Context Navigation

source: trunk/kernel/mm/vmm.c @ 39

Last change on this file since 39 was 23, checked in by alain, 7 years ago
Introduce syscalls.
File size: 42.5 KB

Line
1	/*
2	* vmm.c - virtual memory manager related operations interface.
3	*
4	* Authors Ghassan Almaless (2008,2009,2010,2011, 2012)
5	* Mohamed Lamine Karaoui (2015)
6	* Alain Greiner (2016)
7	*
8	* Copyright (c) UPMC Sorbonne Universites
9	*
10	* This file is part of ALMOS-MKH.
11	*
12	* ALMOS-MKH is free software; you can redistribute it and/or modify it
13	* under the terms of the GNU General Public License as published by
14	* the Free Software Foundation; version 2.0 of the License.
15	*
16	* ALMOS-MKH is distributed in the hope that it will be useful, but
17	* WITHOUT ANY WARRANTY; without even the implied warranty of
18	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
19	* General Public License for more details.
20	*
21	* You should have received a copy of the GNU General Public License
22	* along with ALMOS-MKH; if not, write to the Free Software Foundation,
23	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
24	*/
25
26	#include <kernel_config.h>
27	#include <hal_types.h>
28	#include <hal_special.h>
29	#include <hal_gpt.h>
30	#include <printk.h>
31	#include <memcpy.h>
32	#include <rwlock.h>
33	#include <list.h>
34	#include <bits.h>
35	#include <process.h>
36	#include <thread.h>
37	#include <vseg.h>
38	#include <cluster.h>
39	#include <scheduler.h>
40	#include <vfs.h>
41	#include <mapper.h>
42	#include <page.h>
43	#include <kmem.h>
44	#include <vmm.h>
45
46	//////////////////////////////////////////////////////////////////////////////////
47	// Extern global variables
48	//////////////////////////////////////////////////////////////////////////////////
49
50	extern process_t process_zero; // defined in cluster.c file
51
52
53	////////////////////////////////////
54	void vmm_init( process_t * process )
55	{
56	error_t error;
57	vseg_t * vseg_kentry;
58	vseg_t * vseg_args;
59	vseg_t * vseg_envs;
60	vseg_t * vseg_heap;
61	intptr_t base;
62	intptr_t size;
63
64	// get pointer on VMM
65	vmm_t * vmm = &process->vmm;
66
67	// check UTILS zone size
68	if( (CONFIG_VMM_KENTRY_SIZE + CONFIG_VMM_ARGS_SIZE + CONFIG_VMM_ENVS_SIZE ) >
69	CONFIG_VMM_ELF_BASE )
70	{
71	printk("\n[PANIC] in %s : UTILS zone too small for process %x\n",
72	__FUNCTION__ , process->pid );
73	hal_core_sleep();
74	}
75
76	// check max number of stacks slots
77	if( CONFIG_THREAD_MAX_PER_CLUSTER > 32 )
78	{
79	printk("\n[PANIC] in %s : max number of threads per cluster for a single process"
80	" cannot be larger than 32\n", __FUNCTION__ );
81	hal_core_sleep();
82	}
83
84	// check STACK zone size
85	if( (CONFIG_VMM_STACK_SIZE * CONFIG_THREAD_MAX_PER_CLUSTER) >
86	(CONFIG_VMM_VSPACE_SIZE - CONFIG_VMM_STACK_BASE) )
87	{
88	printk("\n[PANIC] in %s : STACK zone too small for process %x\n",
89	__FUNCTION__ , process->pid );
90	hal_core_sleep();
91	}
92
93	// initialize the rwlock protecting the vsegs list
94	rwlock_init( &vmm->vsegs_lock );
95
96	// initialize local list of vsegs and radix-tree
97	vmm->vsegs_nr = 0;
98	list_root_init( &vmm->vsegs_root );
99	error = grdxt_init( &vmm->grdxt,
100	CONFIG_VMM_GRDXT_W1,
101	CONFIG_VMM_GRDXT_W2,
102	CONFIG_VMM_GRDXT_W3 );
103	if( error )
104	{
105	printk("\n[PANIC] in %s : cannot initialize radix tree for process %x\n",
106	__FUNCTION__ , process->pid );
107	hal_core_sleep();
108	}
109
110	// register kentry vseg in VMM
111	base = 1 << CONFIG_PPM_PAGE_SHIFT;
112	size = CONFIG_VMM_KENTRY_SIZE << CONFIG_PPM_PAGE_SHIFT;
113	vseg_kentry = vmm_create_vseg( process , base , size , VSEG_TYPE_CODE );
114	if( vseg_kentry == NULL )
115	{
116	printk("\n[PANIC] in %s : cannot register kent vseg for process %x\n",
117	__FUNCTION__ , process->pid );
118	hal_core_sleep();
119	}
120	vmm->kent_vpn_base = 1;
121
122	// register the args vseg in VMM
123	base = (CONFIG_VMM_KENTRY_SIZE + 1 )<<CONFIG_PPM_PAGE_SHIFT;
124	size = CONFIG_VMM_ARGS_SIZE << CONFIG_PPM_PAGE_SHIFT;
125	vseg_args = vmm_create_vseg( process , base , size , VSEG_TYPE_DATA );
126	if( vseg_args == NULL )
127	{
128	printk("\n[PANIC] in %s : cannot register args vseg for process %x\n",
129	__FUNCTION__ , process->pid );
130	hal_core_sleep();
131	}
132	vmm->args_vpn_base = CONFIG_VMM_KENTRY_SIZE + 1;
133
134	// register the envs vseg in VMM
135	base = (CONFIG_VMM_KENTRY_SIZE + CONFIG_VMM_ARGS_SIZE + 1 )<<CONFIG_PPM_PAGE_SHIFT;
136	size = CONFIG_VMM_ENVS_SIZE << CONFIG_PPM_PAGE_SHIFT;
137	vseg_envs = vmm_create_vseg( process , base , size , VSEG_TYPE_DATA );
138	if( vseg_envs == NULL )
139	{
140	printk("\n[PANIC] in %s : cannot register envs vseg for process %x\n",
141	__FUNCTION__ , process->pid );
142	hal_core_sleep();
143	}
144	vmm->envs_vpn_base = CONFIG_VMM_KENTRY_SIZE + CONFIG_VMM_ARGS_SIZE + 1;
145
146	// register the heap vseg in VMM
147	base = CONFIG_VMM_HEAP_BASE << CONFIG_PPM_PAGE_SHIFT;
148	size = (CONFIG_VMM_MMAP_BASE-CONFIG_VMM_HEAP_BASE) << CONFIG_PPM_PAGE_SHIFT;
149	vseg_heap = vmm_create_vseg( process , base , size , VSEG_TYPE_HEAP );
150	if( vseg_heap == NULL )
151	{
152	printk("\n[PANIC] in %s : cannot register heap vseg in for process %x\n",
153	__FUNCTION__ , process->pid );
154	hal_core_sleep();
155	}
156	vmm->heap_vpn_base = CONFIG_VMM_HEAP_BASE;
157
158	// initialize generic page table
159	error = hal_gpt_create( &vmm->gpt );
160	if( error )
161	{
162	printk("PANIC in %s : cannot initialize page table\n", __FUNCTION__ );
163	hal_core_sleep();
164	}
165
166	// initialize STACK allocator
167	vmm->stack_mgr.bitmap = 0;
168	vmm->stack_mgr.vpn_base = CONFIG_VMM_STACK_BASE;
169
170	// initialize MMAP allocator
171	vmm->mmap_mgr.vpn_base = CONFIG_VMM_MMAP_BASE;
