XPTR( process_cxy , &process_ptr->pid ) ) );
+
+    // get extended pointer on TXT chdev
+    xptr_t chdev_xp = chdev_from_file( file_xp );
+ 
+assert( __FUNCTION__, (chdev_xp != XPTR_NULL),
+"chdev undefined for STDIN pseudo-file of process %x\n",
+hal_remote_l32( XPTR( process_cxy , &process_ptr->pid ) ) );
+
+    // get cluster and local pointer on chdev
+   cxy_t     chdev_cxy = GET_CXY( chdev_xp );
+   chdev_t * chdev_ptr = GET_PTR( chdev_xp );
+ 
+   // get parent TXT terminal index
+   return hal_remote_l32( XPTR( chdev_cxy , &chdev_ptr->channel ) );
+
+}  // end process_txt_get_index()
+
+///////////////////////////////////////////////////
 void process_txt_set_ownership( xptr_t process_xp )
 {
     process_t * process_ptr;
     cxy_t       process_cxy;
-    pid_t       process_pid;
     xptr_t      file_xp;
     xptr_t      txt_xp;     
@@ -2484 +2800 @@
     process_cxy = GET_CXY( process_xp );
     process_ptr = GET_PTR( process_xp );
-    process_pid = hal_remote_l32( XPTR( process_cxy , &process_ptr->pid ) );
 
     // check owner cluster
-    assert( (process_cxy == CXY_FROM_PID( process_pid )) ,
+    assert( __FUNCTION__, (process_xp == hal_remote_l64( XPTR( process_cxy , &process_ptr->owner_xp ))),
     "process descriptor not in owner cluster" );
 
@@ -2506 +2821 @@
 uint32_t txt_id = hal_remote_l32( XPTR( txt_cxy , &txt_ptr->channel ) );
 if( DEBUG_PROCESS_TXT < cycle )
-printk("\n[%s] thread[%x,%x] give TXT%d ownership to process %x / cycle %d\n",
-__FUNCTION__, this->process->pid, this->trdid, txt_id, process_pid, cycle );
+printk("\n[%s] thread[%x,%x] give TXT%d ownership to process / cycle %d\n",
+__FUNCTION__, this->process->pid, this->trdid, txt_id, cycle );
 #endif
 
@@ -2541 +2856 @@
 
 // check owner cluster
-assert( (process_cxy == CXY_FROM_PID( process_pid )) ,
+assert( __FUNCTION__, (process_cxy == CXY_FROM_PID( process_pid )) ,
 "process descriptor not in owner cluster" );
 
@@ -2595 +2910 @@
 
 // It must exist a KSH process for each user TXT channel
-assert( (found == true), "KSH process not found for TXT%d", txt_id );
+assert( __FUNCTION__, (found == true), "KSH process not found for TXT%d", txt_id );
 
         }
@@ -2671 +2986 @@
 // check calling thread execute in target process owner cluster
 pid_t process_pid = hal_remote_l32( XPTR( process_cxy , &process_ptr->pid ) );
-assert( (process_cxy == CXY_FROM_PID( process_pid )) ,
+assert( __FUNCTION__, (process_cxy == CXY_FROM_PID( process_pid )) ,
 "process descriptor not in owner cluster" );
 
@@ -2715 +3030 @@
     xptr_t      txt0_lock_xp;
     
-    assert( (txt_id < LOCAL_CLUSTER->nb_txt_channels) ,
+    assert( __FUNCTION__, (txt_id < LOCAL_CLUSTER->nb_txt_channels) ,
     "illegal TXT terminal index" );
 

