1 | /* |
---|
2 | * vmm.h - virtual memory management related operations |
---|
3 | * |
---|
4 | * Authors Ghassan Almaless (2008,2009,2010,2011, 2012) |
---|
5 | * Alain Greiner (2016,2017,2018,2019,2020)) |
---|
6 | * |
---|
7 | * Copyright (c) UPMC Sorbonne Universites |
---|
8 | * |
---|
9 | * This file is part of ALMOS-MKH. |
---|
10 | * |
---|
11 | * ALMOS-MKH is free software; you can redistribute it and/or modify it |
---|
12 | * under the terms of the GNU General Public License as published by |
---|
13 | * the Free Software Foundation; version 2.0 of the License. |
---|
14 | * |
---|
15 | * ALMOS-MKH is distributed in the hope that it will be useful, but |
---|
16 | * WITHOUT ANY WARRANTY; without even the implied warranty of |
---|
17 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
---|
18 | * General Public License for more details. |
---|
19 | * |
---|
20 | * You should have received a copy of the GNU General Public License |
---|
21 | * along with ALMOS-MKH; if not, write to the Free Software Foundation, |
---|
22 | * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA |
---|
23 | */ |
---|
24 | |
---|
25 | #ifndef _VMM_H_ |
---|
26 | #define _VMM_H_ |
---|
27 | |
---|
28 | #include <hal_kernel_types.h> |
---|
29 | #include <bits.h> |
---|
30 | #include <list.h> |
---|
31 | #include <queuelock.h> |
---|
32 | #include <remote_queuelock.h> |
---|
33 | #include <hal_gpt.h> |
---|
34 | #include <vseg.h> |
---|
35 | #include <page.h> |
---|
36 | |
---|
37 | /**** Forward declarations ****/ |
---|
38 | |
---|
39 | struct process_s; |
---|
40 | struct vseg_s; |
---|
41 | |
---|
42 | /********************************************************************************************* |
---|
43 | * This structure defines the STACK allocator used by the VMM to dynamically handle |
---|
44 | * vseg allocation or release requests for an user thread. |
---|
45 | * This allocator handles a fixed size array of fixed size slots in STACK zone of user space. |
---|
46 | * The stack size and the number of slots are defined by the CONFIG_VMM_STACK_SIZE, and |
---|
47 | * CONFIG_VMM_STACK_BASE parameters. |
---|
48 | * Each slot can contain one user stack vseg. The first 4 Kbytes page in the slot is not |
---|
49 | * mapped to detect stack overflow. |
---|
50 | * In this implementation, the slot index is defined by the user thead LTID. |
---|
51 | * All allocated stacks are registered in a bitmap defining the STACK zone state: |
---|
52 | * - The allocator checks that the requested slot has not been already allocated, and set the |
---|
53 | * corresponding bit in the bitmap. |
---|
54 | * - The de-allocator reset the corresponding bit in the bitmap. |
---|
55 | ********************************************************************************************/ |
---|
56 | |
---|
57 | typedef struct stack_mgr_s |
---|
58 | { |
---|
59 | busylock_t lock; /*! lock protecting STACK allocator */ |
---|
60 | vpn_t vpn_base; /*! first page of STACK zone */ |
---|
61 | bitmap_t bitmap; /*! bit vector of allocated stacks */ |
---|
62 | } |
---|
63 | stack_mgr_t; |
---|
64 | |
---|
65 | /********************************************************************************************* |
---|
66 | * This structure defines the MMAP allocator used by the VMM to dynamically handle MMAP vsegs |
---|
67 | * requested or released by an user process. It must be called in the reference cluster. |
---|
68 | * - allocation policy : |
---|
69 | * This allocator implements the buddy algorithm. All allocated vsegs occupy an integer |
---|
70 | * number of pages, that is power of 2, and are aligned (vpn_base is multiple of vpn_size). |
---|
71 | * The requested number of pages is rounded if required. The global allocator state is |
---|
72 | * completely defined by the free_pages_root[] array indexed by the vseg order. |
---|
73 | * These free lists are local, but are implemented as xlist because we use the existing |
---|
74 | * vseg.xlist to register a free vseg in its free list. |
---|
75 | * - release policy : |
---|
76 | * A released vseg is recursively merged with the "buddy" vseg when it is free, in |
---|
77 | * order to build the largest possible aligned free vsegs. The resulting vseg.vpn_size |
---|
78 | * field is updated. |
---|
79 | * Implementation note: |
---|
80 | * The only significant (and documented) fiels in the vsegs registered in the MMAP allocator |
---|
81 | * free lists are "xlist", "vpn_base", and "vpn_size". |
---|
82 | ********************************************************************************************/ |
---|
83 | |
---|
84 | typedef struct mmap_mgr_s |
---|
85 | { |
