source: trunk/kernel/kern/dqdt.c @ 636

Last change on this file since 636 was 632, checked in by alain, 6 years ago

This version replace the RPC by direct remote memory access
for physical pages allacation/release.
It is commited before being tested.

File size: 22.9 KB
Line 
1/*
2 * dqdt.c - Distributed Quaternary Decision Tree implementation.
3 *
4 * Author : Alain Greiner (2016,2017,2018)
5 *
6 * Copyright (c)  UPMC Sorbonne Universites
7 *
8 * This file is part of ALMOS-MKH.
9 *
10 * ALMOS-MKH is free software; you can redistribute it and/or modify it
11 * under the terms of the GNU General Public License as published by
12 * the Free Software Foundation; version 2.0 of the License.
13 *
14 * ALMOS-MKH is distributed in the hope that it will be useful, but
15 * WITHOUT ANY WARRANTY; without even the implied warranty of
16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
17 * General Public License for more details.
18 *
19 * You should have received a copy of the GNU General Public License
20 * along with ALMOS-MKH; if not, write to the Free Software Foundation,
21 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
22 */
23
24#include <kernel_config.h>
25#include <hal_kernel_types.h>
26#include <hal_special.h>
27#include <hal_macros.h>
28#include <hal_atomic.h>
29#include <hal_remote.h>
30#include <thread.h>
31#include <printk.h>
32#include <chdev.h>
33#include <cluster.h>
34#include <bits.h>
35#include <dqdt.h>
36
37
38///////////////////////////////////////////////////////////////////////////////////////////
39//      Extern variables
40///////////////////////////////////////////////////////////////////////////////////////////
41
42extern chdev_directory_t  chdev_dir;  // defined in chdev.h / allocated in kernel_init.c
43
44///////////////////////////////////////////////////////////////////////////////////////////
45// This static recursive function traverse the DQDT quad-tree from root to bottom.
46///////////////////////////////////////////////////////////////////////////////////////////
47static void dqdt_recursive_print( xptr_t  node_xp )
48{
49        uint32_t x;
50        uint32_t y;
51    dqdt_node_t node;
52
53    // get node local copy
54    hal_remote_memcpy( XPTR( local_cxy , &node ), node_xp , sizeof(dqdt_node_t) );
55
56    // display node content
57        nolock_printk("- level %d / cluster %x : threads = %x / pages = %x / clusters %d / cores %d\n",
58    node.level, GET_CXY( node_xp ), node.threads, node.pages, node.clusters, node.cores );
59
60    // recursive call on children if node is not terminal
61    if ( node.level > 0 )
62    {
63        for ( x = 0 ; x < 2 ; x++ )
64        {
65            for ( y = 0 ; y < 2 ; y++ )
66            {
67                xptr_t iter_xp = node.children[x][y];
68                if ( iter_xp != XPTR_NULL ) dqdt_recursive_print( iter_xp );
69            }
70        }
71    }
72}
73
74/////////////////////////
75void dqdt_display( void )
76{
77    // get extended pointer on DQDT root node
78        cluster_t * cluster = &cluster_manager;
79    xptr_t      root_xp = cluster->dqdt_root_xp;
80
81    // get pointers on TXT0 chdev
82    xptr_t    txt0_xp  = chdev_dir.txt_tx[0];
83    cxy_t     txt0_cxy = GET_CXY( txt0_xp );
84    chdev_t * txt0_ptr = GET_PTR( txt0_xp );
85
86    // get extended pointer on remote TXT0 lock
87    xptr_t  lock_xp = XPTR( txt0_cxy , &txt0_ptr->wait_lock );
88
89    // get TXT0 lock
90    remote_busylock_acquire( lock_xp );
91
92    // print header
93    nolock_printk("\n***** DQDT state\n\n");
94
95    // call recursive function
96    dqdt_recursive_print( root_xp );
97
98    // release TXT0 lock
99    remote_busylock_release( lock_xp );
100}
101
102///////////////////////////////////////////////////////////////////////////////////////
103// This static function initializes recursively, from top to bottom, the quad-tree
104// infrastructure. The DQDT nodes are allocated as global variables in each local
105// cluster manager. At each level in the quad-tree, this function initializes the
106// node identified by the <cxy> and <level> arguments, selects in each child
107// macro-cluster the precise cluster where will be placed the subtree root node,
108// and call recursively itself to initialize the child node in the selected cluster.
109///////////////////////////////////////////////////////////////////////////////////////
110// @ node cxy  : cluster containing the node to initialize
111// @ level     : level of node to be initialised
112// @ parent_xp : extended pointer on the parent node
113///////////////////////////////////////////////////////////////////////////////////////
114static void dqdt_recursive_build( cxy_t    node_cxy,
115                                  uint32_t level,
116                                  xptr_t   parent_xp )
117{
118    assert( (level < 5) , __FUNCTION__, "illegal DQDT level %d\n", level );
119 
120    uint32_t node_x;         // node X coordinate
121    uint32_t node_y;         // node Y coordinate
122    uint32_t mask;           // to compute associated macro-cluster coordinates
123    uint32_t node_base_x;    // associated macro_cluster X coordinate
124    uint32_t node_base_y;    // associated macro_cluster y coordinate
125    uint32_t half;           // associated macro-cluster half size
126    uint32_t cores;          // number of cores in macro cluster
127    uint32_t clusters;       // number of clusters in macro cluster
128
129    // get node cluster coordinates
130    node_x = HAL_X_FROM_CXY( node_cxy );
131    node_y = HAL_Y_FROM_CXY( node_cxy );
132       
133    // get macro-cluster mask and half-size
134    mask   = (1 << level) - 1;
135    half   = (level > 0) ? (1 << (level - 1)) : 0;
136
137    // get macro-cluster coordinates
138    node_base_x = node_x & ~mask;
139    node_base_y = node_y & ~mask;
140
141    // get pointer on local cluster manager
142    cluster_t * cluster = LOCAL_CLUSTER;
143
144    // build local and extended pointer on node to be initialized
145    dqdt_node_t * node_ptr = &cluster->dqdt_tbl[level];
146    xptr_t        node_xp  = XPTR( node_cxy , node_ptr );
147
148#if DEBUG_DQDT_INIT
149printk("\n[DBG] %s : cxy(%d,%d) / level %d / mask %x / half %d / ptr %x\n",
150__FUNCTION__, node_x, node_y, level, mask, half, node_ptr );
151#endif
152 
153    // make remote node default initialisation
154    hal_remote_memset( node_xp , 0 , sizeof( dqdt_node_t ) );
155
156    // initialize <parent> field
157    hal_remote_s64( XPTR( node_cxy , &node_ptr->parent ) , parent_xp );
158
159    // initialize <level> field
160    hal_remote_s32( XPTR( node_cxy , &node_ptr->level ) , level );
161
162    // recursive initialisation
163    if( level == 0 )                      // terminal case : cluster
164    {
165        // initialize <clusters> field in node
166        hal_remote_s32( XPTR( node_cxy , &node_ptr->clusters ) , 1 );
167
168        // initialize <cores> field in node
169        cores = hal_remote_l32( XPTR ( node_cxy , &cluster->cores_nr ) );
170        hal_remote_s32( XPTR( node_cxy , &node_ptr->cores ) , cores );
171    }
172    else                                  // non terminal : macro-cluster
173    {
174        bool_t        found;
175        uint32_t      x;
176        uint32_t      y;
177        cxy_t         child_cxy;
178        xptr_t        child_xp;
179        dqdt_node_t * child_ptr =  &cluster->dqdt_tbl[level-1];
180
181        // search an active cluster in child[0][0] macro-cluster
182        found = false; 
183        for( x = node_base_x ; 
184        (x < (node_base_x + half)) && (found == false) ; x++ )
185        {
186            for( y = node_base_y ; 
187            (y < (node_base_y + half)) && (found == false) ; y++ )
188            {
189                child_cxy = HAL_CXY_FROM_XY( x , y );
190
191                if( cluster_is_active( child_cxy ) )
192                {
193                    // initialize recursively selected child[0][0] node
194                    dqdt_recursive_build( child_cxy , level-1 , node_xp );
195
196                    // build extended pointer on child[0][0] node
197                    child_xp = XPTR( child_cxy , child_ptr );
198
199                    // update <cores> field in node
200                    cores = hal_remote_l32( XPTR ( child_cxy , &child_ptr->cores ) );
201                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->cores ) , cores );
202
203                    // update <clusters> field in node
204                    clusters = hal_remote_l32( XPTR ( child_cxy , &child_ptr->clusters ) );
205                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->clusters ) , clusters );
206
207                    // update <child[0][0]> field in node
208                    hal_remote_s64( XPTR( node_cxy , &node_ptr->children[0][0] ), child_xp );
209
210                    // udate <arity> field in node
211                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->arity ) , 1 );
212   
213                    // exit loops
214                    found = true;
215                }
216            }
217        }
218
219        // search an active cluster in child[0][1] macro-cluster
220        found = false; 
221        for( x = node_base_x ; 
222        (x < (node_base_x + half)) && (found == false) ; x++ )
223        {
224            for( y = (node_base_y + half) ; 
225            (y < (node_base_y + (half<<1))) && (found == false) ; y++ )
226            {
227                child_cxy = HAL_CXY_FROM_XY( x , y );
228
229                if( cluster_is_active( child_cxy ) )
230                {
231                    // initialize recursively selected child[0][1] node
232                    dqdt_recursive_build( child_cxy , level-1 , node_xp );
233
234                    // build extended pointer on child[0][1] node
235                    child_xp = XPTR( child_cxy , child_ptr );
236
237                    // update <cores> field in node
238                    cores = hal_remote_l32( XPTR ( child_cxy , &child_ptr->cores ) );
239                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->cores ) , cores );
240
241                    // update <clusters> field in node
242                    clusters = hal_remote_l32( XPTR ( child_cxy , &child_ptr->clusters ) );
243                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->clusters ) , clusters );
244
245                    // update <child[0][1]> field in node
246                    hal_remote_s64( XPTR( node_cxy , &node_ptr->children[0][1] ), child_xp );
247
248                    // udate <arity> field in node
249                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->arity ) , 1 );
250   
251                    // exit loops
252                    found = true;
253                }
254            }
255        }
256
257        // search an active cluster in child[1][0] macro-cluster
258        found = false; 
259        for( x = (node_base_x +half) ; 
260        (x < (node_base_x + (half<<1))) && (found == false) ; x++ )
261        {
262            for( y = node_base_y ; 
263            (y < (node_base_y + half)) && (found == false) ; y++ )
264            {
265                child_cxy = HAL_CXY_FROM_XY( x , y );
266
267                if( cluster_is_active( child_cxy ) )
268                {
269                    // initialize recursively selected child[1][0] node
270                    dqdt_recursive_build( child_cxy , level-1 , node_xp );
271
272                    // build extended pointer on child[1][0] node
273                    child_xp = XPTR( child_cxy , child_ptr );
274
275                    // update <cores> field in node
276                    cores = hal_remote_l32( XPTR ( child_cxy , &child_ptr->cores ) );
277                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->cores ) , cores );
278
279                    // update <clusters> field in node
280                    clusters = hal_remote_l32( XPTR ( child_cxy , &child_ptr->clusters ) );
281                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->clusters ) , clusters );
282
283                    // update <child[1][0]> field in node
284                    hal_remote_s64( XPTR( node_cxy , &node_ptr->children[1][0] ), child_xp );
285
286                    // udate <arity> field in node
287                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->arity ) , 1 );
288   
289                    // exit loops
290                    found = true;
291                }
292            }
293        }
294
295        // search an active cluster in child[1][1] macro-cluster
296        found = false; 
297        for( x = (node_base_x + half) ; 
298        (x < (node_base_x + (half<<1))) && (found == false) ; x++ )
299        {
300            for( y = (node_base_y + half) ; 
301            (y < (node_base_y + (half<<1))) && (found == false) ; y++ )
302            {
303                child_cxy = HAL_CXY_FROM_XY( x , y );
304
305                if( cluster_is_active( child_cxy ) )
306                {
307                    // initialize recursively selected child[1][1] node
308                    dqdt_recursive_build( child_cxy , level-1 , node_xp );
309
310                    // build extended pointer on child[1][1] node
311                    child_xp = XPTR( child_cxy , child_ptr );
312
313                    // update <cores> field in node
314                    cores = hal_remote_l32( XPTR ( child_cxy , &child_ptr->cores ) );
315                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->cores ) , cores );
316
317                    // update <clusters> field in node
318                    clusters = hal_remote_l32( XPTR ( child_cxy , &child_ptr->clusters ) );
319                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->clusters ) , clusters );
320
321                    // update <child[1][1]> field in node
322                    hal_remote_s64( XPTR( node_cxy , &node_ptr->children[1][1] ), child_xp );
323
324                    // udate <arity> field in node
325                    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->arity ) , 1 );
326   
327                    // exit loops
328                    found = true;
329                }
330            }
331        }
332    }
333}  // end dqdt_recursive_build()
334
335//////////////////////
336void dqdt_init( void )
337{
338    // get x_size & y_size from cluster manager
339    cluster_t * cluster = &cluster_manager;
340    uint32_t    x_size  = cluster->x_size;
341    uint32_t    y_size  = cluster->y_size;
342
343    assert( ((x_size <= 16) && (y_size <= 16)) , "illegal mesh size\n");
344 
345    // compute level_max
346    uint32_t  x_size_ext = POW2_ROUNDUP( x_size );
347    uint32_t  y_size_ext = POW2_ROUNDUP( y_size );
348    uint32_t  size_ext   = MAX( x_size_ext , y_size_ext );
349    uint32_t  level_max  = bits_log2( size_ext );
350
351    // each CP0 register the DQDT root in local cluster manager
352    cluster->dqdt_root_xp = XPTR( 0 , &cluster->dqdt_tbl[level_max] );
353
354#if DEBUG_DQDT_INIT
355if( local_cxy == 0 )
356printk("\n[DBG] %s : x_size = %d / y_size = %d / level_max = %d\n",
357__FUNCTION__, x_size, y_size, level_max );
358#endif
359   
360    // only CP0 in cluster 0 call the recursive function to build the quad-tree
361    if (local_cxy == 0) dqdt_recursive_build( local_cxy , level_max , XPTR_NULL );
362
363#if DEBUG_DQDT_INIT
364if( local_cxy == 0 ) dqdt_display();
365#endif
366
367}  // end dqdt_init()
368
369
370///////////////////////////////////////////////////////////////////////////
371// This recursive function is called by both the dqdt_increment_pages()
372// and by the dqdt_decrement_pages() functions.
373// It traverses the quad tree from clusters to root.
374///////////////////////////////////////////////////////////////////////////
375// @ node_xp    : extended pointer on current node
376// @ increment  : number of pages variation
377///////////////////////////////////////////////////////////////////////////
378static void dqdt_propagate_pages( xptr_t  node_xp,
379                                  int32_t increment )
380{
381    // get current node cluster identifier and local pointer
382    cxy_t         node_cxy = GET_CXY( node_xp );
383    dqdt_node_t * node_ptr = GET_PTR( node_xp );
384
385    // update current node pages number
386    hal_remote_atomic_add( XPTR( node_cxy , &node_ptr->pages ) , increment );
387
388    // get extended pointer on parent node
389    xptr_t parent_xp = (xptr_t)hal_remote_l64( XPTR( node_cxy , &node_ptr->parent ) );
390
391    // propagate if required
392    if ( parent_xp != XPTR_NULL ) dqdt_propagate_pages( parent_xp, increment );
393}
394
395////////////////////////////////////////
396void dqdt_increment_pages( cxy_t    cxy,
397                           uint32_t order )
398{
399    // get local pointer on node[0] (same in all clusters)
400    dqdt_node_t * node_ptr = &LOCAL_CLUSTER->dqdt_tbl[0];
401
402    // update DQDT node[0] in remote cluster cxy
403    hal_remote_atomic_add( XPTR( cxy , &node_ptr->pages ) , (1 << order) );
404
405    // get extended pointer on parent node in remote cluster cxy
406    xptr_t parent_xp = hal_remote_l64( XPTR( cxy , &node_ptr->parent ) );
407
408     // propagate to DQDT upper levels
409    if( parent_xp != XPTR_NULL ) dqdt_propagate_pages( parent_xp , (1 << order) );
