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source: trunk/kernel/libk/grdxt.c @ 680

Last change on this file since 680 was 671, checked in by alain, 4 years ago
Cosmetic.
File size: 21.9 KB

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1	/*
2	* grdxt.c - Three-levels Generic Radix-tree implementation.
3	*
4	* authors Alain Greiner (2016,2017,2018,2019))
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 <hal_kernel_types.h>
25	#include <hal_special.h>
26	#include <hal_remote.h>
27	#include <errno.h>
28	#include <printk.h>
29	#include <kmem.h>
30	#include <grdxt.h>
31
32	////////////////////////////////////////////////////////////////////////////////////////
33	// Local access functions
34	////////////////////////////////////////////////////////////////////////////////////////
35
36	/////////////////////////////////
37	error_t grdxt_init( grdxt_t * rt,
38	uint32_t ix1_width,
39	uint32_t ix2_width,
40	uint32_t ix3_width )
41	{
42	void ** root;
43	kmem_req_t req;
44
45	rt->ix1_width = ix1_width;
46	rt->ix2_width = ix2_width;
47	rt->ix3_width = ix3_width;
48
49	// allocates first level array
50	req.type = KMEM_KCM;
51	req.order = ix1_width + ( (sizeof(void*) == 4) ? 2 : 3 );
52	req.flags = AF_KERNEL \| AF_ZERO;
53	root = kmem_alloc( &req );
54
55	if( root == NULL )
56	{
57	printk("\n[ERROR] in %s : cannot allocate first level array\n", __FUNCTION__);
58	return -1;
59	}
60
61	rt->root = root;
62
63	return 0;
64
65	} // end grdxt_init()
66
67	//////////////////////////////////
68	void grdxt_destroy( grdxt_t * rt )
69	{
70	kmem_req_t req;
71
72	uint32_t w1 = rt->ix1_width;
73	uint32_t w2 = rt->ix2_width;
74	uint32_t w3 = rt->ix3_width;
75
76	void ** ptr1 = rt->root;
77	void ** ptr2;
78	void ** ptr3;
79
80	uint32_t ix1;
81	uint32_t ix2;
82	uint32_t ix3;
83
84	assert( __FUNCTION__, (rt != NULL) , "pointer on radix tree is NULL\n" );
85
86	for( ix1=0 ; ix1 < (uint32_t)(1 << w1) ; ix1++ )
87	{
88	ptr2 = ptr1[ix1];
89
90	if( ptr2 == NULL ) continue;
91
92	for( ix2=0 ; ix2 < (uint32_t)(1 << w2) ; ix2++ )
93	{
94	ptr3 = ptr2[ix2];
95
96	if( ptr3 == NULL ) continue;
97
98	for( ix3=0 ; ix3 < (uint32_t)(1 << w3) ; ix3++ )
99	{
100	if( ptr3[ix3] != NULL )
101	{
102	printk("\n[WARNING] in %s : ptr3[%d][%d][%d] non empty\n",
103	__FUNCTION__, ix1, ix2, ix3 );
104	}
105	}
106
107	// release level 3 array
108	req.type = KMEM_KCM;
109	req.ptr = ptr3;
110	kmem_free( &req );
111	}
112
113	// release level 2 array
114	req.type = KMEM_KCM;
115	req.ptr = ptr2;
116	kmem_free( &req );
117	}
118
119	// release level 1 array
120	req.type = KMEM_KCM;
121	req.ptr = ptr1;
122	kmem_free( &req );
123
124	} // end grdxt_destroy()
125
126	////////////////////////////////////
127	error_t grdxt_insert( grdxt_t * rt,
128	uint32_t key,
129	void * value )
130	{
131	kmem_req_t req;
132
133	uint32_t w1 = rt->ix1_width;
134	uint32_t w2 = rt->ix2_width;
135	uint32_t w3 = rt->ix3_width;
136
137	// Check key value
138	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
139
140	// compute indexes
141	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
142	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
143	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
144
145	// get ptr1
146	void ** ptr1 = rt->root;
147
148	if( ptr1 == NULL ) return -1;
149
150	// get ptr2
151	void ** ptr2 = ptr1[ix1];
152
153	// If required, allocate memory for the missing level 2 array
154	if( ptr2 == NULL )
155	{