---|
86 | busylock_t lock; /*! lock protecting MMAP allocator */ |
---|
87 | vpn_t vpn_base; /*! first page of MMAP zone */ |
---|
88 | vpn_t vpn_size; /*! number of pages in MMAP zone */ |
---|
89 | xlist_entry_t free_list_root[CONFIG_VMM_HEAP_MAX_ORDER + 1]; /* roots of free lists */ |
---|
90 | } |
---|
91 | mmap_mgr_t; |
---|
92 | |
---|
93 | /********************************************************************************************* |
---|
94 | * This structure defines the Virtual Memory Manager for a given process in a given cluster. |
---|
95 | * This local VMM implements four main services: |
---|
96 | * 1) It contains the local copy of vseg list (VSL), only complete in referrence. |
---|
97 | * 2) It contains the local copy of the generic page table (GPT), only complete in reference. |
---|
98 | * 3) The stack manager dynamically allocates virtual memory space for the STACK vsegs. |
---|
99 | * 4) The mmap manager dynamically allocates virtual memory for the (FILE/ANON/REMOTE) vsegs. |
---|
100 | ******************************************************a************************************** |
---|
101 | * Implementation notes: |
---|
102 | * 1. In most clusters, the VSL and GPT are only partial copies of the reference VSL and GPT |
---|
103 | * structures, stored in the reference cluster. |
---|
104 | * 2. The VSL contains only local vsegs, but it is implemented as an xlist, and protected by |
---|
105 | * a remote_rwlock, because it can be accessed by a thread running in a remote cluster. |
---|
106 | * An example is the vmm_fork_copy() function. |
---|
107 | * 3. The GPT in the reference cluster can be directly accessed by remote threads to handle |
---|
108 | * false page-fault (page is mapped in the reference GPT, but the PTE copy is missing |
---|
109 | * in the local GPT). As each PTE can be protected by a specific GPT_LOCKED attribute |
---|
110 | * for exclusive access, it is NOT protected by a global lock. |
---|
111 | ********************************************************************************************/ |
---|
112 | |
---|
113 | typedef struct vmm_s |
---|
114 | { |
---|
115 | remote_queuelock_t vsl_lock; /*! lock protecting the local VSL */ |
---|
116 | xlist_entry_t vsegs_root; /*! Virtual Segment List root */ |
---|
117 | uint32_t vsegs_nr; /*! total number of local vsegs */ |
---|
118 | |
---|
119 | gpt_t gpt; /*! Generic Page Table descriptor */ |
---|
120 | |
---|
121 | stack_mgr_t stack_mgr; /*! embedded STACK vsegs allocator */ |
---|
122 | |
---|
123 | mmap_mgr_t mmap_mgr; /*! embedded MMAP vsegs allocator */ |
---|
124 | |
---|
125 | uint32_t false_pgfault_nr; /*! false page fault counter (for all threads) */ |
---|
126 | uint32_t local_pgfault_nr; /*! false page fault counter (for all threads) */ |
---|
127 | uint32_t global_pgfault_nr; /*! false page fault counter (for all threads) */ |
---|
128 | uint32_t false_pgfault_cost; /*! cumulated cost (for all threads) */ |
---|
129 | uint32_t local_pgfault_cost; /*! cumulated cost (for all threads) */ |
---|
130 | uint32_t global_pgfault_cost; /*! cumulated cost (for all threads) */ |
---|
131 | |
---|
132 | vpn_t args_vpn_base; /*! args vseg first page */ |
---|
133 | vpn_t envs_vpn_base; /*! envs vseg first page */ |
---|
134 | vpn_t code_vpn_base; /*! code vseg first page */ |
---|
135 | vpn_t data_vpn_base; /*! data vseg first page */ |
---|
136 | vpn_t heap_vpn_base; /*! heap zone first page */ |
---|
137 | |
---|
138 | intptr_t entry_point; /*! main thread entry point */ |
---|
139 | } |
---|
140 | vmm_t; |
---|
141 | |
---|
142 | /********************************************************************************************* |
---|
143 | * This function makes only a partial initialisation of the VMM attached to an user |
---|
144 | * process: It intializes the STACK and MMAP allocators, and the VSL lock. |
---|
145 | * - The GPT has been previously created, with the hal_gpt_create() function. |
---|
146 | * - The "kernel" vsegs are previously registered, by the hal_vmm_kernel_update() function. |
---|
147 | * - The "code" and "data" vsegs arlmmmmmme registered by the elf_load_process() function. |
---|
148 | * - The "stack" vsegs are dynamically registered by the thread_user_create() function. |
---|
149 | * - The "file", "anon", "remote" vsegs are dynamically registered by the mmap() syscall. |
---|
150 | ********************************************************************************************* |
---|
151 | * @ process : pointer on process descriptor |
---|
152 | * @ return 0 if success / return -1 if failure. |
---|