172	vmm->mmap_mgr.vpn_size = CONFIG_VMM_STACK_BASE - CONFIG_VMM_MMAP_BASE;
173	vmm->mmap_mgr.first_free_vpn = CONFIG_VMM_MMAP_BASE;
174	uint32_t i;
175	for( i = 0 ; i < 32 ; i++ ) list_root_init( &vmm->mmap_mgr.zombi_list[i] );
176
177	// initialize instrumentation counters
178	vmm->pgfault_nr = 0;
179	vmm->u_err_nr = 0;
180	vmm->m_err_nr = 0;
181
182	hal_wbflush();
183
184	} // end vmm_init()
185
186	//////////////////////////////////////////
187	error_t vmm_copy( process_t * dst_process,
188	process_t * src_process )
189	{
190	error_t error;
191
192	vmm_t * src_vmm = &src_process->vmm;
193	vmm_t * dst_vmm = &dst_process->vmm;
194
195	// take the src_vmm vsegs_lock
196	rwlock_wr_lock( &src_vmm->vsegs_lock );
197
198	// initialise dst_vmm vsegs_lock
199	rwlock_init( &dst_vmm->vsegs_lock );
200
201	// initialise the dst_vmm vsegs list and the radix tree
202	dst_vmm->vsegs_nr = 0;
203	list_root_init( &dst_vmm->vsegs_root );
204	error = grdxt_init( &dst_vmm->grdxt,
205	CONFIG_VMM_GRDXT_W1,
206	CONFIG_VMM_GRDXT_W2,
207	CONFIG_VMM_GRDXT_W3 );
208	if( error )
209	{
210	printk("\n[ERROR] in %s : cannot initialise radix tree for process %x\n",
211	__FUNCTION__ , dst_process->pid );
212	return ENOMEM;
213	}
214
215	// loop on src_vmm list of vsegs to create
216	// and register vsegs copies in dst_vmm
217	list_entry_t * iter;
218	vseg_t * src_vseg;
219	vseg_t * dst_vseg;
220	LIST_FOREACH( &src_vmm->vsegs_root , iter )
221	{
222	// get pointer on current src_vseg
223	src_vseg = LIST_ELEMENT( iter , vseg_t , list );
224
225	// allocate memory for a new dst_vseg
226	dst_vseg = vseg_alloc();
227
228	if( dst_vseg == NULL )
229	{
230	// release all allocated vsegs
231	LIST_FOREACH( &dst_vmm->vsegs_root , iter )
232	{
233	dst_vseg = LIST_ELEMENT( iter , vseg_t , list );
234	vseg_free( dst_vseg );
235	}
236	return ENOMEM;
237	}
238
239	// copy src_vseg to dst_vseg
240	vseg_init_from_ref( dst_vseg , XPTR( local_cxy , src_vseg ) );
241
242	// register dst_vseg in dst_vmm
243	vseg_attach( dst_vmm , dst_vseg );
244	}
245
246	// release the src_vmm vsegs_lock
247	rwlock_wr_unlock( &src_vmm->vsegs_lock );
248
249	// initialize generic page table
250	error = hal_gpt_create( &dst_vmm->gpt );
251
252	if( error )
253	{
254	printk("\n[ERROR] in %s : cannot initialize page table\n", __FUNCTION__ );
255	return ENOMEM;
256	}
257
258	// initialize STACK allocator
259	dst_vmm->stack_mgr.bitmap = 0;
260	dst_vmm->stack_mgr.vpn_base = CONFIG_VMM_STACK_BASE;
261
262	// initialize MMAP allocator
263	dst_vmm->mmap_mgr.vpn_base = CONFIG_VMM_MMAP_BASE;
264	dst_vmm->mmap_mgr.vpn_size = CONFIG_VMM_STACK_BASE - CONFIG_VMM_MMAP_BASE;
265	dst_vmm->mmap_mgr.first_free_vpn = CONFIG_VMM_MMAP_BASE;
266	uint32_t i;
267	for( i = 0 ; i < 32 ; i++ ) list_root_init( &dst_vmm->mmap_mgr.zombi_list[i] );
268
269	// initialise instrumentation counters
270	dst_vmm->pgfault_nr = 0;
271	dst_vmm->u_err_nr = 0;
272	dst_vmm->m_err_nr = 0;
273
274	// copy base addresses
275	dst_vmm->kent_vpn_base = src_vmm->kent_vpn_base;
276	dst_vmm->args_vpn_base = src_vmm->args_vpn_base;
277	dst_vmm->envs_vpn_base = src_vmm->envs_vpn_base;
278	dst_vmm->heap_vpn_base = src_vmm->heap_vpn_base;
279	dst_vmm->code_vpn_base = src_vmm->code_vpn_base;
280	dst_vmm->data_vpn_base = src_vmm->data_vpn_base;
281
282	dst_vmm->entry_point = src_vmm->entry_point;
283
284	// HEAP TODO : new heap for child ???
285	dst_vmm->heap_vseg = src_vmm->heap_vseg;
286
287	// initialize generic page table
288	error = hal_gpt_create( &dst_vmm->gpt );
289
290	if( error )
291	{
292	printk("\n[ERROR] in %s : cannot initialize page table\n", __FUNCTION__ );
293	return ENOMEM;
294	}
295
296	// copy GPT content from src_vmm to dst_vmm, activating "Copy-On-Write"
297	// TODO register Copy-On_Write in page descriptors
298	bool_t cow = true;
299	hal_gpt_copy( &dst_vmm->gpt , &src_vmm->gpt , cow );
300
301	hal_wbflush();
302
303	return 0;
304
305	} // end vmm_copy()
306
307	///////////////////////////////////////
308	void vmm_destroy( process_t * process )
309	{
310	vseg_t * vseg;
311
312	// get pointer on VMM
313	vmm_t * vmm = &process->vmm;
314
315	// get lock protecting vseg list
316	rwlock_wr_lock( &vmm->vsegs_lock );
317
318	// remove all vsegs registered in vmm
319	while( !list_is_empty( &vmm->vsegs_root ) )
320	{
321	vseg = LIST_FIRST( &vmm->vsegs_root , vseg_t , list );
322	vseg_detach( vmm , vseg );
323	vseg_free( vseg );
324	}
325
326	// delete vsegs radix_tree
327	grdxt_destroy( &vmm->grdxt );
328
329	// release lock
330	rwlock_wr_unlock(&vmm->vsegs_lock);
331
332	// remove all vsegs from zombi_lists in MMAP allocator
333	uint32_t i;
334	for( i = 0 ; i<32 ; i++ )
335	{
336	while( !list_is_empty( &vmm->mmap_mgr.zombi_list[i] ) )
337	{
338	vseg = LIST_FIRST( &vmm->mmap_mgr.zombi_list[i] , vseg_t , list );
339	vseg_detach( vmm , vseg );
340	vseg_free( vseg );
341	}
342	}
343
344	// release memory allocated to the local page table
345	hal_gpt_destroy( &vmm->gpt );
346
347	} // end vmm_destroy()
348
349	/////////////////////////////////////////////////
350	vseg_t * vmm_check_conflict( process_t * process,
351	vpn_t vpn_base,
352	vpn_t vpn_size )
353	{
354	vmm_t * vmm = &process->vmm;
355	vseg_t * vseg;
356	list_entry_t * iter;
357
358	// scan the list of registered vsegs
359	LIST_FOREACH( &vmm->vsegs_root , iter )
360	{
361	vseg = LIST_ELEMENT( iter , vseg_t , list );
362	if( ((vpn_base + vpn_size) > vseg->vpn_base) &&
363	(vpn_base < (vseg->vpn_base + vseg->vpn_size)) ) return vseg;
364	}
365	return NULL;
366	} // vmm_check_conflict()
367
368	////////////////////////////////////////////////////////////////////////////////////////////
369	// This static function is called by the vmm_create_vseg() function, and implements
370	// the VMM stack_vseg specific allocator.