156	// allocate memory for level 2 array
157	req.type = KMEM_KCM;
158	req.order = w2 + ( (sizeof(void*) == 4) ? 2 : 3 );
159	req.flags = AF_KERNEL \| AF_ZERO;
160	ptr2 = kmem_alloc( &req );
161
162	if( ptr2 == NULL) return -1;
163
164	// update level 1 array
165	ptr1[ix1] = ptr2;
166	}
167
168	// get ptr3
169	void ** ptr3 = ptr2[ix2];
170
171	// If required, allocate memory for the missing level 3 array
172	if( ptr3 == NULL )
173	{
174	// allocate memory for level 3 array
175	req.type = KMEM_KCM;
176	req.order = w3 + ( (sizeof(void*) == 4) ? 2 : 3 );
177	req.flags = AF_KERNEL \| AF_ZERO;
178	ptr3 = kmem_alloc( &req );
179
180	if( ptr3 == NULL) return -1;
181
182	// update level 3 array
183	ptr2[ix2] = ptr3;
184	}
185
186	// register the value
187	ptr3[ix3] = value;
188
189	hal_fence();
190
191	return 0;
192
193	} // end grdxt_insert()
194
195	///////////////////////////////////
196	void * grdxt_remove( grdxt_t * rt,
197	uint32_t key )
198	{
199	uint32_t w1 = rt->ix1_width;
200	uint32_t w2 = rt->ix2_width;
201	uint32_t w3 = rt->ix3_width;
202
203	// Check key value
204	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
205
206	// compute indexes
207	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
208	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
209	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
210
211	// get ptr1
212	void ** ptr1 = rt->root;
213
214	if( ptr1 == NULL ) return NULL;
215
216	// get ptr2
217	void ** ptr2 = ptr1[ix1];
218
219	if( ptr2 == NULL ) return NULL;
220
221	// get ptr3
222	void ** ptr3 = ptr2[ix2];
223
224	if( ptr3 == NULL ) return NULL;
225
226	// get value
227	void * value = ptr3[ix3];
228
229	// reset selected slot
230	ptr3[ix3] = NULL;
231	hal_fence();
232
233	return value;
234
235	} // end grdxt_remove()
236
237	///////////////////////////////////
238	void * grdxt_lookup( grdxt_t * rt,
239	uint32_t key )
240	{
241	uint32_t w1 = rt->ix1_width;
242	uint32_t w2 = rt->ix2_width;
243	uint32_t w3 = rt->ix3_width;
244
245	// Check key value
246	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
247
248	void ** ptr1 = rt->root;
249	void ** ptr2;
250	void ** ptr3;
251
252	// compute indexes
253	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
254	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
255	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
256
257	// get ptr2
258	ptr2 = ptr1[ix1];
259	if( ptr2 == NULL ) return NULL;
260
261	// get ptr3
262	ptr3 = ptr2[ix2];
263	if( ptr3 == NULL ) return NULL;
264
265	// get value
266	void * value = ptr3[ix3];
267
268	return value;
269
270	} // end grdxt_lookup()
271
272	//////////////////////////////////////
273	void * grdxt_get_first( grdxt_t * rt,
274	uint32_t start_key,
275	uint32_t * found_key )
276	{
277	uint32_t ix1;
278	uint32_t ix2;
279	uint32_t ix3;
280
281	uint32_t w1 = rt->ix1_width;
282	uint32_t w2 = rt->ix2_width;
283	uint32_t w3 = rt->ix3_width;
284
285	// Check key value
286	assert( __FUNCTION__, ((start_key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", start_key );
287
288	// compute max indexes
289	uint32_t max1 = 1 << w1;
290	uint32_t max2 = 1 << w2;
291	uint32_t max3 = 1 << w3;
292
293	// compute min indexes
294	uint32_t min1 = start_key >> (w2 + w3);
295	uint32_t min2 = (start_key >> w3) & ((1 << w2) -1);
296	uint32_t min3 = start_key & ((1 << w3) - 1);
297
298	void ** ptr1 = rt->root;
299	void ** ptr2;
300	void ** ptr3;
301
302	for( ix1 = min1 ; ix1 < max1 ; ix1++ )
303	{
304	ptr2 = ptr1[ix1];
305	if( ptr2 == NULL ) continue;
306
307	for( ix2 = min2 ; ix2 < max2 ; ix2++ )
308	{
309	ptr3 = ptr2[ix2];
310	if( ptr3 == NULL ) continue;
311
312	for( ix3 = min3 ; ix3 < max3 ; ix3++ )
313	{
314	if( ptr3[ix3] == NULL ) continue;
315	else
316	{
317	*found_key = (ix1 << (w2+w3)) \| (ix2 << w3) \| ix3;
318	return ptr3[ix3];
319	}
320	}
321	}
322	}
323
324	return NULL;
325
326	} // end grdxt_get_first()
327
328
329
330	////////////////////////////////////////////////////////////////////////////////////////
331	// Remote access functions
332	////////////////////////////////////////////////////////////////////////////////////////
333
334	////////////////////////////////////////////
335	error_t grdxt_remote_init( xptr_t rt_xp,
336	uint32_t ix1_width,
337	uint32_t ix2_width,
338	uint32_t ix3_width )
339	{
340	void ** root;
341	kmem_req_t req;
342
343	// get cluster and local pointer
344	cxy_t rt_cxy = GET_CXY( rt_xp );
345	grdxt_t * rt_ptr = GET_PTR( rt_xp );
346
347	// initialize widths
348	hal_remote_s32( XPTR( rt_cxy , &rt_ptr->ix1_width ) , ix1_width );
349	hal_remote_s32( XPTR( rt_cxy , &rt_ptr->ix2_width ) , ix2_width );
350	hal_remote_s32( XPTR( rt_cxy , &rt_ptr->ix3_width ) , ix3_width );
351
352	// allocates first level array
353	req.type = KMEM_KCM;
354	req.order = ix1_width + ( (sizeof(void*) == 4) ? 2 : 3 );
355	req.flags = AF_KERNEL \| AF_ZERO;
356	root = kmem_remote_alloc( rt_cxy , &req );
357
358	if( root == NULL )
359	{
360	printk("\n[ERROR] in %s : cannot allocate first level array\n", __FUNCTION__);
361	return -1;
362	}
363
364	// register first level array in rt descriptor
365	hal_remote_spt( XPTR( rt_cxy , &rt_ptr->root ) , root );
366
367	return 0;
368
369	} // end grdxt_remote_init()
370
371	//////////////////////////////////////////
372	void grdxt_remote_destroy( xptr_t rt_xp )
373	{
374	kmem_req_t req;
375
376	uint32_t w1;
377	uint32_t w2;
378	uint32_t w3;
379
380	uint32_t ix1;
381	uint32_t ix2;
382	uint32_t ix3;
383
384	void ** ptr1;
385	void ** ptr2;
386	void ** ptr3;
387
388	// get cluster and local pointer
389	cxy_t rt_cxy = GET_CXY( rt_xp );
390	grdxt_t * rt_ptr = GET_PTR( rt_xp );
391
392	// get widths
393	w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
394	w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
395	w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
396
397	// get ptr1
398	ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
399
400	for( ix1=0 ; ix1 < (uint32_t)(1 << w1) ; ix1++ )
401	{
402	// get ptr2
403	ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
404
405	if( ptr2 == NULL ) continue;
406
407	for( ix2=0 ; ix2 < (uint32_t)(1 << w2) ; ix2++ )
408	{
409	// get ptr3
410	ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
411
412	if( ptr3 == NULL ) continue;
413
414	for( ix3=0 ; ix3 < (uint32_t)(1 << w3) ; ix3++ )
415	{
416	if( ptr3[ix3] != NULL )
417	{
418	printk("\n[WARNING] in %s : ptr3[%d][%d][%d] non empty\n",
419	__FUNCTION__, ix1, ix2, ix3 );
420	}
421	}
422
423	// release level 3 array
424	req.type = KMEM_KCM;
425	req.ptr = ptr3;
426	kmem_remote_free( rt_cxy , &req );
427	}
428
429	// release level 2 array
430	req.type = KMEM_KCM;
431	req.ptr = ptr2;
432	kmem_remote_free( rt_cxy , &req );
433	}
434
435	// release level 1 array
436	req.type = KMEM_KCM;
437	req.ptr = ptr1;
438	kmem_remote_free( rt_cxy , &req );
439
440	} // end grdxt_remote_destroy()