153 | ********************************************************************************************/ |
---|
154 | error_t vmm_user_init( struct process_s * process ); |
---|
155 | |
---|
156 | /********************************************************************************************* |
---|
157 | * This function re-initialises the VMM attached to an user process to prepare a new |
---|
158 | * call to the vmm_user_init() function after an exec() syscall. |
---|
159 | * It removes from the VMM of the process identified by the <process> argument all |
---|
160 | * all user vsegs, by calling the vmm_remove_vseg() function. |
---|
161 | * - the vsegs are removed from the VSL. |
---|
162 | * - the corresponding GPT entries are removed from the GPT. |
---|
163 | * - the physical pages are released to the relevant kmem when they are not shared. |
---|
164 | * The VSL and the GPT are not modified for the kernel vsegs. |
---|
165 | ********************************************************************************************* |
---|
166 | * @ process : pointer on process descriptor. |
---|
167 | ********************************************************************************************/ |
---|
168 | void vmm_user_reset( struct process_s * process ); |
---|
169 | |
---|
170 | /********************************************************************************************* |
---|
171 | * This function is called by the process_make_fork() function. It partially copies |
---|
172 | * the content of a remote parent process VMM to the local child process VMM: |
---|
173 | * - The KERNEL vsegs required by the architecture must have been previously |
---|
174 | * created in the child VMM, using the hal_vmm_kernel_update() function. |
---|
175 | * - The DATA, ANON, REMOTE vsegs registered in the parent VSL are registered in the |
---|
176 | * child VSL. All valid PTEs in parent GPT are copied to the child GPT. |
---|
177 | * The WRITABLE and COW flags are not modified, as it will be done later for those |
---|
178 | * shared pages by the vmm_set_cow() function. |
---|
179 | * - The CODE vsegs registered in the parent VSL are registered in the child VSL, but the |
---|
180 | * GPT entries are not copied in the child GPT, and will be dynamically updated from |
---|
181 | * the .elf file when a page fault is reported. |
---|
182 | * - The FILE vsegs registered in the parent VSL are registered in the child VSL, and all |
---|
183 | * valid GPT entries in parent GPT are copied to the child GPT. The COW flag is not set. |
---|
184 | * - No STACK vseg is copied from parent VMM to child VMM: the child stack vseg is copied |
---|
185 | * later from the cluster containing the user thread requesting the fork(). |
---|
186 | ********************************************************************************************* |
---|
187 | * @ child_process : local pointer on local child process descriptor. |
---|
188 | * @ parent_process_xp : extended pointer on remote parent process descriptor. |
---|
189 | * @ return 0 if success / return -1 if failure. |
---|
190 | ********************************************************************************************/ |
---|
191 | error_t vmm_fork_copy( struct process_s * child_process, |
---|
192 | xptr_t parent_process_xp ); |
---|
193 | |
---|
194 | /********************************************************************************************* |
---|
195 | * This function is called by the process_make_fork() function to update the COW attribute |
---|
196 | * in the parent parent process vsegs. It set the COW flag, and reset the WRITABLE flag of |
---|
197 | * all GPT entries of the DATA, MMAP, and REMOTE vsegs of the <process> argument. |
---|
198 | * It must be called by a thread running in the reference cluster, that contains the complete |
---|
199 | * VSL and GPT (use the rpc_vmm_set_cow_client() when the calling thread client is remote). |
---|
200 | * It updates all copies of the process in all clusters, to maintain coherence in GPT copies, |
---|
201 | * using the list of copies stored in the owner process, and using remote_write accesses to |
---|
202 | * update the remote GPTs. It atomically increment the pending_fork counter, in all involved |
---|
203 | * physical page descriptors. It cannot fail, as only mapped entries in GPTs are updated. |
---|
204 | ********************************************************************************************* |
---|
205 | * @ process : local pointer on local reference process descriptor. |
---|
206 | ********************************************************************************************/ |
---|
207 | void vmm_set_cow( struct process_s * process ); |