371	////////////////////////////////////////////////////////////////////////////////////////////
372	// @ vmm : pointer on VMM.
373	// @ vpn_base : (return value) first allocated page
374	// @ vpn_size : (return value) number of allocated pages
375	////////////////////////////////////////////////////////////////////////////////////////////
376	static error_t vmm_stack_alloc( vmm_t * vmm,
377	vpn_t * vpn_base,
378	vpn_t * vpn_size )
379	{
380	// get stack allocator pointer
381	stack_mgr_t * mgr = &vmm->stack_mgr;
382
383	// get lock on stack allocator
384	spinlock_lock( &mgr->lock );
385
386	// get first free slot index in bitmap
387	int32_t index = bitmap_ffc( &mgr->bitmap , 4 );
388	if( (index < 0) \|\| (index > 31) ) return ENOMEM;
389
390	// update bitmap
391	bitmap_set( &mgr->bitmap , index );
392
393	// release lock on stack allocator
394	spinlock_unlock( &mgr->lock );
395
396	// returns vpn_base, vpn_size (one page non allocated)
397	vpn_base = mgr->vpn_base + index CONFIG_VMM_STACK_SIZE + 1;
398	*vpn_size = CONFIG_VMM_STACK_SIZE - 1;
399	return 0;
400
401	} // end vmm_stack_alloc()
402
403	////////////////////////////////////////////////////////////////////////////////////////////
404	// This static function is called by the vmm_create_vseg() function, and implements
405	// the VMM MMAP specific allocator.
406	////////////////////////////////////////////////////////////////////////////////////////////
407	// @ vmm : [in] pointer on VMM.
408	// @ npages : [in] requested number of pages.
409	// @ vpn_base : [out] first allocated page.
410	// @ vpn_size : [out] actual number of allocated pages.
411	////////////////////////////////////////////////////////////////////////////////////////////
412	static error_t vmm_mmap_alloc( vmm_t * vmm,
413	vpn_t npages,
414	vpn_t * vpn_base,
415	vpn_t * vpn_size )
416	{
417	uint32_t index;
418	vseg_t * vseg;
419	vpn_t base;
420	vpn_t size;
421	vpn_t free;
422
423	// mmap vseg size must be power of 2
424	// compute actual size and index in zombi_list array
425	size = POW2_ROUNDUP( npages );
426	index = bits_log2( size );
427
428	// get mmap allocator pointer
429	mmap_mgr_t * mgr = &vmm->mmap_mgr;
430
431	// get lock on mmap allocator
432	spinlock_lock( &mgr->lock );
433
434	// get vseg from zombi_list or from mmap zone
435	if( list_is_empty( &mgr->zombi_list[index] ) ) // from mmap zone
436	{
437	// check overflow
438	free = mgr->first_free_vpn;
439	if( (free + size) > mgr->vpn_size ) return ENOMEM;
440
441	// update STACK allocator
442	mgr->first_free_vpn += size;
443
444	// compute base
445	base = free;
446	}
447	else // from zombi_list
448	{
449	// get pointer on zombi vseg from zombi_list
450	vseg = LIST_FIRST( &mgr->zombi_list[index] , vseg_t , list );
451
452	// remove vseg from free-list
453	list_unlink( &vseg->list );
454
455	// compute base
456	base = vseg->vpn_base;
457	}
458
459	// release lock on mmap allocator
460	spinlock_unlock( &mgr->lock );
461
462	// returns vpn_base, vpn_size
463	*vpn_base = base;
464	*vpn_size = size;
465	return 0;
466
467	} // end vmm_mmap_alloc()
468
469	//////////////////////////////////////////////
470	vseg_t * vmm_create_vseg( process_t * process,
471	intptr_t base,
472	intptr_t size,
473	uint32_t type )
474	{
475	vseg_t * vseg; // created vseg pointer
476	vpn_t vpn_base; // vseg first page
477	vpn_t vpn_size; // number of pages
478	error_t error;
479
480	// get pointer on VMM
481	vmm_t * vmm = &process->vmm;
482
483	vmm_dmsg("\n[INFO] %s enter for process %x / base = %x / size = %x / type = %s\n",
484	__FUNCTION__ , process->pid , base , size , vseg_type_name[type] );
485
486	// compute base, size, vpn_base, vpn_size, depending on type
487	// we use the VMM specific allocators for STACK and MMAP vsegs
488	if( type == VSEG_TYPE_STACK )
489	{
490	// get vpn_base and vpn_size from STACK allocator
491	error = vmm_stack_alloc( vmm , &vpn_base , &vpn_size );
492	if( error )
493	{
494	printk("\n[ERROR] in %s : no vspace for stack vseg / process %x in cluster %x\n",
495	__FUNCTION__ , process->pid , local_cxy );
496	return NULL;
497	}
498
499	// compute vseg base and size from vpn_base and vpn_size
500	base = vpn_base << CONFIG_PPM_PAGE_SHIFT;
501	size = vpn_size << CONFIG_PPM_PAGE_SHIFT;
502	}
503	else if( (type == VSEG_TYPE_ANON) \|\|
504	(type == VSEG_TYPE_FILE) \|\|
505	(type == VSEG_TYPE_REMOTE) )
506	{
507	// get vpn_base and vpn_size from MMAP allocator
508	vpn_t npages = size >> CONFIG_PPM_PAGE_SHIFT;
509	error = vmm_mmap_alloc( vmm , npages , &vpn_base , &vpn_size );
510	if( error )
511	{
512	printk("\n[ERROR] in %s : no vspace for mmap vseg / process %x in cluster %x\n",
513	__FUNCTION__ , process->pid , local_cxy );
514	return NULL;
515	}
516
517	// compute vseg base and size from vpn_base and vpn_size
518	base = vpn_base << CONFIG_PPM_PAGE_SHIFT;
519	size = vpn_size << CONFIG_PPM_PAGE_SHIFT;
520	}
521	else
522	{
523	vpn_base = ARROUND_DOWN( base , CONFIG_PPM_PAGE_SIZE ) >> CONFIG_PPM_PAGE_SHIFT;
524	vpn_size = ARROUND_UP( base + size , CONFIG_PPM_PAGE_SIZE ) >> CONFIG_PPM_PAGE_SHIFT;
525	}
526
527	// check collisions
528	vseg = vmm_check_conflict( process , vpn_base , vpn_size );
529	if( vseg != NULL )
530	{
531	printk("\n[ERROR] in %s for process %x : new vseg [vpn_base = %x / vpn_size = %x]\n"
532	" overlap existing vseg [vpn_base = %x / vpn_size = %x]\n",
533	__FUNCTION__ , process->pid, vpn_base, vpn_size,
534	vseg->vpn_base, vseg->vpn_size );
535	return NULL;
536	}
537
538	// allocate physical memory for vseg descriptor
539	vseg = vseg_alloc();
540	if( vseg == NULL )