441
442	//////////////////////////////////////////////
443	error_t grdxt_remote_insert( xptr_t rt_xp,
444	uint32_t key,
445	void * value )
446	{
447	kmem_req_t req;
448
449	// get cluster and local pointer on remote rt descriptor
450	cxy_t rt_cxy = GET_CXY( rt_xp );
451	grdxt_t * rt_ptr = GET_PTR( rt_xp );
452
453	#if DEBUG_GRDXT_INSERT
454	uint32_t cycle = (uint32_t)hal_get_cycles();
455	if(DEBUG_GRDXT_INSERT < cycle)
456	printk("\n[%s] enter / rt_xp (%x,%x) / key %x / value %x\n",
457	__FUNCTION__, rt_cxy, rt_ptr, key, (intptr_t)value );
458	#endif
459
460	// get widths
461	uint32_t w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
462	uint32_t w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
463	uint32_t w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
464
465	#if DEBUG_GRDXT_INSERT
466	if(DEBUG_GRDXT_INSERT < cycle)
467	printk("\n[%s] get widths : w1 %d / w2 %d / w3 %d\n",
468	__FUNCTION__, w1, w2, w3 );
469	#endif
470
471	// Check key value
472	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
473
474	// compute indexes
475	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
476	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
477	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
478
479	#if DEBUG_GRDXT_INSERT
480	if(DEBUG_GRDXT_INSERT < cycle)
481	printk("\n[%s] compute indexes : ix1 %d / ix2 %d / ix3 %d\n",
482	__FUNCTION__, ix1, ix2, ix3 );
483	#endif
484
485	// get ptr1
486	void ** ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
487
488	if( ptr1 == NULL ) return -1;
489
490	#if DEBUG_GRDXT_INSERT
491	if(DEBUG_GRDXT_INSERT < cycle)
492	printk("\n[%s] compute ptr1 = %x\n",
493	__FUNCTION__, (intptr_t)ptr1 );
494	#endif
495
496	// get ptr2
497	void ** ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
498
499	#if DEBUG_GRDXT_INSERT
500	if(DEBUG_GRDXT_INSERT < cycle)
501	printk("\n[%s] get current ptr2 = %x\n",
502	__FUNCTION__, (intptr_t)ptr2 );
503	#endif
504
505	// allocate memory for the missing level_2 array if required
506	if( ptr2 == NULL )
507	{
508	// allocate memory in remote cluster
509	req.type = KMEM_KCM;
510	req.order = w2 + ((sizeof(void*) == 4) ? 2 : 3 );
511	req.flags = AF_ZERO \| AF_KERNEL;
512	ptr2 = kmem_remote_alloc( rt_cxy , &req );
513
514	if( ptr2 == NULL ) return -1;
515
516	// update level_1 entry
517	hal_remote_spt( XPTR( rt_cxy , &ptr1[ix1] ) , ptr2 );
518
519	#if DEBUG_GRDXT_INSERT
520	if(DEBUG_GRDXT_INSERT < cycle)
521	printk("\n[%s] update ptr1[%d] : &ptr1[%d] = %x / ptr2 = %x\n",
522	__FUNCTION__, ix1, ix1, &ptr1[ix1], ptr2 );
523	#endif
524
525	}
526
527	// get ptr3
528	void ** ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
529
530	#if DEBUG_GRDXT_INSERT
531	if(DEBUG_GRDXT_INSERT < cycle)
532	printk("\n[%s] get current ptr3 = %x\n",
533	__FUNCTION__, (intptr_t)ptr3 );
534	#endif
535
536	// allocate memory for the missing level_3 array if required
537	if( ptr3 == NULL )
538	{
539	// allocate memory in remote cluster
540	req.type = KMEM_KCM;
541	req.order = w3 + ((sizeof(void*) == 4) ? 2 : 3 );
542	req.flags = AF_ZERO \| AF_KERNEL;
543	ptr3 = kmem_remote_alloc( rt_cxy , &req );
544
545	if( ptr3 == NULL ) return -1;
546
547	// update level_2 entry
548	hal_remote_spt( XPTR( rt_cxy , &ptr2[ix2] ) , ptr3 );
549
550	#if DEBUG_GRDXT_INSERT
551	if(DEBUG_GRDXT_INSERT < cycle)
552	printk("\n[%s] update ptr2[%d] : &ptr2[%d] %x / ptr3 %x\n",
553	__FUNCTION__, ix2, ix2, &ptr2[ix2], ptr3 );
554	#endif
555
556	}
557
558	// register value in level_3 array
559	hal_remote_spt( XPTR( rt_cxy , &ptr3[ix3] ) , value );
560
561	#if DEBUG_GRDXT_INSERT
562	if(DEBUG_GRDXT_INSERT < cycle)
563	printk("\n[%s] update ptr3[%d] : &ptr3[%d] %x / value %x\n",
564	__FUNCTION__, ix3, ix3, &ptr3[ix3], value );
565	#endif
566
567	hal_fence();
568
569	return 0;
570
571	} // end grdxt_remote_insert()
572
573	////////////////////////////////////////////
574	xptr_t grdxt_remote_remove( xptr_t rt_xp,
575	uint32_t key )
576	{
577	// get cluster and local pointer on remote rt descriptor
578	cxy_t rt_cxy = GET_CXY( rt_xp );
579	grdxt_t * rt_ptr = GET_PTR( rt_xp );
580
581	// get widths
582	uint32_t w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
583	uint32_t w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
584	uint32_t w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
585
586	// Check key value
587	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
588
589	// compute indexes
590	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
591	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
592	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
593
594	// get ptr1
595	void ** ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
596
597	// get ptr2
598	void ** ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
599	if( ptr2 == NULL ) return XPTR_NULL;
600
601	// get ptr3
602	void ** ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
603	if( ptr3 == NULL ) return XPTR_NULL;
604
605	// get value
606	void * value = hal_remote_lpt( XPTR( rt_cxy , &ptr3[ix3] ) );
607
608	// reset selected slot
609	hal_remote_spt( XPTR( rt_cxy, &ptr3[ix3] ) , NULL );
610	hal_fence();
611
612	return XPTR( rt_cxy , value );
613
614	} // end grdxt_remote_remove()
615
616	////////////////////////////////////////////
617	xptr_t grdxt_remote_lookup( xptr_t rt_xp,
618	uint32_t key )
619	{
620	// get cluster and local pointer on remote rt descriptor
621	grdxt_t * rt_ptr = GET_PTR( rt_xp );
622	cxy_t rt_cxy = GET_CXY( rt_xp );
623
624	// get widths
625	uint32_t w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
626	uint32_t w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
627	uint32_t w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
628
629	// Check key value
630	assert( __FUNCTION__, ((key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", key );
631
632	// compute indexes
633	uint32_t ix1 = key >> (w2 + w3); // index in level 1 array
634	uint32_t ix2 = (key >> w3) & ((1 << w2) -1); // index in level 2 array
635	uint32_t ix3 = key & ((1 << w3) - 1); // index in level 3 array
636
637	// get ptr1
638	void ** ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
639
640	// get ptr2
641	void ** ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
642	if( ptr2 == NULL ) return XPTR_NULL;
643
644	// get ptr3
645	void ** ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
646	if( ptr3 == NULL ) return XPTR_NULL;
647
648	// get pointer on registered item
649	void * item_ptr = hal_remote_lpt( XPTR( rt_cxy , &ptr3[ix3] ) );
650
651	// return extended pointer on registered item
652	if ( item_ptr == NULL ) return XPTR_NULL;
653	else return XPTR( rt_cxy , item_ptr );
654
655	} // end grdxt_remote_lookup()
656
657	////////////////////////////////////////////////
658	xptr_t grdxt_remote_get_first( xptr_t rt_xp,
659	uint32_t start_key,
660	uint32_t * found_key )
661	{
662	uint32_t ix1;