trunk/kernel/kern/process.h

@@ -71 +71 @@
  * This structure defines an array of extended pointers on the open file descriptors
  * for a given process. The file descriptors are always stored in the same cluster 
- * as the inode associated to the file. A free entry in this array contains XPTR_NULL.
+ * as the object associated to the file descriptor (inode, socket, pipe, etc). 
+ * A free entry in this array contains XPTR_NULL.
  * The array size is defined by the CONFIG_PROCESS_FILE_MAX_NR parameter.
  *
- * NOTE: - Only the fd_array[] in the reference process contains the complete list of open
- *         files, and is protected by the lock against concurrent access.
- *       - the fd_array[] in a process copy is not used.
- *         open files to speed the fdid to xptr translation, but the "lock" and "max"
- *         fields are not significant for these copies.
+ * NOTE: - Only the fd_array[] in the owner cluster process contains the complete list
+ *         of open files, and is protected by the lock against concurrent access.
+ *       - the fd_array[] in a process copy is only used to speed the fdid -> xptr
+ *         translation, but the "lock" and "max" fields are not significant in these copies.
  *       - The modifications made by the process_fd_register() function are only done
  *         in the owner cluster.
  *       - The modifications made by the process_fd_remove() function are done in the
  *         owner cluster, and in all process_copies.
- *       - In case of miss on the local fd_array, the process_fd_get_xptr() access the
+ *       - In case of miss on a local fd_array, the process_fd_get_xptr() access the
  *         owner cluster fd_array, and update the fd_array local copy.
  ********************************************************************************************/
@@ -94 +94 @@
 }
 fd_array_t;
+
+/*********************************************************************************************
+ * This structure defines the information required by the process_make_exec() function
+ * to create a new reference process descriptor, and the associated main thread.
+ * All fields in this structure are filled by the sys_exec() function, using the
+ * process_exec_get_strings() function.
+ *
+ * It contains three parts:
+ * - the "path" field is a string defining the pathname of the .elf file.
+ * - the "args_pointers" & "args_nr" fields define the arguments (one arg == one string).
+ * - the "envs_pointers" & "envs_nr" fields define the env variables (one env == one string).
+ *
+ * For both the arguments, and the environment variables, the array of pointers and the
+ * strings themselve are stored in kernel space in the same kernel buffer containing
+ * an integer number of pages, defined by CONFIG_VMM_ARGS_SIZE and CONFIG_VMM_ENVS_SIZE.
+ * This aligned kernel buffer (one or several contiguous physical pages) contains :
+ * - in the first bytes, a fixed size kernel array of pointers on the strings.
+ * - in the following bytes, the strings themselves.
+ * The size of these arrays of pointers is defined by CONFIG_PROCESS_ARGS_MAX_NR
+ * and CONFIG¨PROCESS_ENVS_MAX_NR.
+ *
+ * WARNING: The "args_pointers" & "envs_pointers" kernel buffer are directly mapped to
+ *          the "args" and "envs" user vsegs to be accessed by the user process. 
+ *          Therefore, the arrays of pointers build by the sys_exec() function contain
+ *          kernel pointers, but the process_make_exec() function replace these pointers
+ *          by user pointers in the new process user space.
+ ********************************************************************************************/
+
+typedef struct exec_info_s
+{
+    char           path[CONFIG_VFS_MAX_PATH_LENGTH];  /*! .elf file path in kernel space    */
+
+    char        ** args_pointers;  /*! pointer on array of pointers on strings              */
+    uint32_t       args_nr;        /*! actual number of arguments                           */
+
+    char        ** envs_pointers;  /*! pointer on array of pointers on strings              */
+    uint32_t       envs_nr;        /*! actual number of environment variables               */
+    char         * envs_buf_free;  /*! local pointer on first free slot in strings buffer   */
+}
+exec_info_t;
 
 /*********************************************************************************************
@@ -112 +152 @@
  *    are actually use as read-only caches.
  * 3) the <fd_array>, containing extended pointers on the open file descriptors, is only
- *    complete in the reference process cluster, other copies are read-only caches.
+ *    complete in the owner process cluster, other copies are read-only caches.
  * 4) The <sem_root>, <mutex_root>, <barrier_root>, <condvar_root>, and the associated
  *    <sync_lock>, dynamically allocated, are only defined in the reference cluster.
@@ -129 +169 @@
     fd_array_t         fd_array;         /*! embedded open file descriptors array            */
 
+    exec_info_t        exec_info;        /*! embedded structure for args & envs              */
+
     xptr_t             vfs_root_xp;      /*! extended pointer on VFS root inode              */
     xptr_t             vfs_bin_xp;       /*! extended pointer on .elf file descriptor        */
@@ -165 +207 @@
 }
 process_t;
-
-/*********************************************************************************************
- * This structure defines the information required by the process_make_exec() function
- * to create a new reference process descriptor, and the associated main thread.
- ********************************************************************************************/
-
-typedef struct exec_info_s
-{
-    char               path[CONFIG_VFS_MAX_PATH_LENGTH];   /*!  .elf file path              */
-
-    char            ** args_pointers;  /*! physical base address of array of pointers       */
-    char             * args_buf_base;  /*! physical base address of kernel args buffer      */
-    uint32_t           args_nr;        /*! actual number of arguments                       */
-
-    char            ** envs_pointers;  /*! physical base address of array of pointers       */
-    char             * envs_buf_base;  /*! physical base address of kernel args buffer      */
-    char             * envs_buf_free;  /*! physical address of first free slot in envs_buf  */
-    uint32_t           envs_nr;        /*! actual number of environment variables           */
-}
-exec_info_t;
 