541	{
542	printk("\n[ERROR] in %s for process %x : cannot allocate memory for vseg\n",
543	__FUNCTION__ , process->pid );
544	return NULL;
545	}
546
547	// initialize vseg descriptor
548	vseg_init( vseg , base, size , vpn_base , vpn_size , type , local_cxy , 0 , 0 );
549
550	// update "heap_vseg" in VMM
551	process->vmm.heap_vseg = vseg;
552
553	// attach vseg to vmm
554	rwlock_wr_lock( &vmm->vsegs_lock );
555	vseg_attach( vmm , vseg );
556	rwlock_wr_unlock( &vmm->vsegs_lock );
557
558	vmm_dmsg("\n[INFO] : %s exit for process %x, vseg [%x, %x] has been mapped\n",
559	__FUNCTION__ , process->pid , vseg->min , vseg->max );
560
561	return vseg;
562
563	} // end vmm_create_vseg()
564
565	/////////////////////////////////////
566	void vmm_remove_vseg( vseg_t * vseg )
567	{
568	// get pointers on calling process and VMM
569	thread_t * this = CURRENT_THREAD;
570	process_t * process = this->process;
571	vmm_t * vmm = &this->process->vmm;
572	uint32_t type = vseg->type;
573
574	// detach vseg from VMM
575	rwlock_wr_lock( &vmm->vsegs_lock );
576	vseg_detach( &process->vmm , vseg );
577	rwlock_wr_unlock( &vmm->vsegs_lock );
578
579	// release the stack slot to VMM stack allocator if STACK type
580	if( type == VSEG_TYPE_STACK )
581	{
582	// get pointer on stack allocator
583	stack_mgr_t * mgr = &vmm->stack_mgr;
584
585	// compute slot index
586	uint32_t index = ((vseg->vpn_base - mgr->vpn_base - 1) / CONFIG_VMM_STACK_SIZE);
587
588	// update stacks_bitmap
589	spinlock_lock( &mgr->lock );
590	bitmap_clear( &mgr->bitmap , index );
591	spinlock_unlock( &mgr->lock );
592	}
593
594	// release the vseg to VMM mmap allocator if MMAP type
595	if( (type == VSEG_TYPE_ANON) \|\| (type == VSEG_TYPE_FILE) \|\| (type == VSEG_TYPE_REMOTE) )
596	{
597	// get pointer on mmap allocator
598	mmap_mgr_t * mgr = &vmm->mmap_mgr;
599
600	// compute zombi_list index
601	uint32_t index = bits_log2( vseg->vpn_size );
602
603	// update zombi_list
604	spinlock_lock( &mgr->lock );
605	list_add_first( &mgr->zombi_list[index] , &vseg->list );
606	spinlock_unlock( &mgr->lock );
607	}
608
609	// release physical memory allocated for vseg descriptor if no MMAP type
610	if( (type != VSEG_TYPE_ANON) && (type != VSEG_TYPE_FILE) && (type != VSEG_TYPE_REMOTE) )
611	{
612	vseg_free( vseg );
613	}
614
615	} // end vmm_remove_vseg()
616
617
618	//////////////////////////////////////////
619	error_t vmm_map_vseg( vseg_t * vseg,
620	uint32_t attr )
621	{
622	vpn_t vpn; // VPN of PTE to be set
623	vpn_t vpn_min; // VPN of first PTE to be set
624	vpn_t vpn_max; // VPN of last PTE to be set (excluded)
625	ppn_t ppn; // PPN of allocated physical page
626	uint32_t order; // ln( number of small pages for one single PTE )
627	page_t * page;
628	error_t error;
629
630	// check vseg type
631	uint32_t type = vseg->type;
632	if( (type != VSEG_TYPE_KCODE) && (type != VSEG_TYPE_KDATA) && (type != VSEG_TYPE_KDEV) )
633	{
634	printk("\n[PANIC] in %s : not a kernel vseg\n", __FUNCTION__ );
635	hal_core_sleep();
636	}
637
638	// get pointer on page table
639	gpt_t * gpt = &process_zero.vmm.gpt;
640
641	// define number of small pages per PTE
642	if( attr & GPT_SMALL ) order = 0; // 1 small page
643	else order = 9; // 512 small pages
644
645	// loop on pages in vseg
646	vpn_min = vseg->vpn_base;
647	vpn_max = vpn_min + vseg->vpn_size;
648	for( vpn = vpn_min ; vpn < vpn_max ; vpn++ )
649	{
650	kmem_req_t req;
651	req.type = KMEM_PAGE;
652	req.size = order;
653	req.flags = AF_KERNEL \| AF_ZERO;
654	page = (page_t *)kmem_alloc( &req );
655	if( page == NULL )
656	{
657	printk("\n[ERROR] in %s : cannot allocate physical memory\n", __FUNCTION__ );
658	return ENOMEM;
659	}
660
661	// set page table entry
662	ppn = ppm_page2ppn( page );
663	error = hal_gpt_set_pte( gpt , vpn , ppn , attr );
664	if( error )
665	{
666	printk("\n[ERROR] in %s : cannot register PPE\n", __FUNCTION__ );
667	return ENOMEM;
668	}
669	}
670
671	return 0;
672	} // end vmm_map_vseg()
673
674	/////////////////////////////////////////
675	void vmm_unmap_vseg( process_t * process,
676	vseg_t * vseg )
677	{
678	vpn_t vpn; // VPN of current PTE
679	vpn_t vpn_min; // VPN of first PTE
680	vpn_t vpn_max; // VPN of last PTE (excluded)
681
682	// get pointer on process page table
683	gpt_t * gpt = &process->vmm.gpt;
684
685	// loop on pages in vseg
686	vpn_min = vseg->vpn_base;
687	vpn_max = vpn_min + vseg->vpn_size;
688	for( vpn = vpn_min ; vpn < vpn_max ; vpn++ )
689	{
690	hal_gpt_reset_pte( gpt , vpn );
691	}
692	} // end vmm_unmap_vseg()
693
694
695	/////////////////////////////////////////////
696	error_t vmm_resize_vseg( process_t * process,
697	intptr_t base,
698	intptr_t size )
699	{
700	error_t error;
701
702	// get pointer on process VMM
703	vmm_t * vmm = &process->vmm;
704
705	intptr_t addr_min = base;
706	intptr_t addr_max = base + size;
707	uint32_t shift = CONFIG_PPM_PAGE_SHIFT;
708
709	// get pointer on vseg
710	vseg_t * vseg = grdxt_lookup( &vmm->grdxt , (uint32_t)(base >> shift) );
711
712	if( vseg == NULL) return EINVAL;
713
714	// get VMM lock protecting vsegs list
715	rwlock_wr_lock( &vmm->vsegs_lock );
716
717	if( (vseg->min > addr_min) \|\| (vseg->max < addr_max) ) // region not included in vseg
718	{
719	error = EINVAL;
720	}
721	else if( (vseg->min == addr_min) && (vseg->max == addr_max) ) // vseg must be removed
722	{
723	vmm_remove_vseg( vseg );
724	error = 0;
725	}
726	else if( vseg->min == addr_min ) // vseg must be resized
727	{
728	printk("\n[PANIC] in %s : resize not implemented yet\n", __FUNCTION__ );
729	hal_core_sleep();