---|
208 | |
---|
209 | /********************************************************************************************* |
---|
210 | * This function modifies the vseg identified by <process> and <base> arguments in all |
---|
211 | * clusters containing a VSL copy, as defined by <new_base> and <new_size> arguments. |
---|
212 | * The new vseg, defined by the <new_base> and <new_size> arguments must be included |
---|
213 | * in the existing vseg. The target VSL size and base fields are modified in the VSL. |
---|
214 | * This is done in all clusters containing a VMM copy to maintain VMM coherence. |
---|
215 | * It is called by the sys_munmap() and dev_fbf_resize_window() functions. |
---|
216 | * It can be called by a thread running in any cluster, as it uses the vmm_resize_vseg() in |
---|
217 | * the local cluster, and parallel RPC_VMM_RESIZE_VSEG for remote clusters. |
---|
218 | * It cannot fail, as only vseg registered in VSL copies are updated. |
---|
219 | ********************************************************************************************* |
---|
220 | * @ process : local pointer on process descriptor. |
---|
221 | * @ base : current vseg base address in user space. |
---|
222 | * @ new_base : new vseg base. |
---|
223 | * @ new_size : new vseg size. |
---|
224 | ********************************************************************************************/ |
---|
225 | void vmm_global_resize_vseg( struct process_s * process, |
---|
226 | intptr_t base, |
---|
227 | intptr_t new_base, |
---|
228 | intptr_t new_size ); |
---|
229 | |
---|
230 | /********************************************************************************************* |
---|
231 | * This function removes the vseg identified by the <process> and <base> arguments from |
---|
232 | * the VSL and remove all associated PTE entries from the GPT. |
---|
233 | * This is done in all clusters containing a VMM copy to maintain VMM coherence. |
---|
234 | * It is called by the sys_munmap() and dev_fbf_resize_window() functions. |
---|
235 | * It can be called by a thread running in any cluster, as it uses the vmm_remove_vseg() in |
---|
236 | * the local cluster, and parallel RPC_VMM_REMOVE_VSEG for remote clusters. |
---|
237 | * It cannot fail, as only vseg registered in VSL copies are deleted. |
---|
238 | ********************************************************************************************* |
---|
239 | * @ pid : local pointer on process identifier. |
---|
240 | * @ base : vseg base address in user space. |
---|
241 | ********************************************************************************************/ |
---|
242 | void vmm_global_delete_vseg( struct process_s * process, |
---|
243 | intptr_t base ); |
---|
244 | |
---|
245 | /********************************************************************************************* |
---|
246 | * This function modifies one GPT entry identified by the <process> and <vpn> arguments |
---|
247 | * in all clusters containing a process copy. It maintains coherence in GPT copies, |
---|
248 | * using remote_write accesses. |
---|
249 | * It cannot fail, as only mapped PTE2 in GPT copies are updated. |
---|
250 | ********************************************************************************************* |
---|
251 | * @ process : local pointer on local process descriptor. |
---|
252 | * @ vpn : PTE index. |
---|
253 | * @ attr : PTE / attributes. |
---|
254 | * @ ppn : PTE / physical page index. |
---|
255 | ********************************************************************************************/ |
---|
256 | void vmm_global_update_pte( struct process_s * process, |
---|
257 | vpn_t vpn, |
---|
258 | uint32_t attr, |
---|
259 | ppn_t ppn ); |
---|
260 | |
---|
261 | /********************************************************************************************* |
---|
262 | * This function deletes, in the local cluster, all vsegs registered in the VSL |
---|
263 | * of the process identified by the <process> argument. For each vseg: |
---|
264 | * - it unmaps all vseg PTEs from the GPT (release the physical pages when required). |
---|
265 | * - it removes the vseg from the local VSL. |
---|
266 | * - it releases the memory allocated to the local vseg descriptors. |
---|
267 | * - it releases the memory allocated to the GPT itself. |
---|
268 | ********************************************************************************************* |
---|
269 | * @ process : pointer on process descriptor. |
---|
270 | ********************************************************************************************/ |
---|
271 | void vmm_destroy( struct process_s * process ); |