 /***************   Process Descriptor Operations    *****************************************/
@@ -393 +415 @@
 
 /*********************************************************************************************
- * This function implements the "exec" system call, and is called by the sys_exec() function.
+ * This function is called twice by the sys_exec() function :
+ * - to register the main() arguments (args) in the process <exec_info> structure.
+ * - to register the environment variables (envs) in the <exec_info> structure.
+ * In both cases the input is an array of NULL terminated string pointers in user space,
+ * identified by the <u_pointers> argument. The strings can be dispatched anywhere in 
+ * the calling user process space. The max number of envs, and the max number of args are 
+ * defined by the CONFIG_PROCESS_ARGS_NR and CONFIG_PROCESS_ENVS_MAX_NR parameters. 
+ *********************************************************************************************
+ * Implementation Note:
+ * Both the array of pointers and the strings themselve are stored in kernel space in one
+ * single, dynamically allocated, kernel buffer containing an integer number of pages,
+ * defined by the CONFIG_VMM_ENVS_SIZE and CONFIG_VMM_STACK_SIZE parameters.
+ * This aligned kernel buffer (one or several contiguous physical pages) contains :
+ * - in the first bytes a fixed size kernel array of kernel pointers on the strings.
+ * - in the following bytes the strings themselves.
+ * All the pointers, and the actual number of strings are stored in the process exec_info
+ * structure defined in the <process.h> file.
+ *********************************************************************************************
+ * @ is_args     : [in]    true if called for (args) / false if called for (envs).
+ * @ u_pointers  : [in]    array of pointers on the strings (in user space).
+ * @ exec_info   : [inout] pointer on the exec_info structure.
+ * @ return 0 if success / non-zero if too many strings or no memory.
+ ********************************************************************************************/
+error_t process_exec_get_strings( bool_t         is_args,
+                                  char        ** u_pointers,
+                                  exec_info_t  * exec_info );
+
+/*********************************************************************************************
+ * This function implements the "execve" system call, and is called by sys_exec() function.
+ * It must be called by the main thread of the calling "old" process.
+ * The <exec_info> structure in process descriptor contains all informations required
+ * to update both the calling process descriptor and the calling thread descriptor.
  * The "new" process keep the "old" process PID and PPID, all open files, and env variables,
- * the vfs_root and vfs_cwd, but build a brand new memory image (new VMM from the new .elf).
+ * the vfs_root and vfs_cwd, but build a brand new memory image (new VMM from the .elf file).
  * It is executed in the local cluster, that becomes both the "owner" and the "reference"
  * cluster for the "new" process.
  *********************************************************************************************
- * @ exec_info   : [in]  pointer on the exec_info structure.
+ * Implementation note:
+ * It executes the following sequence:
+ * 1) it creates a file descriptor for the .elf file (pathname in exec_info).
+ * 2) it deletes all other threads than the main thread, in all clusters.
+ * 3) it reset the existing VMM (remove all user vsegs).
+ * 4) it build the "args" user vseg from process exec_info, and registers in the VMM. 
+ * 5) TODO it build the "envs" user vseg from process exec_info, and registers in the VMM.
+ * 6) it get the "code" and "data" user vsegs from the .elf file, and registers in the VMM.
+ * 7) it allocates an user "stack" vseg, and registers in the VMM
+ * 8) it calls thread_user_exec() to complete thread initialisation and jumps to user code.
+ *********************************************************************************************
  * @ return 0 if success / return non-zero if error.
  ********************************************************************************************/
-error_t process_make_exec( exec_info_t * exec_info );
+error_t process_make_exec( void );
 