730	error = 0;
731	}
732	else if( vseg->max == addr_max ) // vseg must be resized
733	{
734	printk("\n[PANIC] in %s : resize not implemented yet\n", __FUNCTION__ );
735	hal_core_sleep();
736	error = 0;
737	}
738	else // vseg cut in three regions => vseg must be resized & new vseg created
739	{
740	printk("\n[PANIC] in %s : resize not implemented yet\n", __FUNCTION__ );
741	hal_core_sleep();
742	error = 0;
743	}
744
745	// release VMM lock
746	rwlock_wr_unlock( &vmm->vsegs_lock );
747
748	return error;
749	} // end vmm_resize_vseg()
750
751	///////////////////////////////////////////
752	vseg_t * vmm_get_vseg( process_t * process,
753	intptr_t vaddr )
754	{
755
756	// get pointer on process VMM
757	vmm_t * vmm = &process->vmm;
758
759	// get lock protecting the vseg list
760	rwlock_rd_lock( &vmm->vsegs_lock );
761
762	// get pointer on vseg from radix tree
763	vseg_t * vseg = grdxt_lookup( &vmm->grdxt, (uint32_t)(vaddr >> CONFIG_PPM_PAGE_SHIFT) );
764
765	// release the lock
766	rwlock_rd_unlock( &vmm->vsegs_lock );
767
768	return vseg;
769
770	} // end vmm_get_vseg()
771
772	/////////////////////////////////////////
773	error_t vmm_get_pte( process_t * process,
774	vpn_t vpn,
775	uint32_t * ret_attr,
776	ppn_t * ret_ppn )
777	{
778	vseg_t * vseg; // pointer on vseg containing VPN
779	ppn_t ppn; // PPN from GPT entry
780	uint32_t attr; // attributes from GPT entry
781	error_t error;
782
783	// this function must be called by a thread running in the reference cluster
784	if( GET_CXY( process->ref_xp ) != local_cxy );
785	{
786	printk("\n[PANIC] in %s : not called in the reference cluster\n", __FUNCTION__ );
787	hal_core_sleep();
788	}
789
790	// get VMM pointer
791	vmm_t * vmm = &process->vmm;
792
793	// access GPT to get PTE attributes and PPN
794	hal_gpt_get_pte( &vmm->gpt , vpn , &attr , &ppn );
795
796	// if PTE unmapped => allocate one small physical page to map it
797	if( (attr & GPT_MAPPED) == 0 )
798	{
799	// get vseg pointer
800	vseg = vmm_get_vseg( process , vpn<<CONFIG_PPM_PAGE_SHIFT );
801
802	if( vseg == NULL );
803	{
804	printk("\n[ERROR] in %s : out of segment / process = %x / vpn = %x\n",
805	__FUNCTION__ , process->pid , vpn );
806	return EINVAL;
807	}
808
809	// select the target cluster for physical mapping
810	uint32_t target_cxy;
811	if( vseg->flags & VSEG_DISTRIB ) // depends on VPN LSB
812	{
813	uint32_t x_width = LOCAL_CLUSTER->x_width;
814	uint32_t y_width = LOCAL_CLUSTER->y_width;
815	target_cxy = vpn & ((1<<(x_width + y_width)) - 1);
816	}
817	else // defined in vseg descriptor
818	{
819	target_cxy = vseg->cxy;
820	}
821
822	// allocate memory for page fault
823	kmem_req_t req;
824	page_t * page;
825	if( target_cxy == local_cxy ) // target cluster is the local cluster
826	{
827	req.type = KMEM_PAGE;
828	req.size = 0;
829	req.flags = AF_NONE;
830	page = (page_t *)kmem_alloc( &req );
831
832	error = ( page == NULL ) ? 1 : 0;
833	ppn = ppm_page2ppn( page );
834	}
835	else // target cluster is not the local cluster
836	{
837	rpc_pmem_get_pages_client( target_cxy , 0 , &error , &ppn );
838	}
839
840	if( error )
841	{
842	printk("\n[ERROR] in %s : cannot allocate memory / process = %x / vpn = %x\n",
843	__FUNCTION__ , process->pid , vpn );
844	return ENOMEM;
845	}
846
847	// define GPT attributes from vseg flags
848	attr = GPT_MAPPED \| GPT_SMALL;
849	if( vseg->flags & VSEG_USER ) attr \|= GPT_USER;
850	if( vseg->flags & VSEG_WRITE ) attr \|= GPT_WRITABLE;
851	if( vseg->flags & VSEG_EXEC ) attr \|= GPT_EXECUTABLE;
852	if( vseg->flags & VSEG_CACHE ) attr \|= GPT_CACHABLE;
853
854	// set the missing PTE in local VMM
855	error = hal_gpt_set_pte( &vmm->gpt , vpn , ppn , attr );
856	if( error )
857	{
858	printk("\n[ERROR] in %s : cannot register PTE / process = %x / vpn = %x\n",
859	__FUNCTION__ , process->pid , vpn );
860	return ENOMEM;
861	}
862	}
863
864	*ret_ppn = ppn;
865	*ret_attr = attr;
866	return 0;
867	} // end vmm_get_pte()
868
869	///////////////////////////////////////////////////
870	error_t vmm_handle_page_fault( process_t * process,
871	vseg_t * vseg,
872	vpn_t vpn )
873	{
874	uint32_t attr; // missing page attributes
875	ppn_t ppn; // missing page PPN
876	error_t error; // return value
877
878	// get local VMM pointer
879	vmm_t * vmm = &process->vmm;
880
881	// get reference process cluster and local pointer
882	cxy_t ref_cxy = GET_CXY( process->ref_xp );
883	process_t * ref_ptr = (process_t *)GET_PTR( process->ref_xp );
884
885	// get missing PTE attributes and PPN
886	if( local_cxy != ref_cxy ) // local cluster is not the reference cluster
887	{
888	rpc_vmm_get_pte_client( ref_cxy , ref_ptr , vpn , &attr , &ppn , &error );
889	}
890	else // local cluster is the reference cluster
891	{
892	error = vmm_get_pte( process , vpn , &attr , &ppn );
893	}
894
895	// check page allocation error
896	if( error )
897	{
898	printk("\n[ERROR] in %s : cannot allocate memory / process = %x / vpn = %x\n",
899	__FUNCTION__ , process->pid , vpn );
900	return ENOMEM;
901	}
902
903	// set the missing PTE in local VMM
904	error = hal_gpt_set_pte( &vmm->gpt , vpn , attr , ppn );
905	if( error )
906	{
907	printk("\n[ERROR] in %s : cannot register PTE / process = %x / vpn = %x\n",
908	__FUNCTION__ , process->pid , vpn );
909	return ENOMEM;
910	}
911
912	return 0;
913	} // end vmm_handle_page_fault()
914
915	///////////////////////////////////////////
916	error_t vmm_v2p_translate( bool_t ident,
917	void * ptr,
918	paddr_t * paddr )
919	{
920	process_t * process = CURRENT_THREAD->process;
921
922	if( ident ) // identity mapping
923	{