663	uint32_t ix2;
664	uint32_t ix3;
665
666	void ** ptr1; // local base address of remote first level array
667	void ** ptr2; // local base address of remote second level array
668	void ** ptr3; // local base address of remote third level array
669
670	// get cluster and local pointer on remote rt descriptor
671	grdxt_t * rt_ptr = GET_PTR( rt_xp );
672	cxy_t rt_cxy = GET_CXY( rt_xp );
673
674	// get widths
675	uint32_t w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
676	uint32_t w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
677	uint32_t w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
678
679	// Check key value
680	assert( __FUNCTION__, ((start_key >> (w1 + w2 + w3)) == 0 ), "illegal key value %x\n", start_key );
681
682	// compute min indexes
683	uint32_t min1 = start_key >> (w2 + w3);
684	uint32_t min2 = (start_key >> w3) & ((1 << w2) -1);
685	uint32_t min3 = start_key & ((1 << w3) - 1);
686
687	// compute max indexes
688	uint32_t max1 = 1 << w1;
689	uint32_t max2 = 1 << w2;
690	uint32_t max3 = 1 << w3;
691
692	// get ptr1
693	ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
694
695	for( ix1 = min1 ; ix1 < max1 ; ix1++ )
696	{
697	ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
698	if( ptr2 == NULL ) continue;
699
700	for( ix2 = min2 ; ix2 < max2 ; ix2++ )
701	{
702	ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
703	if( ptr3 == NULL ) continue;
704
705	for( ix3 = min3 ; ix3 < max3 ; ix3++ )
706	{
707	void * item = hal_remote_lpt( XPTR( rt_cxy , &ptr3[ix3] ) );
708
709	if( item == NULL ) continue;
710	else
711	{
712	*found_key = (ix1 << (w2+w3)) \| (ix2 << w3) \| ix3;
713	return XPTR( rt_cxy , item );
714	}
715	}
716	}
717	}
718
719	return XPTR_NULL;
720
721	} // end grdxt_remote_get_first()
722
723	/////////////////////////i/////////////////
724	void grdxt_remote_display( xptr_t rt_xp,
725	char * name )
726	{
727	uint32_t ix1;
728	uint32_t ix2;
729	uint32_t ix3;
730
731	void ** ptr1;
732	void ** ptr2;
733	void ** ptr3;
734
735	// check rt_xp
736	assert( __FUNCTION__, (rt_xp != XPTR_NULL) , "pointer on radix tree is NULL\n" );
737
738	// get cluster and local pointer on remote rt descriptor
739	grdxt_t * rt_ptr = GET_PTR( rt_xp );
740	cxy_t rt_cxy = GET_CXY( rt_xp );
741
742	// get widths
743	uint32_t w1 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix1_width ) );
744	uint32_t w2 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix2_width ) );
745	uint32_t w3 = hal_remote_l32( XPTR( rt_cxy , &rt_ptr->ix3_width ) );
746
747	ptr1 = hal_remote_lpt( XPTR( rt_cxy , &rt_ptr->root ) );
748
749	printk("\n***** Generic Radix Tree for <%s>\n", name );
750
751	for( ix1=0 ; ix1 < (uint32_t)(1<<w1) ; ix1++ )
752	{
753	ptr2 = hal_remote_lpt( XPTR( rt_cxy , &ptr1[ix1] ) );
754	if( ptr2 == NULL ) continue;
755
756	for( ix2=0 ; ix2 < (uint32_t)(1<<w2) ; ix2++ )
757	{
758	ptr3 = hal_remote_lpt( XPTR( rt_cxy , &ptr2[ix2] ) );
759	if( ptr3 == NULL ) continue;
760
761	for( ix3=0 ; ix3 < (uint32_t)(1<<w3) ; ix3++ )
762	{
763	void * value = hal_remote_lpt( XPTR( rt_cxy , &ptr3[ix3] ) );
764	if( value == NULL ) continue;
765
766	uint32_t key = (ix1<<(w2+w3)) + (ix2<<w3) + ix3;
767	printk(" - key = %x / value = %x / ptr1 = %x / ptr2 = %x / ptr3 = %x\n",
768	key, (intptr_t)value, (intptr_t)ptr1, (intptr_t)ptr2, (intptr_t)ptr3 );
769	}
770	}
771	}
772
773	} // end grdxt_remote_display()
774
775

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