 /*********************************************************************************************
@@ -452 +515 @@
  * and return the slot index in the <fdid> buffer.
  * It can be called by any thread in any cluster.
- * It takes the lock protecting the fd_array against concurrent accesses.
- * Note: we must use the owner process descriptor, because this fd_array must
- * contain all files open by a given process.
- *********************************************************************************************
- * @ process_xp : [in]  extended pointer on client reference process.
+ * It takes the lock protecting the fd_array against concurrent slot allocations.
+ * Note: we must use the owner process descriptor, because only this fd_array contains
+ * all files open by a given process.
+ *********************************************************************************************
+ * @ process_xp : [in]  extended pointer on owner process.
  * @ file_xp    : [in]  extended pointer on the file descriptor to be registered.
  * @ fdid       : [out] buffer for allocated fd_array slot index.
@@ -470 +533 @@
  * process descriptor, identified by the <process_xp> argument. 
  * It can be called by any thread in any cluster.
- * It takes the lock protecting the fd_array against concurrent accesses.
+ * It takes the lock protecting the list of copies.
  * Note: we must use the owner process descriptor, because only this owner cluster contains
  * the complete list of process copies.
@@ -523 +586 @@
 
 /*********************************************************************************************
- * This function copies all non-zero entries (other than the three first stdin/stdout/stderr)
- * from a remote <src_xp> fd_array, embedded in a process descriptor, to another remote 
- * <dst_xp> fd_array, embedded in another process descriptor. 
- * The calling thread can be running in any cluster.
- * It takes the lock protecting the reference fd_array against concurrent accesses.
- * For each involved file descriptor, the refcount is incremented.
- *********************************************************************************************
- * @ dst_xp   : extended pointer on the destination fd_array_t.
- * @ src_xp   : extended pointer on the source fd_array_t.
- ********************************************************************************************/
-void process_fd_remote_copy( xptr_t dst_xp,
-                             xptr_t src_xp );
+ * This function scans all entries in a fd_array, identified by the <src_xp> argument, that
+ * must be the process descriptor in owner cluster. For each non-zero entry, it allocates a
+ * new file descriptor in the cluster containing the involved inode, and registers it in the
+ * fd_array identified by the <dst_xp> argument, that must also be the process descriptor in
+ * owner cluster. The calling thread itself can be running in any cluster.
+ * It takes the lock protecting the <src_xp> fd_array against concurrent accesses.
+ *********************************************************************************************
+ * @ dst_xp   : extended pointer on the source process descriptor (in owner cluster).
+ * @ src_xp   : extended pointer on the destination process descriptor (in owner cluster).
+ ********************************************************************************************/
+void process_fd_replicate( xptr_t dst_xp,
+                           xptr_t src_xp );
 
 /*********************************************************************************************
@@ -598 +661 @@
 
 /*********************************************************************************************
- * This function attach a process, identified by the <process> argument to a TXT terminal,
+ * This function attach a process, identified by the <process_xp> argument to a TXT terminal,
  * identified by the <txt_id> channel index argument.
- * The process descriptor identified by the <process> argument must be in the owner cluster.  
- * It insert the process descriptor in the xlist rooted in the TXT_RX device.
+ * The process descriptor identified by the <process_xp> argument must be in the owner
+ * cluster. It insert the process descriptor in the xlist rooted in the TXT_RX device.
  * It is called by the process_reference_init() function.
  *********************************************************************************************
- * @ process  : local pointer on process descriptor.
- * @ txt_id   : TXT channel index.
- ********************************************************************************************/
-void process_txt_attach( process_t * process,
-                         uint32_t    txt_id );
+ * @ process_xp : extended pointer on process descriptor in owner cluster.
+ * @ txt_id     : TXT channel index.
+ ********************************************************************************************/
+void process_txt_attach( xptr_t    process_xp,
+                         uint32_t  txt_id );
 
 /*********************************************************************************************
@@ -617 +680 @@
  * cluster, but the calling thread can be running in any cluster. 
  *********************************************************************************************
- * @ process_xp  : extended pointer on process descriptor.
+ * @ process_xp  : extended pointer on process descriptor in owner cluster.
  ********************************************************************************************/
 void process_txt_detach( xptr_t  process_xp );                     
+
+/*********************************************************************************************
+ * This function returns the TXT terminal index allocated to a process identified by the
+ * <process_xp> argument. The process descriptor identified by the <process_xp> argument 
+ * must be in the owner cluster, but the calling thread can be running in any cluster. 
+ *********************************************************************************************
+ * @ process_xp  : extended pointer on process descriptor in owner cluster.
+ ********************************************************************************************/
+uint32_t process_txt_get_index( xptr_t process_xp );
 