924	*paddr = (paddr_t)PADDR( local_cxy , (lpa_t)ptr );
925	return 0;
926	}
927
928	// access page table
929	error_t error;
930	vpn_t vpn;
931	uint32_t attr;
932	ppn_t ppn;
933	uint32_t offset;
934
935	vpn = (vpn_t)( (intptr_t)ptr >> CONFIG_PPM_PAGE_SHIFT );
936	offset = (uint32_t)( ((intptr_t)ptr) & CONFIG_PPM_PAGE_MASK );
937
938	if( local_cxy == GET_CXY( process->ref_xp) ) // calling process is reference process
939	{
940	error = vmm_get_pte( process, vpn , &attr , &ppn );
941	}
942	else // use a RPC
943	{
944	cxy_t ref_cxy = GET_CXY( process->ref_xp );
945	process_t * ref_ptr = (process_t *)GET_PTR( process->ref_xp );
946	rpc_vmm_get_pte_client( ref_cxy , ref_ptr , vpn , &attr , &ppn , &error );
947	}
948
949	// set paddr
950	*paddr = (((paddr_t)ppn) << CONFIG_PPM_PAGE_SHIFT) \| offset;
951
952	return error;
953
954	} // end vmm_v2p_translate()
955
956	//////////////////////////////////////////////
957
958
959
960
961	/*
962
963	///////////////////////////////////////////////////////////////////
964	///////////////////////////////////////////////////////////////////
965	error_t vmm_inval_shared_page( vseg_t *vseg, vma_t vaddr, ppn_t ppn)
966	{
967	pmm_page_info_t current;
968	error_t err;
969
970	error= pmm_get_page(&vseg->vmm->pmm, vaddr, &current);
971
972	if((err) \|\| (current.ppn != ppn))
973	goto ended;
974
975	current.ppn = 0;
976	current.attr = 0;
977	current.cluster = NULL;
978
979	error= pmm_set_page(&vseg->vmm->pmm, vaddr, &current);
980
981	ended:
982	return err;
983	}
984
985	error_t vmm_update_shared_page( vseg_t *vseg, vma_t vaddr, ppn_t ppn)
986	{
987	pmm_page_info_t current;
988	error_t err;
989
990	error= pmm_get_page(&vseg->vmm->pmm, vaddr, &current);
991
992	if((err) \|\| (current.attr != 0))
993	goto ended;
994
995	current.ppn = ppn;
996	current.attr = vseg->vm_pgprot;
997	current.cluster = NULL; // this function is called after invalidate one
998
999	error= pmm_set_page(&vseg->vmm->pmm, vaddr , &current);
1000
1001	ended:
1002	return err;
1003	}
1004
1005	// Hypothesis: the vseg is shared-anon, mapper list is rdlocked, page is locked
1006	error_t vmm_migrate_shared_page_seq( vseg_t vseg, struct page_s page, struct page_s **new)
1007	{
1008	register vseg_t *reg;
1009	register struct process_s *process;
1010	register struct process_s *this_process;
1011	struct page_s *new_pg;
1012	struct list_entry *iter;
1013	kmem_req_t req;
1014	vma_t vaddr;
1015	ppn_t ppn;
1016	error_t err;
1017
1018	vaddr = (page->index << PMM_PAGE_SHIFT) + vseg->vm_start + vseg->vm_offset;
1019	ppn = ppm_page2ppn(page);
1020	this_process = (new == NULL) ? NULL : current_process;
1021	iter = &vseg->vm_shared_list;
1022	error = ECANCELED;
1023
1024	// Invalidate All
1025	do
1026	{
1027	reg = list_element(iter, vseg_t, vm_shared_list);
1028
1029	process = vmm_get_process(reg->vmm);
1030
1031	if(process != this_process)
1032	{
1033	error= vmm_inval_shared_page(reg, vaddr, ppn);
1034
1035	if(err) goto fail_inval;
1036	}
1037
1038	assert(vseg->vm_mapper.m_home_cid == current_cid);
1039	iter = list_next(&vseg->vm_mapper.m_reg_root, iter);
1040
1041	}while(iter != NULL);
1042
1043	req.type = KMEM_PAGE;
1044	req.size = 0;
1045	req.excep_code = AF_USER;
1046
1047	new_pg = kmem_alloc(&req);
1048	*new = new_pg;
1049
1050	if(new_pg == NULL)
1051	{
1052	error= ENOMEM;
1053	goto fail_alloc;
1054	}
1055
1056	page_copy(new_pg, page);
1057
1058	page_lock(new_pg);
1059
1060	new_pg->mapper = page->mapper;
1061	new_pg->index = page->index;
1062
1063	// TODO: do the complet job regading dirty page
1064	if(PAGE_IS(page, PG_DIRTY))
1065	PAGE_SET(new_pg, PG_DIRTY);
1066
1067	ppn = ppm_page2ppn(new_pg);
1068	iter = &vseg->vm_shared_list;
1069
1070	// Update All
1071	do
1072	{
1073	reg = list_element(iter, vseg_t, vm_shared_list);
1074
1075	process = vmm_get_process(reg->vmm);
1076
1077	if(process != this_process)
1078	(void) vmm_update_shared_page(reg, vaddr, ppn);
1079
1080	assert(vseg->vm_mapper.m_home_cid == current_cid);
1081	iter = list_next(&vseg->vm_mapper.m_reg_root, iter);
1082
1083
1084	}while(iter != NULL);
1085
1086	page_unlock(new_pg);
1087
1088	fail_alloc:
1089	fail_inval:
1090	return err;
1091	}
1092
1093	//TODO: revisit all manipulation of the page->refcount
1094	///////////////////////////////////////////////////////////////
1095	static inline error_t vmm_do_migrate( vseg_t * vseg,
1096	pmm_page_info_t * pinfo,
1097	uint32_t vaddr )
1098	{
1099	kmem_req_t req;
1100	pmm_page_info_t current;
1101	page_t * newpage;
1102	cluster_t * cluster;
1103	thread_t * this;
1104	error_t err;
1105	ppn_t ppn;
1106
1107	assert( pinfo->ppn != 0 );
1108
1109	ppn = pinfo->ppn;
1110	this = current_thread;
1111	newpage = NULL;
1112	cluster = current_cluster;
1113
1114	current.attr = 0;
1115	current.ppn = 0;
1116
1117	error= pmm_lock_page(&vseg->vmm->pmm, vaddr, &current);
1118
1119	if(error\|\| (current.isAtomic == false) \|\|
1120	(current.ppn != ppn) \|\| !(current.attr & PMM_MIGRATE))
1121	{
1122	#if CONFIG_SHOW_SPURIOUS_PGFAULT
1123	printk(INFO, "%s: pid %d, tid %d, cpu %d, nothing to do for vaddr %x\n",
1124	__FUNCTION__,
1125	this->process->pid,
1126	this->info.order,
1127	cpu_get_id(),
1128	vaddr);
1129	#endif
1130	this->info.spurious_pgfault_cntr ++;
1131	pmm_unlock_page(&vseg->vmm->pmm, vaddr, &current);
1132	pmm_tlb_flush_vaddr(vaddr, PMM_DATA);
1133	return 0;
1134	}
1135
1136	if(!ppn_is_local(ppn))
1137	{
1138	req.type = KMEM_PAGE;
1139	req.size = 0;
1140	req.excep_code = AF_PGFAULT;
1141
1142	newpage = kmem_alloc(&req);
1143
1144	if(newpage)
1145	{
1146	newpage->mapper = NULL;//?
