final/runtime/src/kmp_threadprivate.c - openmp - Git at Google

 /*
  * kmp_threadprivate.c -- OpenMP threadprivate support library
  */


 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.txt for details.
 //
 //===----------------------------------------------------------------------===//


 #include "kmp.h"
 #include "kmp_itt.h"
 #include "kmp_i18n.h"

 /* ------------------------------------------------------------------------ */
 /* ------------------------------------------------------------------------ */

 #define USE_CHECKS_COMMON

 #define KMP_INLINE_SUBR         1


 /* ------------------------------------------------------------------------ */
 /* ------------------------------------------------------------------------ */

 void
 kmp_threadprivate_insert_private_data( int gtid, void *pc_addr, void *data_addr, size_t pc_size );
 struct private_common *
 kmp_threadprivate_insert( int gtid, void *pc_addr, void *data_addr, size_t pc_size );

 struct shared_table     __kmp_threadprivate_d_table;

 /* ------------------------------------------------------------------------ */
 /* ------------------------------------------------------------------------ */

 static
 #ifdef KMP_INLINE_SUBR
 __forceinline
 #endif
 struct private_common *
 __kmp_threadprivate_find_task_common( struct common_table *tbl, int gtid, void *pc_addr )

 {
     struct private_common *tn;

 #ifdef KMP_TASK_COMMON_DEBUG
     KC_TRACE( 10, ( "__kmp_threadprivate_find_task_common: thread#%d, called with address %p\n",
                     gtid, pc_addr ) );
     dump_list();
 #endif

     for (tn = tbl->data[ KMP_HASH(pc_addr) ]; tn; tn = tn->next) {
         if (tn->gbl_addr == pc_addr) {
 #ifdef KMP_TASK_COMMON_DEBUG
             KC_TRACE( 10, ( "__kmp_threadprivate_find_task_common: thread#%d, found node %p on list\n",
                             gtid, pc_addr ) );
 #endif
             return tn;
         }
     }
     return 0;
 }

 static
 #ifdef KMP_INLINE_SUBR
 __forceinline
 #endif
 struct shared_common *
 __kmp_find_shared_task_common( struct shared_table *tbl, int gtid, void *pc_addr )
 {
     struct shared_common *tn;

     for (tn = tbl->data[ KMP_HASH(pc_addr) ]; tn; tn = tn->next) {
         if (tn->gbl_addr == pc_addr) {
 #ifdef KMP_TASK_COMMON_DEBUG
             KC_TRACE( 10, ( "__kmp_find_shared_task_common: thread#%d, found node %p on list\n",
                             gtid, pc_addr ) );
 #endif
             return tn;
         }
     }
     return 0;
 }


 /*
  *      Create a template for the data initialized storage.
  *      Either the template is NULL indicating zero fill,
  *      or the template is a copy of the original data.
  */

 static struct private_data *
 __kmp_init_common_data( void *pc_addr, size_t pc_size )
 {
     struct private_data *d;
     size_t       i;
     char        *p;

     d = (struct private_data *) __kmp_allocate( sizeof( struct private_data ) );
 /*
     d->data = 0;  // AC: commented out because __kmp_allocate zeroes the memory
     d->next = 0;
 */
     d->size = pc_size;
     d->more = 1;

     p = (char*)pc_addr;

     for (i = pc_size;  i > 0; --i) {
         if (*p++ != '\0') {
             d->data = __kmp_allocate( pc_size );
             KMP_MEMCPY( d->data, pc_addr, pc_size );
             break;
         }
     }

     return d;
 }

 /*
  *      Initialize the data area from the template.
  */

 static void
 __kmp_copy_common_data( void *pc_addr, struct private_data *d )
 {
     char *addr = (char *) pc_addr;
     int   i, offset;

     for (offset = 0; d != 0; d = d->next) {
         for (i = d->more; i > 0; --i) {
             if (d->data == 0)
                 memset( & addr[ offset ], '\0', d->size );
             else
                 KMP_MEMCPY( & addr[ offset ], d->data, d->size );
             offset += d->size;
         }
     }
 }

 /* ------------------------------------------------------------------------ */
 /* ------------------------------------------------------------------------ */

 /* we are called from __kmp_serial_initialize() with __kmp_initz_lock held. */
 void
 __kmp_common_initialize( void )
 {
     if( ! TCR_4(__kmp_init_common) ) {
         int q;
 #ifdef KMP_DEBUG
         int gtid;
 #endif

         __kmp_threadpriv_cache_list = NULL;

 #ifdef KMP_DEBUG
         /* verify the uber masters were initialized */
         for(gtid = 0 ; gtid < __kmp_threads_capacity; gtid++ )
             if( __kmp_root[gtid] ) {
                 KMP_DEBUG_ASSERT( __kmp_root[gtid]->r.r_uber_thread );
                 for ( q = 0; q< KMP_HASH_TABLE_SIZE; ++q)
                     KMP_DEBUG_ASSERT( !__kmp_root[gtid]->r.r_uber_thread->th.th_pri_common->data[q] );
 /*                    __kmp_root[ gitd ]-> r.r_uber_thread -> th.th_pri_common -> data[ q ] = 0;*/
             }
 #endif /* KMP_DEBUG */

         for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q)
             __kmp_threadprivate_d_table.data[ q ] = 0;

         TCW_4(__kmp_init_common, TRUE);
     }
 }

 /* Call all destructors for threadprivate data belonging to all threads.
    Currently unused! */
 void
 __kmp_common_destroy( void )
 {
     if( TCR_4(__kmp_init_common) ) {
         int q;

         TCW_4(__kmp_init_common, FALSE);

         for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q) {
             int gtid;
             struct private_common *tn;
             struct shared_common  *d_tn;