 /*********************************************************************************************
@@ -625 +697 @@
  * ownership of its attached TXT_RX terminal (i.e. put the process in foreground).
  * It can be called by a thread running in any cluster, but the target process descriptor
- * must be the process owner.
+ * must be in the owner cluster.
  *********************************************************************************************
  * @ owner_xp  : extended pointer on process descriptor in owner cluster.
@@ -654 +726 @@
 
 /*********************************************************************************************
- * This function returns an extended ponter on the current TXT owner process, 
+ * This function returns an extended pointer on the current TXT owner process, 
  * for the TXT terminal identified by the <channel> index. 
  *********************************************************************************************

trunk/kernel/kern/rpc.c

@@ -102 +102 @@
 void __attribute__((noinline)) rpc_undefined( xptr_t xp __attribute__ ((unused)) )
 {
-        assert( false , "called in cluster %x", local_cxy );
+        assert( __FUNCTION__, false , "called in cluster %x", local_cxy );
 }
 
@@ -231 +231 @@
 
 // response must be available for a blocking RPC
-assert( (*rpc->rsp == 0) , "illegal response for RPC %s\n", rpc_str[rpc->index] );
+assert( __FUNCTION__, (*rpc->rsp == 0) , "illegal response for RPC %s\n", rpc_str[rpc->index] );
 
     }

trunk/kernel/kern/scheduler.c

@@ -85 +85 @@
 
 // check kernel threads list
-assert( (count < sched->k_threads_nr), "bad kernel threads list" );
+assert( __FUNCTION__, (count < sched->k_threads_nr), "bad kernel threads list" );
 
             // get next entry in kernel list
@@ -119 +119 @@
 
 // check user threads list
-assert( (count < sched->u_threads_nr), "bad user threads list" );
+assert( __FUNCTION__, (count < sched->u_threads_nr), "bad user threads list" );
 
             // get next entry in user list
@@ -196 +196 @@
 
 // check target thread blocked
-assert( (thread->blocked & THREAD_BLOCKED_GLOBAL) , "thread not blocked" );
+assert( __FUNCTION__, (thread->blocked & THREAD_BLOCKED_GLOBAL) , "thread not blocked" );
  
             // decrement response counter
@@ -210 +210 @@
 
 // check calling thread != target thread
-assert( (thread != CURRENT_THREAD) , "calling thread cannot delete itself" );
+assert( __FUNCTION__, (thread != CURRENT_THREAD) , "calling thread cannot delete itself" );
  
             // get thread process descriptor
@@ -287 +287 @@
 
 // check process descriptor is local kernel process
-assert( ( thread->process == &process_zero ) , "illegal process descriptor");
+assert( __FUNCTION__, ( thread->process == &process_zero ) , "illegal process descriptor");
 
             // get thread ltid
@@ -322 +322 @@
 
 // check th_nr value
-assert( (process_zero.th_nr > 0) , "kernel process th_nr cannot be 0" );
+assert( __FUNCTION__, (process_zero.th_nr > 0) , "kernel process th_nr cannot be 0" );
 
             // remove thread from process th_tbl[]
@@ -495 +495 @@
 // This assert should always be true, as this check has been
 // done before, by any function that can possibly deschedule...
-assert( (current->busylocks == 0),
+assert( __FUNCTION__, (current->busylocks == 0),
 "current thread hold %d busylocks\n", current->busylocks ); 
 
@@ -511 +511 @@
 
 // check next thread kernel_stack overflow
-assert( (next->signature == THREAD_SIGNATURE),
+assert( __FUNCTION__, (next->signature == THREAD_SIGNATURE),
 "kernel stack overflow for thread %x on core[%x,%d]", next, local_cxy, lid );
 
 // check next thread attached to same core as the current thread
-assert( (next->core == current->core),
+assert( __FUNCTION__, (next->core == current->core),
 "next_core_lid %d / current_core_lid %d", current->core->lid, next->core->lid );
    
 // check next thread not blocked when type != IDLE
-assert( ((next->blocked == 0) || (next->type == THREAD_IDLE)) ,
+assert( __FUNCTION__, ((next->blocked == 0) || (next->type == THREAD_IDLE)) ,
 "next thread %x (%s) is blocked on core[%x,%d]", 
 next->trdid , thread_type_str(next->type) , local_cxy , lid );

trunk/kernel/kern/thread.c

@@ -30 +30 @@
 #include <hal_remote.h>
 #include <hal_vmm.h>
+#include <hal_switch.h>
 #include <memcpy.h>
 #include <printk.h>
@@ -120 +121 @@
 
 // check type and trdid fields are initialized
-assert( (thread->type == type)   , "bad type argument" );
-assert( (thread->trdid == trdid) , "bad trdid argument" );
+assert( __FUNCTION__, (thread->type == type)   , "bad type argument" );
+assert( __FUNCTION__, (thread->trdid == trdid) , "bad trdid argument" );
 
 #if DEBUG_THREAD_INIT
@@ -160 +161 @@
     list_entry_init( &thread->sched_list );
 
+    // initialize the embedded alarm to unlink 
+    list_entry_init( &thread->alarm.list );
+
     // initialize waiting queue entries
     list_entry_init( &thread->wait_list );
@@ -220 +224 @@
     vseg_t       * us_vseg;      // user stack vseg
 
-assert( (attr != NULL) , "pthread attributes must be defined" );
+assert( __FUNCTION__, (attr != NULL) , "pthread attributes must be defined" );
 
 #if DEBUG_THREAD_USER_CREATE
@@ -370 +374 @@
         return -1;
     }
-    hal_cpu_context_init( thread );
+    hal_cpu_context_init( thread,
+                          false , 0 , 0 );   // not a main thread
 
     // allocate & initialize FPU context
@@ -662 +667 @@
 }  // end thread_user_fork()
 
-////////////////////////////////////////////////
-error_t thread_user_exec( void     * entry_func,
-                          uint32_t   argc,
-                          char    ** argv )
+/////////////////////////////////////
+void thread_user_exec( uint32_t argc,
+                       intptr_t argv )
 {
     thread_t  * thread  = CURRENT_THREAD;
@@ -673 +677 @@
 uint32_t cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_THREAD_USER_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] enter / entry %x / cycle %d\n",
-__FUNCTION__, process->pid, thread->trdid, entry_func , cycle );
+printk("\n[%s] thread[%x,%x] enter / cycle %d\n",
+__FUNCTION__, process->pid, thread->trdid, cycle );
 #endif
 
 // check parent thread attributes
-assert( (thread->type == THREAD_USER )          , "bad type" );
-assert( (thread->signature == THREAD_SIGNATURE) , "bad signature" );
-assert( (thread->busylocks == 0)                , "bad busylocks" );
+assert( __FUNCTION__, (thread->type      == THREAD_USER )     , "bad type" );
+assert( __FUNCTION__, (thread->signature == THREAD_SIGNATURE) , "bad signature" );
+assert( __FUNCTION__, (thread->busylocks == 0)                , "bad busylocks" );
 
         // re-initialize various thread descriptor fields
-    thread->quantum         = 0;            // TODO
-    thread->ticks_nr        = 0;            // TODO
-    thread->time_last_check = 0;            // TODO
-
-    thread->entry_func      = entry_func;
-    thread->main_argc       = argc; 
-    thread->main_argv       = argv;
-
-    // the main thread is always detached
-    thread->flags           = THREAD_FLAG_DETACHED;
+    thread->quantum         = 0;                               // TODO
+    thread->ticks_nr        = 0;                               // TODO
+    thread->time_last_check = 0;                               // TODO
+    thread->entry_func      = (void*)process->vmm.entry_point;
+    thread->flags           = THREAD_FLAG_DETACHED;            // main always detached
     thread->blocked         = 0;
     thread->errno           = 0;
-    thread->fork_user       = 0;    // not inherited
-    thread->fork_cxy        = 0;    // not inherited
-
-    // re-initialize busylocks counters
-    thread->busylocks       = 0;
+    thread->fork_user       = 0;
+    thread->fork_cxy        = 0;
 
     // reset thread info
@@ -707 +703 @@
     remote_busylock_init( XPTR( local_cxy , &thread->join_lock ), LOCK_THREAD_JOIN );
 
-    // allocate an user stack vseg for main thread
-    vseg_t * us_vseg = vmm_create_vseg( process,
-                                        VSEG_TYPE_STACK,
-                                        LTID_FROM_TRDID( thread->trdid ),
-                                        0,                 // length unused
-                                        0,                 // file_offset unused
-                                        0,                 // file_size unused
-                                        XPTR_NULL,         // mapper_xp unused
-                                        local_cxy );
-    if( us_vseg == NULL )
-    {
-            printk("\n[ERROR] in %s : cannot create stack vseg for main thread\n", __FUNCTION__ );
-                return -1;
-    }
-
-    // update user stack in thread descriptor
-    thread->user_stack_vseg = us_vseg;
-    
     // release FPU ownership if required
     if( thread->core->fpu_owner == thread ) thread->core->fpu_owner = NULL;
 