1147	ppn_copy(ppm_page2ppn(newpage), ppn);
1148
1149	if(current.attr & PMM_COW)
1150	{
1151	current.attr \|= PMM_WRITE;
1152	current.attr &= ~(PMM_COW);
1153	}
1154
1155	current.ppn = ppm_page2ppn(newpage);
1156	}
1157	}
1158
1159	current.attr \|= PMM_PRESENT;
1160	current.attr &= ~(PMM_MIGRATE);
1161	current.attr &= ~(PMM_LOCKED);
1162	current.cluster = NULL;
1163
1164	//also unlock the table entry
1165	error= pmm_set_page(&vseg->vmm->pmm, vaddr, &current);
1166
1167	if(err)
1168	{
1169	// TODO: we should differ the kmem_free call
1170	//page_unlock(page);
1171	(void)pmm_unlock_page(&vseg->vmm->pmm, vaddr, &current);
1172	req.ptr = newpage;
1173	kmem_free(&req);
1174	return err;
1175	}
1176
1177
1178	if(newpage)
1179	{
1180	ppn_refcount_down(ppn);
1181	current_thread->info.remote_pages_cntr ++;
1182	#if CONFIG_SHOW_REMOTE_PGALLOC
1183	printk(INFO, "%s: pid %d, tid %x, cpu %d, cid %d: got new remote page from cluster %d (vaddr %x)\n",
1184	__FUNCTION__,
1185	current_process->pid,
1186	current_thread,
1187	cpu_get_id(),
1188	cluster->id,
1189	newpage->cid,
1190	vaddr);
1191	#endif
1192	}
1193
1194	#if CONFIG_SHOW_VMMMGRT_MSG
1195	printk(INFO, "%s: pid %d, tid %d, cpu %d: Asked to migrate page (vaddr %x) from cluster %d to cluster %d, error%d\n",
1196	__FUNCTION__,
1197	current_process->pid,
1198	current_thread->info.order,
1199	cpu_get_id(),
1200	vaddr,
1201	ppn_ppn2cid(ppn),
1202	cluster->id,
1203	err);
1204	#endif
1205
1206	return err;
1207	}
1208
1209	error_t vmm_do_cow( vseg_t vseg, pmm_page_info_t pinfo, uint32_t vaddr)
1210	{
1211	register struct page_s *newpage;
1212	register struct page_s *page;
1213	register struct thread_s *this;
1214	register error_t err;
1215	register uint32_t count;
1216	register bool_t isCountDown;
1217	pmm_page_info_t old;
1218	pmm_page_info_t new;
1219	kmem_req_t req;
1220
1221	this = current_thread;
1222	old.attr = 0;
1223	newpage = NULL;
1224	isCountDown = true;
1225
1226	vmm_dmsg(2,"%s: pid %d, tid %d, cpu %d, vaddr %x\n",
1227	__FUNCTION__,
1228	this->process->pid,
1229	this->info.order,
1230	cpu_get_id(),
1231	vaddr);
1232
1233
1234	error= pmm_lock_page(&vseg->vmm->pmm, vaddr, &old);
1235
1236	//TODO: check this condition
1237	if(error\|\| (old.isAtomic == false) \|\| !(old.attr & PMM_COW))
1238	{
1239	#if CONFIG_SHOW_SPURIOUS_PGFAULT
1240	printk(INFO, "%s: pid %d, tid %d, cpu %d, nothing to do for vaddr %x\n",
1241	__FUNCTION__,
1242	this->process->pid,
1243	this->info.order,
1244	cpu_get_id(),
1245	vaddr);
1246	#endif
1247	this->info.spurious_pgfault_cntr ++;
1248	pmm_tlb_flush_vaddr(vaddr, PMM_DATA);
1249	pmm_unlock_page(&vseg->vmm->pmm, vaddr, &old);
1250	return err;
1251	//goto VMM_COW_END;
1252	}
1253
1254	//if the ppn is local and the others (processus with wich we share the page)
1255	//has done cow, then use the old.ppn directly
1256	if(ppn_is_local(old.ppn))
1257	{
1258	page = ppm_ppn2page(&current_cluster->ppm, old.ppn);
1259
1260	if(page->mapper == NULL)
1261	{
1262	count = page_refcount_get(page);
1263	if(count == 1)
1264	{
1265	newpage = page;//don't copy the page. use it directly.
1266	isCountDown = false;
1267	vmm_dmsg(2, "%s: pid %d, tid %d, cpu %d, reuse same page for vaddr %x, pg_addr %x\n",
1268	__FUNCTION__,
1269	this->process->pid,
1270	this->info.order,
1271	cpu_get_id(),
1272	vaddr,
1273	ppm_page2addr(page));
1274	}
1275	}
1276	//else: we need to do the cow even if it's local!
1277
1278	}
1279
1280	//else: alocate newpage and copy the data from the remote node
1281	//also defcount down the ppn
1282	if(newpage == NULL)
1283	{
1284	req.type = KMEM_PAGE;
1285	req.size = 0;
1286	req.excep_code = AF_PGFAULT;
1287
1288	if((newpage = kmem_alloc(&req)) == NULL)
1289	{
1290	(void)pmm_unlock_page(&vseg->vmm->pmm, vaddr, &old);
1291	return ENOMEM;
1292	}
1293
1294	newpage->mapper = NULL;
1295
1296	ppn_copy(ppm_page2ppn(newpage), old.ppn);
1297	assert(isCountDown);
1298
1299	vmm_dmsg(2,
1300	"%s: pid %d, tid %d, cpu %d, newpage for vaddr %x, pg_addr %x\n",
1301	__FUNCTION__,
1302	this->process->pid,
1303	this->info.order,
1304	cpu_get_id(),
1305	vaddr,
1306	ppm_page2addr(newpage));
1307
1308	if(newpage->cid != current_cid)
1309	this->info.remote_pages_cntr ++;
1310	}
1311
1312	new.attr = vseg->vm_pgprot \| PMM_WRITE;
1313	new.attr &= ~(PMM_COW \| PMM_MIGRATE);
1314	new.ppn = ppm_page2ppn(newpage);
1315	new.cluster = NULL;
1316
1317	//this also unlock the table entry (if no error)
1318	error= pmm_set_page(&vseg->vmm->pmm, vaddr, &new);
1319
1320	if(err)
1321	{
1322	(void)pmm_unlock_page(&vseg->vmm->pmm, vaddr, &old);
1323	req.ptr = newpage;
1324	kmem_free(&req);
1325	vmm_dmsg(3, "%s: ended [ error%d ]\n", __FUNCTION__, err);
1326	return err;
1327	}
1328
1329	if(isCountDown) ppn_refcount_down(old.ppn);
1330
1331	vmm_dmsg(2, "%s, pid %d, tid %d, cpu %d, COW ended [vaddr %x]\n",
1332	__FUNCTION__,
1333	this->process->pid,
1334	this->info.order,
1335	cpu_get_id(),
1336	vaddr);
1337
1338	return 0;
1339	}
1340
1341
1342	//refcount is taken on the file at mmap
1343	static inline error_t vmm_do_mapped( vseg_t *vseg, uint32_t vaddr, uint32_t excep_code)
1344	{
1345	ppn_t ppn;
1346	error_t err;
1347	uint32_t index;
1348	bool_t isDone;
1349	pmm_page_info_t info;
1350	pmm_page_info_t current;
1351	struct thread_s *this;
1352
1353	this = current_thread;
1354
1355	current.attr = 1;
1356	current.ppn = 1;
1357	isDone = false;
1358
1359	error= pmm_lock_page(&vseg->vmm->pmm, vaddr, &current);
1360
1361	if(err) return err;
1362
1363	if((current.isAtomic == false) \|\| (current.attr != 0))
1364	{
1365	#if CONFIG_SHOW_SPURIOUS_PGFAULT
1366	printk(INFO, "%s: pid %d, tid %d, cpu %d, nothing to do for vaddr %x\n",
1367	__FUNCTION__,
1368	this->process->pid,
1369	this->info.order,
1370	cpu_get_id(),
1371	vaddr);
1372	#endif
1373	this->info.spurious_pgfault_cntr ++;
1374	pmm_tlb_flush_vaddr(vaddr, PMM_DATA);
1375	return 0;
1376	}
1377
1378	index = ((vaddr - vseg->vm_start) + vseg->vm_offset) >> PMM_PAGE_SHIFT;
1379
1380	//also hold a refcount!