---|
272 | |
---|
273 | /********************************************************************************************* |
---|
274 | * This function scans the list of vsegs registered in the VMM of a given process descriptor |
---|
275 | * to check if a given virtual region (defined by a base and size) overlap an existing vseg. |
---|
276 | ********************************************************************************************* |
---|
277 | * @ process : pointer on process descriptor. |
---|
278 | * @ base : region virtual base address. |
---|
279 | * @ size : region size (bytes). |
---|
280 | * @ returns NULL if no conflict / return conflicting vseg pointer if conflict. |
---|
281 | ********************************************************************************************/ |
---|
282 | vseg_t * vmm_check_conflict( struct process_s * process, |
---|
283 | vpn_t base, |
---|
284 | vpn_t size ); |
---|
285 | |
---|
286 | /********************************************************************************************* |
---|
287 | * This function allocates memory for a vseg descriptor, initialises it, and register it |
---|
288 | * in the VSL of the local process descriptor. |
---|
289 | * - For the FILE, ANON, & REMOTE types, it does not use the <base> argument, but uses |
---|
290 | * the specific VMM MMAP allocator. |
---|
291 | * - For the STACK type, it does not use the <base> and <size> arguments, but uses the |
---|
292 | * the specific VMM STACK allocator. |
---|
293 | * It checks collision with pre-existing vsegs. |
---|
294 | * To comply with the "on-demand" paging policy, this function does NOT modify the GPT, |
---|
295 | * and does not allocate physical memory for vseg data. |
---|
296 | * It should be called by a local thread (could be a RPC thread if the client thread is not |
---|
297 | * running in the reference cluster). |
---|
298 | ********************************************************************************************* |
---|
299 | * @ process : pointer on local processor descriptor. |
---|
300 | * @ type : vseg type. |
---|
301 | * @ base : vseg base address (or user thread ltid for an user stack vseg). |
---|
302 | * @ size : vseg size (bytes). |
---|
303 | * @ file_offset : offset in file for CODE, DATA, FILE types. |
---|
304 | * @ file_size : can be smaller than "size" for DATA type. |
---|
305 | * @ mapper_xp : extended pointer on mapper for CODE, DATA, FILE types. |
---|
306 | * @ cxy : physical mapping cluster (for non distributed vsegs). |
---|
307 | * @ returns pointer on vseg if success / returns NULL if no memory, or conflict. |
---|
308 | ********************************************************************************************/ |
---|
309 | vseg_t * vmm_create_vseg( struct process_s * process, |
---|
310 | vseg_type_t type, |
---|
311 | intptr_t base, |
---|
312 | uint32_t size, |
---|
313 | uint32_t file_offset, |
---|
314 | uint32_t file_size, |
---|
315 | xptr_t mapper_xp, |
---|
316 | cxy_t cxy ); |
---|
317 | |
---|
318 | /********************************************************************************************* |
---|
319 | * This function removes from the VMM of a local process descriptor, identified by |
---|
320 | * the <process> argument, the vseg identified by the <vseg> argument. |
---|
321 | * It is called by the vmm_user_reset(), vmm_global_delete_vseg(), vmm_destroy() functions. |
---|
322 | * It must be called by a local thread, running in the cluster containing the modified VMM. |
---|
323 | * Use the RPC_VMM_REMOVE_VSEG if required. |
---|
324 | * It makes a kernel panic if the process is not registered in the local cluster. |
---|
325 | * For all vseg types, the vseg is detached from local VSL, and all associated PTEs are |
---|
326 | * unmapped from local GPT. Other actions depend on the vseg type: |
---|
327 | * Regarding the vseg descriptor release: |
---|
328 | * . for ANON and REMOTE, the vseg is not released, but registered in local zombi_list. |
---|
329 | * . for STACK the vseg is released to the local stack allocator. |
---|
330 | * . for all other types, the vseg descriptor is released to the local kmem. |
---|
331 | * Regarding the physical pages release: |
---|
332 | * . for KERNEL and FILE, the pages are not released to kmem. |
---|
333 | * . for CODE and STACK, the pages are released to local kmem. |
---|
334 | * . for DATA, ANON and REMOTE, the pages are released to relevant kmem only when |
---|
335 | * the local cluster is the reference cluster. |
---|
336 | * The VSL lock protecting the VSL must be taken by the caller. |
---|