             /*  C++ destructors need to be called once per thread before exiting  */
             /*  don't call destructors for master thread though unless we used copy constructor */

             for (d_tn = __kmp_threadprivate_d_table.data[ q ]; d_tn; d_tn = d_tn->next) {
                 if (d_tn->is_vec) {
                     if (d_tn->dt.dtorv != 0) {
                         for (gtid = 0; gtid < __kmp_all_nth; ++gtid) {
                             if( __kmp_threads[gtid] ) {
                                 if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
                                                          (! KMP_UBER_GTID (gtid)) ) {
                                     tn = __kmp_threadprivate_find_task_common( __kmp_threads[ gtid ]->th.th_pri_common,
                                                                                gtid, d_tn->gbl_addr );
                                     if (tn) {
                                         (*d_tn->dt.dtorv) (tn->par_addr, d_tn->vec_len);
                                     }
                                 }
                             }
                         }
                         if (d_tn->obj_init != 0) {
                             (*d_tn->dt.dtorv) (d_tn->obj_init, d_tn->vec_len);
                         }
                     }
                 } else {
                     if (d_tn->dt.dtor != 0) {
                         for (gtid = 0; gtid < __kmp_all_nth; ++gtid) {
                             if( __kmp_threads[gtid] ) {
                                 if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
                                                          (! KMP_UBER_GTID (gtid)) ) {
                                     tn = __kmp_threadprivate_find_task_common( __kmp_threads[ gtid ]->th.th_pri_common,
                                                                                gtid, d_tn->gbl_addr );
                                     if (tn) {
                                         (*d_tn->dt.dtor) (tn->par_addr);
                                     }
                                 }
                             }
                         }
                         if (d_tn->obj_init != 0) {
                             (*d_tn->dt.dtor) (d_tn->obj_init);
                         }
                     }
                 }
             }
             __kmp_threadprivate_d_table.data[ q ] = 0;
         }
     }
 }

 /* Call all destructors for threadprivate data belonging to this thread */
 void
 __kmp_common_destroy_gtid( int gtid )
 {
     struct private_common *tn;
     struct shared_common *d_tn;

     KC_TRACE( 10, ("__kmp_common_destroy_gtid: T#%d called\n", gtid ) );
     if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
                              (! KMP_UBER_GTID (gtid)) ) {

         if( TCR_4(__kmp_init_common) ) {

             /* Cannot do this here since not all threads have destroyed their data */
             /* TCW_4(__kmp_init_common, FALSE); */

             for (tn = __kmp_threads[ gtid ]->th.th_pri_head; tn; tn = tn->link) {

                 d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
                                                       gtid, tn->gbl_addr );

                 KMP_DEBUG_ASSERT( d_tn );

                 if (d_tn->is_vec) {
                     if (d_tn->dt.dtorv != 0) {
                         (void) (*d_tn->dt.dtorv) (tn->par_addr, d_tn->vec_len);
                     }
                     if (d_tn->obj_init != 0) {
                         (void) (*d_tn->dt.dtorv) (d_tn->obj_init, d_tn->vec_len);
                     }
                 } else {
                     if (d_tn->dt.dtor != 0) {
                         (void) (*d_tn->dt.dtor) (tn->par_addr);
                     }
                     if (d_tn->obj_init != 0) {
                         (void) (*d_tn->dt.dtor) (d_tn->obj_init);
                     }
                 }
             }
             KC_TRACE( 30, ("__kmp_common_destroy_gtid: T#%d threadprivate destructors complete\n",
                            gtid ) );
         }
     }
 }

 /* ------------------------------------------------------------------------ */
 /* ------------------------------------------------------------------------ */

 #ifdef KMP_TASK_COMMON_DEBUG
 static void
 dump_list( void )
 {
     int p, q;

     for (p = 0; p < __kmp_all_nth; ++p) {
         if( !__kmp_threads[p] ) continue;
         for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q) {
             if (__kmp_threads[ p ]->th.th_pri_common->data[ q ]) {
                 struct private_common *tn;

                 KC_TRACE( 10, ( "\tdump_list: gtid:%d addresses\n", p ) );

                 for (tn = __kmp_threads[ p ]->th.th_pri_common->data[ q ]; tn; tn = tn->next)                 {
                     KC_TRACE( 10, ( "\tdump_list: THREADPRIVATE: Serial %p -> Parallel %p\n",
                                     tn->gbl_addr, tn->par_addr ) );
                 }
             }
         }
     }
 }
 #endif /* KMP_TASK_COMMON_DEBUG */


 /*
  * NOTE: this routine is to be called only from the serial part of the program.
  */

 void
 kmp_threadprivate_insert_private_data( int gtid, void *pc_addr, void *data_addr, size_t pc_size )
 {
     struct shared_common **lnk_tn, *d_tn;
     KMP_DEBUG_ASSERT( __kmp_threads[ gtid ] &&
             __kmp_threads[ gtid ] -> th.th_root -> r.r_active == 0 );

     d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
                                           gtid, pc_addr );

     if (d_tn == 0) {
         d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );

         d_tn->gbl_addr = pc_addr;
         d_tn->pod_init = __kmp_init_common_data( data_addr, pc_size );
 /*
         d_tn->obj_init = 0;  // AC: commented out because __kmp_allocate zeroes the memory
         d_tn->ct.ctor = 0;
         d_tn->cct.cctor = 0;;
         d_tn->dt.dtor = 0;
         d_tn->is_vec = FALSE;
         d_tn->vec_len = 0L;
 */
         d_tn->cmn_size = pc_size;

         __kmp_acquire_lock( &__kmp_global_lock, gtid );

         lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(pc_addr) ]);

         d_tn->next = *lnk_tn;
         *lnk_tn = d_tn;

         __kmp_release_lock( &__kmp_global_lock, gtid );
     }
 }

 struct private_common *
 kmp_threadprivate_insert( int gtid, void *pc_addr, void *data_addr, size_t pc_size )
 {
     struct private_common *tn, **tt;
     struct shared_common  *d_tn;

     /* +++++++++ START OF CRITICAL SECTION +++++++++ */

     __kmp_acquire_lock( & __kmp_global_lock, gtid );

     tn = (struct private_common *) __kmp_allocate( sizeof (struct private_common) );

     tn->gbl_addr = pc_addr;

     d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
                                           gtid, pc_addr );     /* Only the MASTER data table exists. */

     if (d_tn != 0) {
         /* This threadprivate variable has already been seen. */

         if ( d_tn->pod_init == 0 && d_tn->obj_init == 0 ) {
             d_tn->cmn_size = pc_size;

             if (d_tn->is_vec) {
                 if (d_tn->ct.ctorv != 0) {
                     /* Construct from scratch so no prototype exists */
                     d_tn->obj_init = 0;
                 }
                 else if (d_tn->cct.cctorv != 0) {
                     /* Now data initialize the prototype since it was previously registered */
                     d_tn->obj_init = (void *) __kmp_allocate( d_tn->cmn_size );
                     (void) (*d_tn->cct.cctorv) (d_tn->obj_init, pc_addr, d_tn->vec_len);
                 }
                 else {
                     d_tn->pod_init = __kmp_init_common_data( data_addr, d_tn->cmn_size );
                 }
             } else {
                 if (d_tn->ct.ctor != 0) {
                     /* Construct from scratch so no prototype exists */
                     d_tn->obj_init = 0;
                 }
                 else if (d_tn->cct.cctor != 0) {
                     /* Now data initialize the prototype since it was previously registered */
                     d_tn->obj_init = (void *) __kmp_allocate( d_tn->cmn_size );
                     (void) (*d_tn->cct.cctor) (d_tn->obj_init, pc_addr);
                 }
                 else {
                     d_tn->pod_init = __kmp_init_common_data( data_addr, d_tn->cmn_size );
                 }
             }
         }
     }
     else {
         struct shared_common **lnk_tn;

         d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
         d_tn->gbl_addr = pc_addr;
         d_tn->cmn_size = pc_size;
         d_tn->pod_init = __kmp_init_common_data( data_addr, pc_size );
 /*
         d_tn->obj_init = 0;  // AC: commented out because __kmp_allocate zeroes the memory
         d_tn->ct.ctor = 0;
         d_tn->cct.cctor = 0;
         d_tn->dt.dtor = 0;
         d_tn->is_vec = FALSE;
         d_tn->vec_len = 0L;
 */
         lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(pc_addr) ]);

         d_tn->next = *lnk_tn;
         *lnk_tn = d_tn;
     }

     tn->cmn_size = d_tn->cmn_size;

     if ( (__kmp_foreign_tp) ? (KMP_INITIAL_GTID (gtid)) : (KMP_UBER_GTID (gtid)) ) {
         tn->par_addr = (void *) pc_addr;
     }
     else {
         tn->par_addr = (void *) __kmp_allocate( tn->cmn_size );
     }

     __kmp_release_lock( & __kmp_global_lock, gtid );

     /* +++++++++ END OF CRITICAL SECTION +++++++++ */

 #ifdef USE_CHECKS_COMMON
         if (pc_size > d_tn->cmn_size) {
             KC_TRACE( 10, ( "__kmp_threadprivate_insert: THREADPRIVATE: %p (%"
                             KMP_UINTPTR_SPEC " ,%" KMP_UINTPTR_SPEC ")\n",
                             pc_addr, pc_size, d_tn->cmn_size ) );
             KMP_FATAL( TPCommonBlocksInconsist );
         }
 #endif /* USE_CHECKS_COMMON */

     tt = &(__kmp_threads[ gtid ]->th.th_pri_common->data[ KMP_HASH(pc_addr) ]);

 #ifdef KMP_TASK_COMMON_DEBUG
     if (*tt != 0) {
         KC_TRACE( 10, ( "__kmp_threadprivate_insert: WARNING! thread#%d: collision on %p\n",
                         gtid, pc_addr ) );
     }
 #endif
     tn->next = *tt;
     *tt = tn;

 #ifdef KMP_TASK_COMMON_DEBUG
     KC_TRACE( 10, ( "__kmp_threadprivate_insert: thread#%d, inserted node %p on list\n",
                     gtid, pc_addr ) );
     dump_list( );
 #endif

     /* Link the node into a simple list */

     tn->link = __kmp_threads[ gtid ]->th.th_pri_head;
     __kmp_threads[ gtid ]->th.th_pri_head = tn;

 #ifdef BUILD_TV
     __kmp_tv_threadprivate_store( __kmp_threads[ gtid ], tn->gbl_addr, tn->par_addr );
 #endif

     if( (__kmp_foreign_tp) ? (KMP_INITIAL_GTID (gtid)) : (KMP_UBER_GTID (gtid)) )
         return tn;

     /*
      * if C++ object with copy constructor, use it;
      * else if C++ object with constructor, use it for the non-master copies only;
      * else use pod_init and memcpy
      *
      * C++ constructors need to be called once for each non-master thread on allocate
      * C++ copy constructors need to be called once for each thread on allocate
      */

     /*
      * C++ object with constructors/destructors;
      * don't call constructors for master thread though
      */
     if (d_tn->is_vec) {
         if ( d_tn->ct.ctorv != 0) {
             (void) (*d_tn->ct.ctorv) (tn->par_addr, d_tn->vec_len);
         } else if (d_tn->cct.cctorv != 0) {
             (void) (*d_tn->cct.cctorv) (tn->par_addr, d_tn->obj_init, d_tn->vec_len);
         } else if (tn->par_addr != tn->gbl_addr) {
             __kmp_copy_common_data( tn->par_addr, d_tn->pod_init );
         }
     } else {
         if ( d_tn->ct.ctor != 0 ) {
             (void) (*d_tn->ct.ctor) (tn->par_addr);
         } else if (d_tn->cct.cctor != 0) {
             (void) (*d_tn->cct.cctor) (tn->par_addr, d_tn->obj_init);
         } else if (tn->par_addr != tn->gbl_addr) {
             __kmp_copy_common_data( tn->par_addr, d_tn->pod_init );
         }
     }
 /* !BUILD_OPENMP_C
     if (tn->par_addr != tn->gbl_addr)
         __kmp_copy_common_data( tn->par_addr, d_tn->pod_init ); */

     return tn;
 }

 /* ------------------------------------------------------------------------ */
 /* We are currently parallel, and we know the thread id.                    */
 /* ------------------------------------------------------------------------ */

 /*!
  @ingroup THREADPRIVATE

  @param loc source location information
  @param data  pointer to data being privatized
  @param ctor  pointer to constructor function for data
  @param cctor  pointer to copy constructor function for data
  @param dtor  pointer to destructor function for data

  Register constructors and destructors for thread private data.
  This function is called when executing in parallel, when we know the thread id.
 */
 void
 __kmpc_threadprivate_register(ident_t *loc, void *data, kmpc_ctor ctor, kmpc_cctor cctor, kmpc_dtor dtor)
 {
     struct shared_common *d_tn, **lnk_tn;

     KC_TRACE( 10, ("__kmpc_threadprivate_register: called\n" ) );

 #ifdef USE_CHECKS_COMMON
     /* copy constructor must be zero for current code gen (Nov 2002 - jph) */
     KMP_ASSERT( cctor == 0);
 #endif /* USE_CHECKS_COMMON */

     /* Only the global data table exists. */
     d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table, -1, data );

     if (d_tn == 0) {
         d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
         d_tn->gbl_addr = data;

         d_tn->ct.ctor = ctor;
         d_tn->cct.cctor = cctor;
         d_tn->dt.dtor = dtor;
 /*
         d_tn->is_vec = FALSE;  // AC: commented out because __kmp_allocate zeroes the memory
         d_tn->vec_len = 0L;
         d_tn->obj_init = 0;
         d_tn->pod_init = 0;
 */
         lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(data) ]);

         d_tn->next = *lnk_tn;
         *lnk_tn = d_tn;
     }
 }

 void *
 __kmpc_threadprivate(ident_t *loc, kmp_int32 global_tid, void *data, size_t size)
 {
     void *ret;
     struct private_common *tn;

     KC_TRACE( 10, ("__kmpc_threadprivate: T#%d called\n", global_tid ) );

 #ifdef USE_CHECKS_COMMON
     if (! __kmp_init_serial)
         KMP_FATAL( RTLNotInitialized );
 #endif /* USE_CHECKS_COMMON */

     if ( ! __kmp_threads[global_tid] -> th.th_root -> r.r_active && ! __kmp_foreign_tp ) {
         /* The parallel address will NEVER overlap with the data_address */
         /* dkp: 3rd arg to kmp_threadprivate_insert_private_data() is the data_address; use data_address = data */

         KC_TRACE( 20, ("__kmpc_threadprivate: T#%d inserting private data\n", global_tid ) );
         kmp_threadprivate_insert_private_data( global_tid, data, data, size );

         ret = data;
     }
     else {
         KC_TRACE( 50, ("__kmpc_threadprivate: T#%d try to find private data at address %p\n",
                        global_tid, data ) );
         tn = __kmp_threadprivate_find_task_common( __kmp_threads[ global_tid ]->th.th_pri_common, global_tid, data );

         if ( tn ) {
             KC_TRACE( 20, ("__kmpc_threadprivate: T#%d found data\n", global_tid ) );
 #ifdef USE_CHECKS_COMMON
             if ((size_t) size > tn->cmn_size) {
                 KC_TRACE( 10, ( "THREADPRIVATE: %p (%" KMP_UINTPTR_SPEC " ,%" KMP_UINTPTR_SPEC ")\n",
                                 data, size, tn->cmn_size ) );
                 KMP_FATAL( TPCommonBlocksInconsist );
             }
 #endif /* USE_CHECKS_COMMON */
         }
         else {
             /* The parallel address will NEVER overlap with the data_address */
             /* dkp: 3rd arg to kmp_threadprivate_insert() is the data_address; use data_address = data */
             KC_TRACE( 20, ("__kmpc_threadprivate: T#%d inserting data\n", global_tid ) );
             tn = kmp_threadprivate_insert( global_tid, data, data, size );
         }

         ret = tn->par_addr;
     }
     KC_TRACE( 10, ("__kmpc_threadprivate: T#%d exiting; return value = %p\n",
                    global_tid, ret ) );

     return ret;
 }

 /*!
  @ingroup THREADPRIVATE
  @param loc source location information
  @param global_tid  global thread number
  @param data  pointer to data to privatize
  @param size  size of data to privatize
  @param cache  pointer to cache
  @return pointer to private storage

  Allocate private storage for threadprivate data.
 */
 void *
 __kmpc_threadprivate_cached(
     ident_t *  loc,
     kmp_int32  global_tid,   // gtid.
     void *     data,         // Pointer to original global variable.
     size_t     size,         // Size of original global variable.
     void ***   cache
 ) {
     KC_TRACE( 10, ("__kmpc_threadprivate_cached: T#%d called with cache: %p, address: %p, size: %"
                    KMP_SIZE_T_SPEC "\n",
                    global_tid, *cache, data, size ) );

     if ( TCR_PTR(*cache) == 0) {
         __kmp_acquire_lock( & __kmp_global_lock, global_tid );

         if ( TCR_PTR(*cache) == 0) {
             __kmp_acquire_bootstrap_lock(&__kmp_tp_cached_lock);
             __kmp_tp_cached = 1;
             __kmp_release_bootstrap_lock(&__kmp_tp_cached_lock);
             void ** my_cache;
             KMP_ITT_IGNORE(
             my_cache = (void**)
                 __kmp_allocate(sizeof( void * ) * __kmp_tp_capacity + sizeof ( kmp_cached_addr_t ));
                            );
             // No need to zero the allocated memory; __kmp_allocate does that.
             KC_TRACE( 50, ("__kmpc_threadprivate_cached: T#%d allocated cache at address %p\n",
                            global_tid, my_cache ) );

             /* TODO: free all this memory in __kmp_common_destroy using __kmp_threadpriv_cache_list */
             /* Add address of mycache to linked list for cleanup later  */
             kmp_cached_addr_t *tp_cache_addr;

             tp_cache_addr = (kmp_cached_addr_t *) & my_cache[__kmp_tp_capacity];
             tp_cache_addr -> addr = my_cache;
             tp_cache_addr -> next = __kmp_threadpriv_cache_list;
             __kmp_threadpriv_cache_list = tp_cache_addr;

             KMP_MB();

             TCW_PTR( *cache, my_cache);

             KMP_MB();
         }

         __kmp_release_lock( & __kmp_global_lock, global_tid );
     }

     void *ret;
     if ((ret = TCR_PTR((*cache)[ global_tid ])) == 0) {
         ret = __kmpc_threadprivate( loc, global_tid, data, (size_t) size);

         TCW_PTR( (*cache)[ global_tid ], ret);
     }
     KC_TRACE( 10, ("__kmpc_threadprivate_cached: T#%d exiting; return value = %p\n",
                    global_tid, ret ) );

     return ret;
 }

 /*!
  @ingroup THREADPRIVATE
  @param loc source location information
  @param data  pointer to data being privatized
  @param ctor  pointer to constructor function for data
  @param cctor  pointer to copy constructor function for data
  @param dtor  pointer to destructor function for data
  @param vector_length length of the vector (bytes or elements?)
  Register vector constructors and destructors for thread private data.
 */
 void
 __kmpc_threadprivate_register_vec( ident_t *loc, void *data, kmpc_ctor_vec ctor,
                                    kmpc_cctor_vec cctor, kmpc_dtor_vec dtor,
                                    size_t vector_length )
 {
     struct shared_common *d_tn, **lnk_tn;

     KC_TRACE( 10, ("__kmpc_threadprivate_register_vec: called\n" ) );

 #ifdef USE_CHECKS_COMMON
     /* copy constructor must be zero for current code gen (Nov 2002 - jph) */
     KMP_ASSERT( cctor == 0);
 #endif /* USE_CHECKS_COMMON */

     d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
                                           -1, data );        /* Only the global data table exists. */

     if (d_tn == 0) {
         d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
         d_tn->gbl_addr = data;

         d_tn->ct.ctorv = ctor;
         d_tn->cct.cctorv = cctor;
         d_tn->dt.dtorv = dtor;
         d_tn->is_vec = TRUE;
         d_tn->vec_len = (size_t) vector_length;
 /*
         d_tn->obj_init = 0;  // AC: commented out because __kmp_allocate zeroes the memory
         d_tn->pod_init = 0;
 */
         lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(data) ]);

         d_tn->next = *lnk_tn;
         *lnk_tn = d_tn;
     }
 }
	/*
	* kmp_threadprivate.c -- OpenMP threadprivate support library
	*/


	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.txt for details.
	//
	//===----------------------------------------------------------------------===//


	#include "kmp.h"
	#include "kmp_itt.h"
	#include "kmp_i18n.h"

	/* ------------------------------------------------------------------------ */
	/* ------------------------------------------------------------------------ */

	#define USE_CHECKS_COMMON

	#define KMP_INLINE_SUBR 1


	/* ------------------------------------------------------------------------ */
	/* ------------------------------------------------------------------------ */

	void
	kmp_threadprivate_insert_private_data( int gtid, void pc_addr, void data_addr, size_t pc_size );
	struct private_common *
	kmp_threadprivate_insert( int gtid, void pc_addr, void data_addr, size_t pc_size );

	struct shared_table __kmp_threadprivate_d_table;

	/* ------------------------------------------------------------------------ */
	/* ------------------------------------------------------------------------ */

	static
	#ifdef KMP_INLINE_SUBR
	__forceinline
	#endif
	struct private_common *
	__kmp_threadprivate_find_task_common( struct common_table tbl, int gtid, void pc_addr )

	{
	struct private_common *tn;

	#ifdef KMP_TASK_COMMON_DEBUG
	KC_TRACE( 10, ( "__kmp_threadprivate_find_task_common: thread#%d, called with address %p\n",
	gtid, pc_addr ) );
	dump_list();
	#endif

	for (tn = tbl->data[ KMP_HASH(pc_addr) ]; tn; tn = tn->next) {
	if (tn->gbl_addr == pc_addr) {
	#ifdef KMP_TASK_COMMON_DEBUG
	KC_TRACE( 10, ( "__kmp_threadprivate_find_task_common: thread#%d, found node %p on list\n",
	gtid, pc_addr ) );
	#endif
	return tn;
	}
	}
	return 0;
	}

	static
	#ifdef KMP_INLINE_SUBR
	__forceinline
	#endif
	struct shared_common *
	__kmp_find_shared_task_common( struct shared_table tbl, int gtid, void pc_addr )
	{
	struct shared_common *tn;

	for (tn = tbl->data[ KMP_HASH(pc_addr) ]; tn; tn = tn->next) {
	if (tn->gbl_addr == pc_addr) {
	#ifdef KMP_TASK_COMMON_DEBUG
	KC_TRACE( 10, ( "__kmp_find_shared_task_common: thread#%d, found node %p on list\n",
	gtid, pc_addr ) );
	#endif
	return tn;
	}
	}
	return 0;
	}


	/*
	* Create a template for the data initialized storage.
	* Either the template is NULL indicating zero fill,
	* or the template is a copy of the original data.
	*/

	static struct private_data *
	__kmp_init_common_data( void *pc_addr, size_t pc_size )
	{
	struct private_data *d;
	size_t i;
	char *p;

	d = (struct private_data *) __kmp_allocate( sizeof( struct private_data ) );
	/*
	d->data = 0; // AC: commented out because __kmp_allocate zeroes the memory
	d->next = 0;
	*/
	d->size = pc_size;
	d->more = 1;

	p = (char*)pc_addr;

	for (i = pc_size; i > 0; --i) {
	if (*p++ != '\0') {
	d->data = __kmp_allocate( pc_size );
	KMP_MEMCPY( d->data, pc_addr, pc_size );
	break;
	}
	}

	return d;
	}

	/*
	* Initialize the data area from the template.
	*/

	static void
	__kmp_copy_common_data( void pc_addr, struct private_data d )
	{
	char addr = (char ) pc_addr;
	int i, offset;

	for (offset = 0; d != 0; d = d->next) {
	for (i = d->more; i > 0; --i) {
	if (d->data == 0)
	memset( & addr[ offset ], '\0', d->size );
	else
	KMP_MEMCPY( & addr[ offset ], d->data, d->size );
	offset += d->size;
	}
	}
	}

	/* ------------------------------------------------------------------------ */
	/* ------------------------------------------------------------------------ */

	/* we are called from __kmp_serial_initialize() with __kmp_initz_lock held. */
	void
	__kmp_common_initialize( void )
	{
	if( ! TCR_4(__kmp_init_common) ) {
	int q;
	#ifdef KMP_DEBUG
	int gtid;
	#endif

	__kmp_threadpriv_cache_list = NULL;

	#ifdef KMP_DEBUG
	/* verify the uber masters were initialized */
	for(gtid = 0 ; gtid < __kmp_threads_capacity; gtid++ )
	if( __kmp_root[gtid] ) {
	KMP_DEBUG_ASSERT( __kmp_root[gtid]->r.r_uber_thread );
	for ( q = 0; q< KMP_HASH_TABLE_SIZE; ++q)
	KMP_DEBUG_ASSERT( !__kmp_root[gtid]->r.r_uber_thread->th.th_pri_common->data[q] );
	/* __kmp_root[ gitd ]-> r.r_uber_thread -> th.th_pri_common -> data[ q ] = 0;*/
	}
	#endif /* KMP_DEBUG */

	for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q)
	__kmp_threadprivate_d_table.data[ q ] = 0;

	TCW_4(__kmp_init_common, TRUE);
	}
	}

	/* Call all destructors for threadprivate data belonging to all threads.
	Currently unused! */
	void
	__kmp_common_destroy( void )
	{
	if( TCR_4(__kmp_init_common) ) {
	int q;

	TCW_4(__kmp_init_common, FALSE);

	for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q) {
	int gtid;
	struct private_common *tn;
	struct shared_common *d_tn;

	/* C++ destructors need to be called once per thread before exiting */
	/* don't call destructors for master thread though unless we used copy constructor */

	for (d_tn = __kmp_threadprivate_d_table.data[ q ]; d_tn; d_tn = d_tn->next) {
	if (d_tn->is_vec) {
	if (d_tn->dt.dtorv != 0) {
	for (gtid = 0; gtid < __kmp_all_nth; ++gtid) {
	if( __kmp_threads[gtid] ) {
	if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
	(! KMP_UBER_GTID (gtid)) ) {
	tn = __kmp_threadprivate_find_task_common( __kmp_threads[ gtid ]->th.th_pri_common,
	gtid, d_tn->gbl_addr );
	if (tn) {
	(*d_tn->dt.dtorv) (tn->par_addr, d_tn->vec_len);
	}
	}
	}
	}
	if (d_tn->obj_init != 0) {
	(*d_tn->dt.dtorv) (d_tn->obj_init, d_tn->vec_len);
	}
	}
	} else {
	if (d_tn->dt.dtor != 0) {
	for (gtid = 0; gtid < __kmp_all_nth; ++gtid) {
	if( __kmp_threads[gtid] ) {
	if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
	(! KMP_UBER_GTID (gtid)) ) {
	tn = __kmp_threadprivate_find_task_common( __kmp_threads[ gtid ]->th.th_pri_common,
	gtid, d_tn->gbl_addr );
	if (tn) {
	(*d_tn->dt.dtor) (tn->par_addr);
	}
	}
	}
	}
	if (d_tn->obj_init != 0) {
	(*d_tn->dt.dtor) (d_tn->obj_init);
	}
	}
	}
	}
	__kmp_threadprivate_d_table.data[ q ] = 0;
	}
	}
	}

	/* Call all destructors for threadprivate data belonging to this thread */
	void
	__kmp_common_destroy_gtid( int gtid )
	{
	struct private_common *tn;
	struct shared_common *d_tn;

	KC_TRACE( 10, ("__kmp_common_destroy_gtid: T#%d called\n", gtid ) );
	if( (__kmp_foreign_tp) ? (! KMP_INITIAL_GTID (gtid)) :
	(! KMP_UBER_GTID (gtid)) ) {

	if( TCR_4(__kmp_init_common) ) {

	/* Cannot do this here since not all threads have destroyed their data */
	/* TCW_4(__kmp_init_common, FALSE); */

	for (tn = __kmp_threads[ gtid ]->th.th_pri_head; tn; tn = tn->link) {

	d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
	gtid, tn->gbl_addr );

	KMP_DEBUG_ASSERT( d_tn );

	if (d_tn->is_vec) {
	if (d_tn->dt.dtorv != 0) {
	(void) (*d_tn->dt.dtorv) (tn->par_addr, d_tn->vec_len);
	}
	if (d_tn->obj_init != 0) {
	(void) (*d_tn->dt.dtorv) (d_tn->obj_init, d_tn->vec_len);
	}
	} else {
	if (d_tn->dt.dtor != 0) {
	(void) (*d_tn->dt.dtor) (tn->par_addr);
	}
	if (d_tn->obj_init != 0) {
	(void) (*d_tn->dt.dtor) (d_tn->obj_init);
	}
	}
	}
	KC_TRACE( 30, ("__kmp_common_destroy_gtid: T#%d threadprivate destructors complete\n",
	gtid ) );
	}
	}
	}

	/* ------------------------------------------------------------------------ */
	/* ------------------------------------------------------------------------ */

	#ifdef KMP_TASK_COMMON_DEBUG
	static void
	dump_list( void )
	{
	int p, q;

	for (p = 0; p < __kmp_all_nth; ++p) {
	if( !__kmp_threads[p] ) continue;
	for (q = 0; q < KMP_HASH_TABLE_SIZE; ++q) {
	if (__kmp_threads[ p ]->th.th_pri_common->data[ q ]) {
	struct private_common *tn;

	KC_TRACE( 10, ( "\tdump_list: gtid:%d addresses\n", p ) );

	for (tn = __kmp_threads[ p ]->th.th_pri_common->data[ q ]; tn; tn = tn->next) {
	KC_TRACE( 10, ( "\tdump_list: THREADPRIVATE: Serial %p -> Parallel %p\n",
	tn->gbl_addr, tn->par_addr ) );
	}
	}
	}
	}
	}
	#endif /* KMP_TASK_COMMON_DEBUG */


	/*
	* NOTE: this routine is to be called only from the serial part of the program.
	*/

	void
	kmp_threadprivate_insert_private_data( int gtid, void pc_addr, void data_addr, size_t pc_size )
	{
	struct shared_common *lnk_tn, d_tn;
	KMP_DEBUG_ASSERT( __kmp_threads[ gtid ] &&
	__kmp_threads[ gtid ] -> th.th_root -> r.r_active == 0 );

	d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
	gtid, pc_addr );

	if (d_tn == 0) {
	d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );

	d_tn->gbl_addr = pc_addr;
	d_tn->pod_init = __kmp_init_common_data( data_addr, pc_size );
	/*
	d_tn->obj_init = 0; // AC: commented out because __kmp_allocate zeroes the memory
	d_tn->ct.ctor = 0;
	d_tn->cct.cctor = 0;;
	d_tn->dt.dtor = 0;
	d_tn->is_vec = FALSE;
	d_tn->vec_len = 0L;
	*/
	d_tn->cmn_size = pc_size;

	__kmp_acquire_lock( &__kmp_global_lock, gtid );

	lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(pc_addr) ]);

	d_tn->next = *lnk_tn;
	*lnk_tn = d_tn;

	__kmp_release_lock( &__kmp_global_lock, gtid );
	}
	}

	struct private_common *
	kmp_threadprivate_insert( int gtid, void pc_addr, void data_addr, size_t pc_size )
	{
	struct private_common tn, *tt;
	struct shared_common *d_tn;

	/* +++++++++ START OF CRITICAL SECTION +++++++++ */

	__kmp_acquire_lock( & __kmp_global_lock, gtid );

	tn = (struct private_common *) __kmp_allocate( sizeof (struct private_common) );

	tn->gbl_addr = pc_addr;

	d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
	gtid, pc_addr ); /* Only the MASTER data table exists. */

	if (d_tn != 0) {
	/* This threadprivate variable has already been seen. */

	if ( d_tn->pod_init == 0 && d_tn->obj_init == 0 ) {
	d_tn->cmn_size = pc_size;

	if (d_tn->is_vec) {
	if (d_tn->ct.ctorv != 0) {
	/* Construct from scratch so no prototype exists */
	d_tn->obj_init = 0;
	}
	else if (d_tn->cct.cctorv != 0) {
	/* Now data initialize the prototype since it was previously registered */
	d_tn->obj_init = (void *) __kmp_allocate( d_tn->cmn_size );
	(void) (*d_tn->cct.cctorv) (d_tn->obj_init, pc_addr, d_tn->vec_len);
	}
	else {
	d_tn->pod_init = __kmp_init_common_data( data_addr, d_tn->cmn_size );
	}
	} else {
	if (d_tn->ct.ctor != 0) {
	/* Construct from scratch so no prototype exists */
	d_tn->obj_init = 0;
	}
	else if (d_tn->cct.cctor != 0) {
	/* Now data initialize the prototype since it was previously registered */
	d_tn->obj_init = (void *) __kmp_allocate( d_tn->cmn_size );
	(void) (*d_tn->cct.cctor) (d_tn->obj_init, pc_addr);
	}
	else {
	d_tn->pod_init = __kmp_init_common_data( data_addr, d_tn->cmn_size );
	}
	}
	}
	}
	else {
	struct shared_common **lnk_tn;

	d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
	d_tn->gbl_addr = pc_addr;
	d_tn->cmn_size = pc_size;
	d_tn->pod_init = __kmp_init_common_data( data_addr, pc_size );
	/*
	d_tn->obj_init = 0; // AC: commented out because __kmp_allocate zeroes the memory
	d_tn->ct.ctor = 0;
	d_tn->cct.cctor = 0;
	d_tn->dt.dtor = 0;
	d_tn->is_vec = FALSE;
	d_tn->vec_len = 0L;
	*/
	lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(pc_addr) ]);

	d_tn->next = *lnk_tn;
	*lnk_tn = d_tn;
	}

	tn->cmn_size = d_tn->cmn_size;

	if ( (__kmp_foreign_tp) ? (KMP_INITIAL_GTID (gtid)) : (KMP_UBER_GTID (gtid)) ) {
	tn->par_addr = (void *) pc_addr;
	}
	else {
	tn->par_addr = (void *) __kmp_allocate( tn->cmn_size );
	}

	__kmp_release_lock( & __kmp_global_lock, gtid );

	/* +++++++++ END OF CRITICAL SECTION +++++++++ */

	#ifdef USE_CHECKS_COMMON
	if (pc_size > d_tn->cmn_size) {
	KC_TRACE( 10, ( "__kmp_threadprivate_insert: THREADPRIVATE: %p (%"
	KMP_UINTPTR_SPEC " ,%" KMP_UINTPTR_SPEC ")\n",
	pc_addr, pc_size, d_tn->cmn_size ) );
	KMP_FATAL( TPCommonBlocksInconsist );
	}
	#endif /* USE_CHECKS_COMMON */

	tt = &(__kmp_threads[ gtid ]->th.th_pri_common->data[ KMP_HASH(pc_addr) ]);

	#ifdef KMP_TASK_COMMON_DEBUG
	if (*tt != 0) {
	KC_TRACE( 10, ( "__kmp_threadprivate_insert: WARNING! thread#%d: collision on %p\n",
	gtid, pc_addr ) );
	}
	#endif
	tn->next = *tt;
	*tt = tn;

	#ifdef KMP_TASK_COMMON_DEBUG
	KC_TRACE( 10, ( "__kmp_threadprivate_insert: thread#%d, inserted node %p on list\n",
	gtid, pc_addr ) );
	dump_list( );
	#endif

	/* Link the node into a simple list */

	tn->link = __kmp_threads[ gtid ]->th.th_pri_head;
	__kmp_threads[ gtid ]->th.th_pri_head = tn;

	#ifdef BUILD_TV
	__kmp_tv_threadprivate_store( __kmp_threads[ gtid ], tn->gbl_addr, tn->par_addr );
	#endif

	if( (__kmp_foreign_tp) ? (KMP_INITIAL_GTID (gtid)) : (KMP_UBER_GTID (gtid)) )
	return tn;

	/*
	* if C++ object with copy constructor, use it;
	* else if C++ object with constructor, use it for the non-master copies only;
	* else use pod_init and memcpy
	*
	* C++ constructors need to be called once for each non-master thread on allocate
	* C++ copy constructors need to be called once for each thread on allocate
	*/

	/*
	* C++ object with constructors/destructors;
	* don't call constructors for master thread though
	*/
	if (d_tn->is_vec) {
	if ( d_tn->ct.ctorv != 0) {
	(void) (*d_tn->ct.ctorv) (tn->par_addr, d_tn->vec_len);
	} else if (d_tn->cct.cctorv != 0) {
	(void) (*d_tn->cct.cctorv) (tn->par_addr, d_tn->obj_init, d_tn->vec_len);
	} else if (tn->par_addr != tn->gbl_addr) {
	__kmp_copy_common_data( tn->par_addr, d_tn->pod_init );
	}
	} else {
	if ( d_tn->ct.ctor != 0 ) {
	(void) (*d_tn->ct.ctor) (tn->par_addr);
	} else if (d_tn->cct.cctor != 0) {
	(void) (*d_tn->cct.cctor) (tn->par_addr, d_tn->obj_init);
	} else if (tn->par_addr != tn->gbl_addr) {
	__kmp_copy_common_data( tn->par_addr, d_tn->pod_init );
	}
	}
	/* !BUILD_OPENMP_C
	if (tn->par_addr != tn->gbl_addr)
	__kmp_copy_common_data( tn->par_addr, d_tn->pod_init ); */

	return tn;
	}

	/* ------------------------------------------------------------------------ */
	/* We are currently parallel, and we know the thread id. */
	/* ------------------------------------------------------------------------ */

	/*!
	@ingroup THREADPRIVATE

	@param loc source location information
	@param data pointer to data being privatized
	@param ctor pointer to constructor function for data
	@param cctor pointer to copy constructor function for data
	@param dtor pointer to destructor function for data

	Register constructors and destructors for thread private data.
	This function is called when executing in parallel, when we know the thread id.
	*/
	void
	__kmpc_threadprivate_register(ident_t loc, void data, kmpc_ctor ctor, kmpc_cctor cctor, kmpc_dtor dtor)
	{
	struct shared_common d_tn, *lnk_tn;

	KC_TRACE( 10, ("__kmpc_threadprivate_register: called\n" ) );

	#ifdef USE_CHECKS_COMMON
	/* copy constructor must be zero for current code gen (Nov 2002 - jph) */
	KMP_ASSERT( cctor == 0);
	#endif /* USE_CHECKS_COMMON */

	/* Only the global data table exists. */
	d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table, -1, data );

	if (d_tn == 0) {
	d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
	d_tn->gbl_addr = data;

	d_tn->ct.ctor = ctor;
	d_tn->cct.cctor = cctor;
	d_tn->dt.dtor = dtor;
	/*
	d_tn->is_vec = FALSE; // AC: commented out because __kmp_allocate zeroes the memory
	d_tn->vec_len = 0L;
	d_tn->obj_init = 0;
	d_tn->pod_init = 0;
	*/
	lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(data) ]);

	d_tn->next = *lnk_tn;
	*lnk_tn = d_tn;
	}
	}

	void *
	__kmpc_threadprivate(ident_t loc, kmp_int32 global_tid, void data, size_t size)
	{
	void *ret;
	struct private_common *tn;

	KC_TRACE( 10, ("__kmpc_threadprivate: T#%d called\n", global_tid ) );

	#ifdef USE_CHECKS_COMMON
	if (! __kmp_init_serial)
	KMP_FATAL( RTLNotInitialized );
	#endif /* USE_CHECKS_COMMON */

	if ( ! __kmp_threads[global_tid] -> th.th_root -> r.r_active && ! __kmp_foreign_tp ) {
	/* The parallel address will NEVER overlap with the data_address */
	/* dkp: 3rd arg to kmp_threadprivate_insert_private_data() is the data_address; use data_address = data */

	KC_TRACE( 20, ("__kmpc_threadprivate: T#%d inserting private data\n", global_tid ) );
	kmp_threadprivate_insert_private_data( global_tid, data, data, size );

	ret = data;
	}
	else {
	KC_TRACE( 50, ("__kmpc_threadprivate: T#%d try to find private data at address %p\n",
	global_tid, data ) );
	tn = __kmp_threadprivate_find_task_common( __kmp_threads[ global_tid ]->th.th_pri_common, global_tid, data );

	if ( tn ) {
	KC_TRACE( 20, ("__kmpc_threadprivate: T#%d found data\n", global_tid ) );
	#ifdef USE_CHECKS_COMMON
	if ((size_t) size > tn->cmn_size) {
	KC_TRACE( 10, ( "THREADPRIVATE: %p (%" KMP_UINTPTR_SPEC " ,%" KMP_UINTPTR_SPEC ")\n",
	data, size, tn->cmn_size ) );
	KMP_FATAL( TPCommonBlocksInconsist );
	}
	#endif /* USE_CHECKS_COMMON */
	}
	else {
	/* The parallel address will NEVER overlap with the data_address */
	/* dkp: 3rd arg to kmp_threadprivate_insert() is the data_address; use data_address = data */
	KC_TRACE( 20, ("__kmpc_threadprivate: T#%d inserting data\n", global_tid ) );
	tn = kmp_threadprivate_insert( global_tid, data, data, size );
	}

	ret = tn->par_addr;
	}
	KC_TRACE( 10, ("__kmpc_threadprivate: T#%d exiting; return value = %p\n",
	global_tid, ret ) );

	return ret;
	}

	/*!
	@ingroup THREADPRIVATE
	@param loc source location information
	@param global_tid global thread number
	@param data pointer to data to privatize
	@param size size of data to privatize
	@param cache pointer to cache
	@return pointer to private storage

	Allocate private storage for threadprivate data.
	*/
	void *
	__kmpc_threadprivate_cached(
	ident_t * loc,
	kmp_int32 global_tid, // gtid.
	void * data, // Pointer to original global variable.
	size_t size, // Size of original global variable.
	void *** cache
	) {
	KC_TRACE( 10, ("__kmpc_threadprivate_cached: T#%d called with cache: %p, address: %p, size: %"
	KMP_SIZE_T_SPEC "\n",
	global_tid, *cache, data, size ) );

	if ( TCR_PTR(*cache) == 0) {
	__kmp_acquire_lock( & __kmp_global_lock, global_tid );

	if ( TCR_PTR(*cache) == 0) {
	__kmp_acquire_bootstrap_lock(&__kmp_tp_cached_lock);
	__kmp_tp_cached = 1;
	__kmp_release_bootstrap_lock(&__kmp_tp_cached_lock);
	void ** my_cache;
	KMP_ITT_IGNORE(
	my_cache = (void**)
	__kmp_allocate(sizeof( void * ) * __kmp_tp_capacity + sizeof ( kmp_cached_addr_t ));
	);
	// No need to zero the allocated memory; __kmp_allocate does that.
	KC_TRACE( 50, ("__kmpc_threadprivate_cached: T#%d allocated cache at address %p\n",
	global_tid, my_cache ) );

	/* TODO: free all this memory in __kmp_common_destroy using __kmp_threadpriv_cache_list */
	/* Add address of mycache to linked list for cleanup later */
	kmp_cached_addr_t *tp_cache_addr;

	tp_cache_addr = (kmp_cached_addr_t *) & my_cache[__kmp_tp_capacity];
	tp_cache_addr -> addr = my_cache;
	tp_cache_addr -> next = __kmp_threadpriv_cache_list;
	__kmp_threadpriv_cache_list = tp_cache_addr;

	KMP_MB();

	TCW_PTR( *cache, my_cache);

	KMP_MB();
	}

	__kmp_release_lock( & __kmp_global_lock, global_tid );
	}

	void *ret;
	if ((ret = TCR_PTR((*cache)[ global_tid ])) == 0) {
	ret = __kmpc_threadprivate( loc, global_tid, data, (size_t) size);

	TCW_PTR( (*cache)[ global_tid ], ret);
	}
	KC_TRACE( 10, ("__kmpc_threadprivate_cached: T#%d exiting; return value = %p\n",
	global_tid, ret ) );

	return ret;
	}

	/*!
	@ingroup THREADPRIVATE
	@param loc source location information
	@param data pointer to data being privatized
	@param ctor pointer to constructor function for data
	@param cctor pointer to copy constructor function for data
	@param dtor pointer to destructor function for data
	@param vector_length length of the vector (bytes or elements?)
	Register vector constructors and destructors for thread private data.
	*/
	void
	__kmpc_threadprivate_register_vec( ident_t loc, void data, kmpc_ctor_vec ctor,
	kmpc_cctor_vec cctor, kmpc_dtor_vec dtor,
	size_t vector_length )
	{
	struct shared_common d_tn, *lnk_tn;

	KC_TRACE( 10, ("__kmpc_threadprivate_register_vec: called\n" ) );

	#ifdef USE_CHECKS_COMMON
	/* copy constructor must be zero for current code gen (Nov 2002 - jph) */
	KMP_ASSERT( cctor == 0);
	#endif /* USE_CHECKS_COMMON */

	d_tn = __kmp_find_shared_task_common( &__kmp_threadprivate_d_table,
	-1, data ); /* Only the global data table exists. */

	if (d_tn == 0) {
	d_tn = (struct shared_common *) __kmp_allocate( sizeof( struct shared_common ) );
	d_tn->gbl_addr = data;

	d_tn->ct.ctorv = ctor;
	d_tn->cct.cctorv = cctor;
	d_tn->dt.dtorv = dtor;
	d_tn->is_vec = TRUE;
	d_tn->vec_len = (size_t) vector_length;
	/*
	d_tn->obj_init = 0; // AC: commented out because __kmp_allocate zeroes the memory
	d_tn->pod_init = 0;
	*/
	lnk_tn = &(__kmp_threadprivate_d_table.data[ KMP_HASH(data) ]);

	d_tn->next = *lnk_tn;
	*lnk_tn = d_tn;
	}
	}