1381	ppn = mapper_get_ppn(&vseg->vm_mapper,
1382	index,
1383	MAPPER_SYNC_OP);
1384
1385	if(!ppn)
1386	{
1387	error= pmm_unlock_page(&vseg->vmm->pmm, vaddr, &current);
1388	assert(!err); //FIXME: liberate the ppn ...
1389	return (VFS_FILE_IS_NULL(vseg->vm_file)) ? EIO : ENOMEM;
1390	}
1391
1392	info.attr = vseg->vm_pgprot;
1393	info.ppn = ppn;
1394	info.cluster = NULL;
1395
1396	//also unlock the page
1397	error= pmm_set_page(&vseg->vmm->pmm, vaddr, &info);
1398
1399	assert(!err);//FIXME: liberate the ppn and unlock the table entry ...
1400	//error= pmm_unlock_page(&vseg->vmm->pmm, vaddr, &current);
1401
1402	return err;
1403	}
1404
1405	/////////////////////////////////////////////////////
1406	static inline error_t vmm_do_aod( vseg_t *vseg, uint32_t vaddr)
1407	{
1408	register error_t err;
1409	register struct page_s *page;
1410	register struct cluster_s *cluster;
1411	struct thread_s *this;
1412	pmm_page_info_t old;
1413	pmm_page_info_t new;
1414	kmem_req_t req;
1415
1416	page = NULL;
1417	old.attr = 0;
1418	this = current_thread;
1419
1420	error= pmm_lock_page(&vseg->vmm->pmm, vaddr, &old);
1421
1422	if(err) return err;
1423
1424	if(old.isAtomic == false)
1425	{
1426	this->info.spurious_pgfault_cntr ++;
1427	pmm_tlb_flush_vaddr(vaddr, PMM_DATA);
1428	return 0;
1429	}
1430
1431	req.type = KMEM_PAGE;
1432	req.size = 0;
1433	req.excep_code = AF_PGFAULT \| AF_ZERO;
1434
1435	if((page = kmem_alloc(&req)) == NULL)
1436	{
1437	(void)pmm_unlock_page(&vseg->vmm->pmm, vaddr, &old);
1438	return ENOMEM;
1439	}
1440
1441	page->mapper = NULL;
1442
1443	new.attr = vseg->vm_pgprot;
1444	new.ppn = ppm_page2ppn(page);
1445	new.cluster = NULL;
1446
1447	error= pmm_set_page(&vseg->vmm->pmm, vaddr, &new);
1448
1449	if(err) goto fail_set_pg;
1450
1451	cluster = current_cluster;
1452
1453	if(page->cid != cluster->id)
1454	this->info.remote_pages_cntr ++;
1455
1456	return 0;
1457
1458	fail_set_pg:
1459	(void)pmm_unlock_page(&vseg->vmm->pmm, vaddr, &old);
1460	req.ptr = page;
1461	kmem_free(&req);
1462
1463	vmm_dmsg(3, "%s: ended [ error%d ]\n", __FUNCTION__, err);
1464	return err;
1465	}
1466
1467	VSEGION_PAGE_FAULT(vmm_default_pagefault)
1468	{
1469	register struct thread_s *this;
1470	register error_t err;
1471	pmm_page_info_t info;
1472
1473	if((error= pmm_get_page(&vseg->vmm->pmm, vaddr, &info)))
1474	return err;
1475
1476	if((info.attr != 0) && (info.ppn != 0))
1477	{
1478	if((info.attr & PMM_COW) && pmm_except_isWrite(excep_code))
1479	{
1480	error= vmm_do_cow(vseg, &info, vaddr);
1481	return err;
1482	}
1483
1484	if(info.attr & PMM_MIGRATE)
1485	return vmm_do_migrate(vseg, &info, vaddr);
1486
1487	if(info.attr & PMM_PRESENT)
1488	{
1489	this = current_thread;
1490
1491	#if CONFIG_SHOW_SPURIOUS_PGFAULT
1492	printk(WARNING, "WARNING: %s: pid %d, tid %d, cpu %d, excep_code %x but vaddr is valid %x, attr %x, ppn %x\n",
1493	__FUNCTION__,
1494	this->process->pid,
1495	this->info.order,
1496	cpu_get_id(),
1497	excep_code,
1498	vaddr,
1499	info.attr,
1500	info.ppn);
1501	#endif
1502
1503	current_thread->info.spurious_pgfault_cntr ++;
1504	pmm_tlb_flush_vaddr(vaddr, PMM_UNKNOWN);
1505	return 0;
1506	}
1507
1508	current_thread->info.spurious_pgfault_cntr ++;
1509	pmm_tlb_flush_vaddr(vaddr, PMM_UNKNOWN);
1510	return 0;
1511	#if 0
1512	#if CONFIG_SHOW_VMM_ERROR_MSG
1513	printk(ERROR,
1514	"ERROR: %s: pid %d, cpu %d, Unexpected page attributes configuration for vaddr %x, found: ppn %x, attr %x\n",
1515	__FUNCTION__,
1516	current_process->pid,
1517	cpu_get_id(),
1518	vaddr,
1519	info.ppn,
1520	info.attr);
1521	#endif
1522
1523	return EPERM;
1524	#endif
1525	}
1526
1527	if(!MAPPER_IS_NULL(vseg->vm_mapper))
1528	return vmm_do_mapped(vseg, vaddr, excep_code);
1529
1530	return vmm_do_aod(vseg, vaddr);
1531	}
1532
1533	*/
1534
1535

Note: See TracBrowser for help on using the repository browser.

Download in other formats: