1 /*
2 * Copyright 2017 Red Hat Inc.
3 *
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
10 *
11 * The above copyright notice and this permission notice shall be included in
12 * all copies or substantial portions of the Software.
13 *
14 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
15 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
16 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
17 * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
18 * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
19 * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
20 * OTHER DEALINGS IN THE SOFTWARE.
21 */
22 #define NVKM_VMM_LEVELS_MAX 5
23 #include "vmm.h"
24
25 #include <subdev/fb.h>
26
27 static void
nvkm_vmm_pt_del(struct nvkm_vmm_pt ** ppgt)28 nvkm_vmm_pt_del(struct nvkm_vmm_pt **ppgt)
29 {
30 struct nvkm_vmm_pt *pgt = *ppgt;
31 if (pgt) {
32 kvfree(pgt->pde);
33 kfree(pgt);
34 *ppgt = NULL;
35 }
36 }
37
38
39 static struct nvkm_vmm_pt *
nvkm_vmm_pt_new(const struct nvkm_vmm_desc * desc,bool sparse,const struct nvkm_vmm_page * page)40 nvkm_vmm_pt_new(const struct nvkm_vmm_desc *desc, bool sparse,
41 const struct nvkm_vmm_page *page)
42 {
43 const u32 pten = 1 << desc->bits;
44 struct nvkm_vmm_pt *pgt;
45 u32 lpte = 0;
46
47 if (desc->type > PGT) {
48 if (desc->type == SPT) {
49 const struct nvkm_vmm_desc *pair = page[-1].desc;
50 lpte = pten >> (desc->bits - pair->bits);
51 } else {
52 lpte = pten;
53 }
54 }
55
56 if (!(pgt = kzalloc(sizeof(*pgt) + lpte, GFP_KERNEL)))
57 return NULL;
58 pgt->page = page ? page->shift : 0;
59 pgt->sparse = sparse;
60
61 if (desc->type == PGD) {
62 pgt->pde = kvcalloc(pten, sizeof(*pgt->pde), GFP_KERNEL);
63 if (!pgt->pde) {
64 kfree(pgt);
65 return NULL;
66 }
67 }
68
69 return pgt;
70 }
71
72 struct nvkm_vmm_iter {
73 const struct nvkm_vmm_page *page;
74 const struct nvkm_vmm_desc *desc;
75 struct nvkm_vmm *vmm;
76 u64 cnt;
77 u16 max, lvl;
78 u32 pte[NVKM_VMM_LEVELS_MAX];
79 struct nvkm_vmm_pt *pt[NVKM_VMM_LEVELS_MAX];
80 int flush;
81 };
82
83 #ifdef CONFIG_NOUVEAU_DEBUG_MMU
84 static const char *
nvkm_vmm_desc_type(const struct nvkm_vmm_desc * desc)85 nvkm_vmm_desc_type(const struct nvkm_vmm_desc *desc)
86 {
87 switch (desc->type) {
88 case PGD: return "PGD";
89 case PGT: return "PGT";
90 case SPT: return "SPT";
91 case LPT: return "LPT";
92 default:
93 return "UNKNOWN";
94 }
95 }
96
97 static void
nvkm_vmm_trace(struct nvkm_vmm_iter * it,char * buf)98 nvkm_vmm_trace(struct nvkm_vmm_iter *it, char *buf)
99 {
100 int lvl;
101 for (lvl = it->max; lvl >= 0; lvl--) {
102 if (lvl >= it->lvl)
103 buf += sprintf(buf, "%05x:", it->pte[lvl]);
104 else
105 buf += sprintf(buf, "xxxxx:");
106 }
107 }
108
109 #define TRA(i,f,a...) do { \
110 char _buf[NVKM_VMM_LEVELS_MAX * 7]; \
111 struct nvkm_vmm_iter *_it = (i); \
112 nvkm_vmm_trace(_it, _buf); \
113 VMM_TRACE(_it->vmm, "%s "f, _buf, ##a); \
114 } while(0)
115 #else
116 #define TRA(i,f,a...)
117 #endif
118
119 static inline void
nvkm_vmm_flush_mark(struct nvkm_vmm_iter * it)120 nvkm_vmm_flush_mark(struct nvkm_vmm_iter *it)
121 {
122 it->flush = min(it->flush, it->max - it->lvl);
123 }
124
125 static inline void
nvkm_vmm_flush(struct nvkm_vmm_iter * it)126 nvkm_vmm_flush(struct nvkm_vmm_iter *it)
127 {
128 if (it->flush != NVKM_VMM_LEVELS_MAX) {
129 if (it->vmm->func->flush) {
130 TRA(it, "flush: %d", it->flush);
131 it->vmm->func->flush(it->vmm, it->flush);
132 }
133 it->flush = NVKM_VMM_LEVELS_MAX;
134 }
135 }
136
137 static void
nvkm_vmm_unref_pdes(struct nvkm_vmm_iter * it)138 nvkm_vmm_unref_pdes(struct nvkm_vmm_iter *it)
139 {
140 const struct nvkm_vmm_desc *desc = it->desc;
141 const int type = desc[it->lvl].type == SPT;
142 struct nvkm_vmm_pt *pgd = it->pt[it->lvl + 1];
143 struct nvkm_vmm_pt *pgt = it->pt[it->lvl];
144 struct nvkm_mmu_pt *pt = pgt->pt[type];
145 struct nvkm_vmm *vmm = it->vmm;
146 u32 pdei = it->pte[it->lvl + 1];
147
148 /* Recurse up the tree, unreferencing/destroying unneeded PDs. */
149 it->lvl++;
150 if (--pgd->refs[0]) {
151 const struct nvkm_vmm_desc_func *func = desc[it->lvl].func;
152 /* PD has other valid PDEs, so we need a proper update. */
153 TRA(it, "PDE unmap %s", nvkm_vmm_desc_type(&desc[it->lvl - 1]));
154 pgt->pt[type] = NULL;
155 if (!pgt->refs[!type]) {
156 /* PDE no longer required. */
157 if (pgd->pt[0]) {
158 if (pgt->sparse) {
159 func->sparse(vmm, pgd->pt[0], pdei, 1);
160 pgd->pde[pdei] = NVKM_VMM_PDE_SPARSE;
161 } else {
162 func->unmap(vmm, pgd->pt[0], pdei, 1);
163 pgd->pde[pdei] = NULL;
164 }
165 } else {
166 /* Special handling for Tesla-class GPUs,
167 * where there's no central PD, but each
168 * instance has its own embedded PD.