410
411#if DEBUG_DQDT_UPDATE_PAGES
412uint32_t cycle = hal_get_cycles();
413if( cycle > DEBUG_DQDT_UPDATE_PAGES )
414printk("\n[DBG] %s : thread %x in process %x / %x pages in cluster %x / cycle %d\n",
415__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid,
416hal_remote_l32( XPTR( cxy , &node_ptr->pages ), cxy, cycle );
417#endif
418
419}
420
421////////////////////////////////////////
422void dqdt_decrement_pages( cxy_t    cxy,
423                           uint32_t order )
424{
425    // get local pointer on node[0] (same in all clusters)
426    dqdt_node_t * node_ptr = &LOCAL_CLUSTER->dqdt_tbl[0];
427
428    // update DQDT node[0] in remote cluster cxy
429    hal_remote_atomic_add( XPTR( cxy , &node_ptr->pages ) , -(1 << order) );
430
431    // get extended pointer on parent node in remote cluster cxy
432    xptr_t parent_xp = hal_remote_l64( XPTR( cxy , &node_ptr->parent ) );
433
434     // propagate to DQDT upper levels
435    if( parent_xp != XPTR_NULL ) dqdt_propagate_pages( parent_xp , -(1 << order) );
436
437#if DEBUG_DQDT_UPDATE_PAGES
438uint32_t cycle = hal_get_cycles();
439if( cycle > DEBUG_DQDT_UPDATE_PAGES )
440printk("\n[DBG] %s : thread %x in process %x / %x pages in cluster %x / cycle %d\n",
441__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid,
442hal_remote_l32( XPTR( cxy , &node_ptr->pages ), cxy, cycle );
443#endif
444
445}
446
447
448
449///////////////////////////////////////////////////////////////////////////
450// This recursive function is called by both the dqdt_increment_threads()
451// and by the dqdt_decrement_threads functions.
452// It traverses the quad tree from clusters to root.
453///////////////////////////////////////////////////////////////////////////
454// @ node       : extended pointer on current node
455// @ increment  : number of pages variation
456///////////////////////////////////////////////////////////////////////////
457static void dqdt_propagate_threads( xptr_t  node,
458                                    int32_t increment )
459{
460    // get current node cluster identifier and local pointer
461    cxy_t         cxy = GET_CXY( node );
462    dqdt_node_t * ptr = GET_PTR( node );
463
464    // update current node threads number
465    hal_remote_atomic_add( XPTR( cxy , &ptr->threads ) , increment );
466
467    // get extended pointer on parent node
468    xptr_t parent = (xptr_t)hal_remote_l64( XPTR( cxy , &ptr->parent ) );
469
470    // propagate if required
471    if ( parent != XPTR_NULL ) dqdt_propagate_threads( parent, increment );
472}
473
474///////////////////////////////////
475void dqdt_increment_threads( void )
476{
477        cluster_t   * cluster = LOCAL_CLUSTER;
478    dqdt_node_t * node    = &cluster->dqdt_tbl[0];
479
480    // update DQDT node level 0
481    hal_atomic_add( &node->threads , 1 );
482
483    // propagate to DQDT upper levels
484    if( node->parent != XPTR_NULL ) dqdt_propagate_threads( node->parent , 1 );
485
486#if DEBUG_DQDT_UPDATE_THREADS
487uint32_t cycle = hal_get_cycles();
488if( cycle > DEBUG_DQDT_UPDATE_THREADS )
489printk("\n[DBG] %s : thread %x in process %x / %d threads in cluster %x / cycle %d\n",
490__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid, 
491node->threads, local_cxy, cycle );
492#endif
493
494}
495
496///////////////////////////////////
497void dqdt_decrement_threads( void )
498{
499        cluster_t   * cluster = LOCAL_CLUSTER;
500    dqdt_node_t * node    = &cluster->dqdt_tbl[0];
501
502    // update DQDT node level 0
503    hal_atomic_add( &node->threads , -1 );
504
505    // propagate to DQDT upper levels
506    if( node->parent != XPTR_NULL ) dqdt_propagate_threads( node->parent , -1 );
507
508#if DEBUG_DQDT_UPDATE_THREADS
509uint32_t cycle = hal_get_cycles();
510if( cycle > DEBUG_DQDT_UPDATE_THREADS )
511printk("\n[DBG] %s : thread %x in process %x / %d threads in cluster %x / cycle %d\n",
512__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid, 
513node->threads, local_cxy, cycle );
514#endif
515
516}
517
518
519/////////////////////////////////////////////////////////////////////////////////////
520// This recursive function is called by both the dqdt_get_cluster_for_process()
521// and by the dqdt_get_cluster_for_memory() functions to select the cluster with the
522// smallest number of threads per core, or the smallest number of pages per cluster.
523// It traverses the quad tree from root to clusters.
524/////////////////////////////////////////////////////////////////////////////////////
525static cxy_t dqdt_select_cluster( xptr_t node,
526                                  bool_t for_memory )
527{
528    dqdt_node_t   node_copy;     // local copy of the current DQDT node
529    xptr_t        child_xp;      // extended pointer on a DQDT child node
530    uint32_t      x;             // child node X coordinate
531    uint32_t      y;             // child node Y coordinate
532    uint32_t      select_x;      // selected child X coordinate
533    uint32_t      select_y;      // selected child Y coordinate
534    uint32_t      load;          // load of the child (threads or pages)
535    uint32_t      load_min;      // current value of the minimal load
536
537    // get DQDT node local copy
538    hal_remote_memcpy( XPTR( local_cxy , &node_copy ), node , sizeof(dqdt_node_t) );
539
540    // return cluster identifier for a terminal mode
541    if( node_copy.level == 0 ) return GET_CXY(node);
542
543    // analyse load for all children in non terminal node
544    load_min = 0xFFFFFFFF;
545    select_x = 0;
546    select_y = 0;
547    for( x = 0 ; x < 2 ; x++ )
548    {
549        for( y = 0 ; y < 2 ; y++ )
550        {
551            child_xp = node_copy.children[x][y];
552            if( child_xp != XPTR_NULL )
553            {
554                cxy_t         cxy  = GET_CXY( child_xp );
555                dqdt_node_t * ptr  = GET_PTR( child_xp );
556
557                // compute average load  for each child
558                if( for_memory )
559                {
560                    load = hal_remote_l32( XPTR( cxy , &ptr->pages ) ) /
561                           hal_remote_l32( XPTR( cxy , &ptr->clusters ) );
562                }
563                else
564                {
565                    load = hal_remote_l32( XPTR( cxy , &ptr->threads ) ) /
566                           hal_remote_l32( XPTR( cxy , &ptr->cores ) );
567                }
568
569                // select children with smallest load
570                if( load <= load_min )
571                {
572                    load_min = load;
573                    select_x = x;
574                    select_y = y;
575                }
576            }
577        }
578    }
579
580    // select the child with the lowest load
581    return dqdt_select_cluster( node_copy.children[select_x][select_y], for_memory );
582
583}  // end dqdt_select_cluster()
584
585
586//////////////////////////////////////////
587cxy_t dqdt_get_cluster_for_process( void )
588{
589    // call recursive function
590    cxy_t cxy = dqdt_select_cluster( LOCAL_CLUSTER->dqdt_root_xp , false );
591
592#if DEBUG_DQDT_SELECT_FOR_PROCESS
593uint32_t cycle = hal_get_cycles();
594if( cycle > DEBUG_DQDT_SELECT_FOR_PROCESS )
595printk("\n[DBG] %s : thread %x in process %x select cluster %x / cycle %d\n",
596__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid, cxy, cycle );
597#endif
598
599    return cxy;
600}
601
602/////////////////////////////////////////
603cxy_t dqdt_get_cluster_for_memory( void )
604{
605    // call recursive function
606    cxy_t cxy = dqdt_select_cluster( LOCAL_CLUSTER->dqdt_root_xp , true );
607
608#if DEBUG_DQDT_SELECT_FOR_MEMORY
609uint32_t cycle = hal_get_cycles();
610if( cycle > DEBUG_DQDT_SELECT_FOR_MEMORY )
611printk("\n[DBG] %s : thread %x in process %x select cluster %x / cycle %d\n",
612__FUNCTION__, CURRENT_THREAD->trdid, CURRENT_THREAD->process->pid, cxy, cycle );
613#endif
614
615    return cxy;
616}
617
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