337 | ********************************************************************************************* |
---|
338 | * @ process : local pointer on process descriptor. |
---|
339 | * @ vseg : local pointer on target vseg. |
---|
340 | ********************************************************************************************/ |
---|
341 | void vmm_remove_vseg( struct process_s * process, |
---|
342 | struct vseg_s * vseg ); |
---|
343 | |
---|
344 | /********************************************************************************************* |
---|
345 | * This function resize a local vseg identified by the <process> and <vseg> arguments. |
---|
346 | * Both the "size" and "base" fields are modified in the process VSL. When the new vseg |
---|
347 | * contains less pages than the target vseg, the relevant pages are removed from the GPT. |
---|
348 | * It is called by the vmm_global_resize() and dev_fbf_resize_window() functions. |
---|
349 | * It must be called by a local thread, running in the cluster containing the modified VSL. |
---|
350 | * Use the RPC_VMM_RESIZE_VSEG if required. |
---|
351 | * The VSL lock protecting the VSL must be taken by the caller. |
---|
352 | ********************************************************************************************* |
---|
353 | * @ process : local pointer on process descriptor |
---|
354 | * @ vseg : local pointer on target vseg |
---|
355 | * @ new_base : vseg base address |
---|
356 | * @ new_size : vseg size (bytes) |
---|
357 | ********************************************************************************************/ |
---|
358 | void vmm_resize_vseg( struct process_s * process, |
---|
359 | struct vseg_s * vseg, |
---|
360 | intptr_t new_base, |
---|
361 | intptr_t new_size ); |
---|
362 | |
---|
363 | /********************************************************************************************* |
---|
364 | * This function checks that a given virtual address <vaddr> in a given <process> is |
---|
365 | * contained in a registered vseg. It can be called by any thread running in any cluster. |
---|
366 | * - if the vseg is registered in the local process VSL, it returns the local vseg pointer. |
---|
367 | * - if the vseg is missing in local VSL, it access directly the reference VSL. |
---|
368 | * - if the vseg is found in reference VSL, it updates the local VSL and returns this pointer. |
---|
369 | * It returns an error when the vseg is missing in the reference VMM, or when there is |
---|
370 | * not enough memory for a new vseg descriptor in the calling thread cluster. |
---|
371 | * For both the local and the reference VSL, it takes the VSL lock before scanning the VSL. |
---|
372 | ********************************************************************************************* |
---|
373 | * @ process : [in] pointer on process descriptor. |
---|
374 | * @ vaddr : [in] virtual address. |
---|
375 | * @ vseg : [out] local pointer on local vseg. |
---|
376 | * @ returns 0 if success / returns -1 if user error |
---|
377 | ********************************************************************************************/ |
---|
378 | error_t vmm_get_vseg( struct process_s * process, |
---|
379 | intptr_t vaddr, |
---|
380 | vseg_t ** vseg ); |
---|
381 | |
---|
382 | /********************************************************************************************* |
---|
383 | * This function is called by the generic exception handler in case of page-fault event, |
---|
384 | * detected for a given <vpn>. The <process> argument is used to access the relevant VMM. |
---|
385 | * It checks the missing VPN and returns an user error if it is not in a registered vseg. |
---|
386 | * For a legal VPN, there is actually 3 cases: |
---|
387 | * 1) if the missing VPN belongs to a private vseg (STACK or CODE segment types, non |
---|
388 | * replicated in all clusters), it allocates a new physical page, computes the attributes, |
---|
389 | * depending on vseg type, and updates directly the local GPT. |
---|
390 | * 2) if the missing VPN belongs to a public vseg, it can be a false page-fault, when the VPN |
---|
391 | * is mapped in the reference GPT, but not in the local GPT. For this false page-fault, |
---|
392 | * the local GPT is simply updated from the reference GPT. |
---|
393 | * 3) if the missing VPN is public, and unmapped in the ref GPT, it is a true page fault. |
---|
394 | * The calling thread allocates a new physical page, computes the attributes, depending |
---|
395 | * on vseg type, and updates directly (without RPC) the local GPT and the reference GPT. |
---|
396 | * Other GPT copies will updated on demand. |
---|
397 | * Concurrent accesses to the GPT(s) are handled, by locking the target PTE before accessing |
---|
398 | * the local and/or reference GPT(s). |
---|
399 | ********************************************************************************************* |
---|
400 | * @ process : local pointer on local process. |
---|
401 | * @ vpn : VPN of the missing PTE. |
---|
402 | * @ returns EXCP_NON_FATAL / EXCP_USER_ERROR / EXCP_KERNEL_PANIC after analysis |
---|
403 | ********************************************************************************************/ |
---|
404 | error_t vmm_handle_page_fault( struct process_s * process, |
---|
405 | vpn_t vpn ); |
---|
406 | |
---|
407 | /********************************************************************************************* |
---|
408 | * This function is called by the generic exception handler in case of WRITE violation event, |
---|
409 | * detected for a given <vpn>. The <process> argument is used to access the relevant VMM. |
---|
410 | * It returns a kernel panic if the faulty VPN is not in a registered vseg, or is not mapped. |
---|
411 | * For a legal mapped vseg there is two cases: |
---|
412 | * 1) If the missing VPN belongs to a private vseg (STACK), it access only the local GPT. |
---|
413 | * It access the forks counter in the current physical page descriptor. |
---|
414 | * If there is a pending fork, it allocates a new physical page from the cluster defined |
---|
415 | * by the vseg type, copies the old physical page content to the new physical page, |
---|
416 | * and decrements the pending_fork counter in old physical page descriptor. |
---|
417 | * Finally, it reset the COW flag and set the WRITE flag in local GPT. |
---|
418 | * 2) If the missing VPN is public, it access only the reference GPT. |
---|
419 | * It access the forks counter in the current physical page descriptor. |
---|
420 | * If there is a pending fork, it allocates a new physical page from the cluster defined |
---|
421 | * by the vseg type, copies the old physical page content to the new physical page, |
---|
422 | * and decrements the pending_fork counter in old physical page descriptor. |
---|
423 | * Finally it calls the vmm_global_update_pte() function to reset the COW flag and set |
---|
424 | * the WRITE flag in all the GPT copies, using a RPC if the reference cluster is remote. |
---|
425 | * In both cases, concurrent accesses to the GPT are handled by locking the target PTE |
---|
426 | * before accessing the GPT. |
---|
427 | ********************************************************************************************* |
---|
428 | * @ process : pointer on local process descriptor copy. |
---|
429 | * @ vpn : VPN of the faulting PTE. |
---|
430 | * @ returns EXCP_NON_FATAL / EXCP_USER_ERROR / EXCP_KERNEL_PANIC after analysis |
---|
431 | ********************************************************************************************/ |
---|
432 | error_t vmm_handle_cow( struct process_s * process, |
---|
433 | vpn_t vpn ); |
---|
434 | |
---|
435 | /********************************************************************************************* |
---|
436 | * This function is called by the vmm_get_pte() function when a page is unmapped. |
---|
437 | * Depending on the vseg type, defined by the <vseg> argument, it returns the PPN |
---|
438 | * (Physical Page Number) associated to a missing page defined by the <vpn> argument. |
---|
439 | * - For the FILE type, it returns directly the physical page from the file mapper. |
---|
440 | * - For the CODE and DATA types, it allocates a new physical page from the cluster defined |
---|
441 | * by the <vseg->cxy> field, or by the <vpn> MSB bits for a distributed vseg, |
---|
442 | * and initialize this page from the .elf file mapper. |
---|
443 | * - For all other types, it allocates a new physical page from the cluster defined |
---|
444 | * by the <vseg->cxy> field, or by the <vpn> MSB bits for a distributed vseg, |
---|
445 | * but the new page is not initialized. |
---|
446 | ********************************************************************************************* |
---|
447 | * @ vseg : local pointer on vseg containing the mising page. |
---|
448 | * @ vpn : Virtual Page Number identifying the missing page. |
---|
449 | * @ ppn : [out] returned Physical Page Number. |
---|
450 | * return 0 if success / return EINVAL or ENOMEM if error. |
---|
451 | ********************************************************************************************/ |
---|
452 | error_t vmm_get_one_ppn( vseg_t * vseg, |
---|
453 | vpn_t vpn, |
---|
454 | ppn_t * ppn ); |
---|
455 | |
---|
456 | #endif /* _VMM_H_ */ |
---|