-    // re-initialize  FPU context
+    // initialize thread FPU context
     hal_fpu_context_init( thread );
+
+    // initialize thread CPU context 
+    hal_cpu_context_init( thread,
+                          true,          // main thread
+                          argc,
+                          argv );  
 
 #if DEBUG_THREAD_USER_EXEC
 cycle = (uint32_t)hal_get_cycles();
 if( DEBUG_THREAD_USER_EXEC < cycle )
-printk("\n[%s] thread[%x,%x] set CPU context & jump to user code / cycle %d\n",
-__FUNCTION__, process->pid, thread->trdid, cycle );
-hal_vmm_display( XPTR( local_cxy , process ) , true );
-#endif
-
-    // re-initialize CPU context... and jump to user code
-        hal_cpu_context_exec( thread );
-
-    assert( false, "we should not execute this code");
- 
-    return 0;
+{
+    printk("\n[%s] thread[%x,%x] set CPU context & jump to user code / cycle %d\n",
+    __FUNCTION__, process->pid, thread->trdid, cycle );
+
+    hal_cpu_context_display( XPTR( local_cxy , thread ) );
+    hal_vmm_display( XPTR( local_cxy , process ) , true );
+}
+#endif
+
+    // restore CPU registers ... and jump to user code
+    hal_do_cpu_restore( thread->cpu_context );
 
 }  // end thread_user_exec()
@@ -761 +745 @@
     thread_t * this = CURRENT_THREAD; 
 
-assert( ( (type == THREAD_IDLE) || (type == THREAD_RPC) || (type == THREAD_DEV) ) ,
+assert( __FUNCTION__, ( (type == THREAD_IDLE) || (type == THREAD_RPC) || (type == THREAD_DEV) ) ,
 "illegal thread type" );
 
-assert( (core_lid < LOCAL_CLUSTER->cores_nr) ,
+assert( __FUNCTION__, (core_lid < LOCAL_CLUSTER->cores_nr) ,
 "illegal core_lid" );
 
@@ -829 +813 @@
     }
 
-    hal_cpu_context_init( thread );
+    hal_cpu_context_init( thread,
+                          false , 0 , 0 );  // not a main thread
 
 #if DEBUG_THREAD_KERNEL_CREATE
@@ -854 +839 @@
 
 // check arguments
-assert( (type == THREAD_IDLE) , "illegal thread type" );
-assert( (core_lid < LOCAL_CLUSTER->cores_nr) , "illegal core index" );
+assert( __FUNCTION__, (type == THREAD_IDLE) , "illegal thread type" );
+assert( __FUNCTION__, (core_lid < LOCAL_CLUSTER->cores_nr) , "illegal core index" );
 
     // set type in thread descriptor
@@ -863 +848 @@
     error = process_register_thread( &process_zero , thread , &trdid );
 
-assert( (error == 0), "cannot register idle_thread in kernel process" );
+assert( __FUNCTION__, (error == 0), "cannot register idle_thread in kernel process" );
 
     // set trdid in thread descriptor
@@ -878 +863 @@
                          NULL );   // no user stack for a kernel thread
 
-assert( (error == 0), "cannot initialize idle_thread" );
-
-    // allocate & initialize CPU context if success
+assert( __FUNCTION__, (error == 0), "cannot initialize idle_thread" );
+
+    // allocate CPU context 
     error = hal_cpu_context_alloc( thread );
 
-assert( (error == 0), "cannot allocate CPU context" );
-
-    hal_cpu_context_init( thread );
+assert( __FUNCTION__, (error == 0), "cannot allocate CPU context" );
+
+    // initialize CPU context
+    hal_cpu_context_init( thread,
+                          false , 0 , 0 );   // not a main thread
 
 }  // end thread_idle_init()
@@ -949 +936 @@
 #endif
 
+    // unlink embedded alarm from the list rooted in core when required
+    list_entry_t * entry = &thread->alarm.list;
+    if( (entry->next != NULL) || (entry->pred != NULL) )  list_unlink( entry );
+
     // remove thread from process th_tbl[]
     count = process_remove_thread( thread );
@@ -1028 +1019 @@
 
     // check signal pending in scheduler
-    assert( sched->req_ack_pending , "no pending signal" );
+    assert( __FUNCTION__, sched->req_ack_pending , "no pending signal" );
     
     // enter critical section
@@ -1101 +1092 @@
 
 //////////////////////////////////////
-void thread_delete( xptr_t  target_xp,
+void thread_delete_request( xptr_t  target_xp,
                     bool_t  is_forced )
 {
@@ -1150 +1141 @@
 // check target thread is not the main thread, because the main thread
 // must be deleted by the parent process sys_wait() function
-assert( ((CXY_FROM_PID( target_pid ) != target_cxy) || (target_ltid != 0)),
+assert( __FUNCTION__, ((CXY_FROM_PID( target_pid ) != target_cxy) || (target_ltid != 0)),
 "target thread cannot be the main thread" );
 
@@ -1275 +1266 @@
 
     }
-}  // end thread_delete()
+}  // end thread_delete_request()
 
 

trunk/kernel/kern/thread.h

@@ -37 +37 @@
 #include <core.h>
 #include <chdev.h>
+#include <alarm.h>
 #include <cluster.h>
 #include <process.h>
@@ -95 +96 @@
 #define THREAD_BLOCKED_LOCK      0x1000  /*! ANY : wait queuelock or rwlock           */
 #define THREAD_BLOCKED_CLIENT    0x2000  /*! DEV : wait clients queue non empty       */
+#define THREAD_BLOCKED_ALARM     0x4000  /*! ANY : wait a timer based alarm           */
 
 /***************************************************************************************
@@ -160 +162 @@
         vseg_t            * user_stack_vseg; /*! local pointer on user stack vseg         */
 
-    void              * entry_func;      /*! pointer on entry function                */
-    void              * entry_args;      /*! pointer on entry function arguments      */
-    uint32_t            main_argc;       /*! main thread number of arguments          */
-    char             ** main_argv;       /*! main thread array of strings arguments   */
+    void              * entry_func;      /*! pointer on thread entry function         */
+    void              * entry_args;      /*! pthread     : pointer on arguments       */
 
     uint32_t            flags;           /*! bit vector of flags                      */
@@ -177 +177 @@
 
     chdev_t           * chdev;           /*! chdev pointer (for a DEV thread only)    */
+
+    alarm_t             alarm;           /*! embedded timer based alarm               */
 
     reg_t               save_sr;         /*! used by sched_yield() function           */
@@ -269 +271 @@
 /***************************************************************************************
  * This function is called by the process_make_exec() function to re-initialise the
- * calling thread descriptor, that will become the new process main thread.
- * It must be called by the main thread of the calling process.
+ * calling thread descriptor, that will become the new process main thread, from
+ * the process descriptor, and from the <args_nr> & <args_base> arguments.
  * - The calling thread TRDID is not modified.
  * - The kernel stack (currently in use) is not modified.  
- * - A new user stack vseg is created and initialised.
- * - The function calls the hal_cpu_context_exec() to re-initialize the CPU context
- *   and the uzone registered in kernel stack, an jump to user code.  
- ***************************************************************************************
- * @ entry_func : main thread entry point.
- * @ argc       : number of main thread arguments.
- * @ argv       : array of pointers on stringarguments.
- * @ returns 0 if success / returns ENOMEM if error.
- **************************************************************************************/
-error_t thread_user_exec( void     * entry_func,
-                          uint32_t   argc,
-                          char    ** argv);
+ * - It calls the hal_cpu_context_init() to re-initialize the thread CPU context.
+ * - It calls the hal_do_cpu_restore() to force execution of the new user code.
+ ***************************************************************************************
+ * @ argc   : actual number of main thread arguments.
+ * @ argv   : user space pointer on array of pointers on arguments.
+ **************************************************************************************/
+void thread_user_exec( uint32_t  argc,
+                       intptr_t  argv );
 
 /***************************************************************************************
@@ -397 +395 @@
  * @ is_forced   : the deletion does not depends on the attached mode. 
  **************************************************************************************/
-void thread_delete( xptr_t  thread_xp,
-                    bool_t  is_forced );
+void thread_delete_request( xptr_t  thread_xp,
+                            bool_t  is_forced );
 
 /***************************************************************************************