169 */
170 func->pde(vmm, pgd, pdei);
171 pgd->pde[pdei] = NULL;
172 }
173 } else {
174 /* PDE was pointing at dual-PTs and we're removing
175 * one of them, leaving the other in place.
176 */
177 func->pde(vmm, pgd, pdei);
178 }
179
180 /* GPU may have cached the PTs, flush before freeing. */
181 nvkm_vmm_flush_mark(it);
182 nvkm_vmm_flush(it);
183 } else {
184 /* PD has no valid PDEs left, so we can just destroy it. */
185 nvkm_vmm_unref_pdes(it);
186 }
187
188 /* Destroy PD/PT. */
189 TRA(it, "PDE free %s", nvkm_vmm_desc_type(&desc[it->lvl - 1]));
190 nvkm_mmu_ptc_put(vmm->mmu, vmm->bootstrapped, &pt);
191 if (!pgt->refs[!type])
192 nvkm_vmm_pt_del(&pgt);
193 it->lvl--;
194 }
195
196 static void
nvkm_vmm_unref_sptes(struct nvkm_vmm_iter * it,struct nvkm_vmm_pt * pgt,const struct nvkm_vmm_desc * desc,u32 ptei,u32 ptes)197 nvkm_vmm_unref_sptes(struct nvkm_vmm_iter *it, struct nvkm_vmm_pt *pgt,
198 const struct nvkm_vmm_desc *desc, u32 ptei, u32 ptes)
199 {
200 const struct nvkm_vmm_desc *pair = it->page[-1].desc;
201 const u32 sptb = desc->bits - pair->bits;
202 const u32 sptn = 1 << sptb;
203 struct nvkm_vmm *vmm = it->vmm;
204 u32 spti = ptei & (sptn - 1), lpti, pteb;
205
206 /* Determine how many SPTEs are being touched under each LPTE,
207 * and drop reference counts.
208 */
209 for (lpti = ptei >> sptb; ptes; spti = 0, lpti++) {
210 const u32 pten = min(sptn - spti, ptes);
211 pgt->pte[lpti] -= pten;
212 ptes -= pten;
213 }
214
215 /* We're done here if there's no corresponding LPT. */
216 if (!pgt->refs[0])
217 return;
218
219 for (ptei = pteb = ptei >> sptb; ptei < lpti; pteb = ptei) {
220 /* Skip over any LPTEs that still have valid SPTEs. */
221 if (pgt->pte[pteb] & NVKM_VMM_PTE_SPTES) {
222 for (ptes = 1, ptei++; ptei < lpti; ptes++, ptei++) {
223 if (!(pgt->pte[ptei] & NVKM_VMM_PTE_SPTES))
224 break;
225 }
226 continue;
227 }
228
229 /* As there's no more non-UNMAPPED SPTEs left in the range
230 * covered by a number of LPTEs, the LPTEs once again take
231 * control over their address range.
232 *
233 * Determine how many LPTEs need to transition state.
234 */
235 pgt->pte[ptei] &= ~NVKM_VMM_PTE_VALID;
236 for (ptes = 1, ptei++; ptei < lpti; ptes++, ptei++) {
237 if (pgt->pte[ptei] & NVKM_VMM_PTE_SPTES)
238 break;
239 pgt->pte[ptei] &= ~NVKM_VMM_PTE_VALID;
240 }
241
242 if (pgt->pte[pteb] & NVKM_VMM_PTE_SPARSE) {
243 TRA(it, "LPTE %05x: U -> S %d PTEs", pteb, ptes);
244 pair->func->sparse(vmm, pgt->pt[0], pteb, ptes);
245 } else
246 if (pair->func->invalid) {
247 /* If the MMU supports it, restore the LPTE to the
248 * INVALID state to tell the MMU there is no point
249 * trying to fetch the corresponding SPTEs.
250 */
251 TRA(it, "LPTE %05x: U -> I %d PTEs", pteb, ptes);
252 pair->func->invalid(vmm, pgt->pt[0], pteb, ptes);
253 }
254 }
255 }
256
257 static bool
nvkm_vmm_unref_ptes(struct nvkm_vmm_iter * it,bool pfn,u32 ptei,u32 ptes)258 nvkm_vmm_unref_ptes(struct nvkm_vmm_iter *it, bool pfn, u32 ptei, u32 ptes)
259 {
260 const struct nvkm_vmm_desc *desc = it->desc;
261 const int type = desc->type == SPT;
262 struct nvkm_vmm_pt *pgt = it->pt[0];
263 bool dma;
264
265 if (pfn) {
266 /* Need to clear PTE valid bits before we dma_unmap_page(). */
267 dma = desc->func->pfn_clear(it->vmm, pgt->pt[type], ptei, ptes);
268 if (dma) {
269 /* GPU may have cached the PT, flush before unmap. */
270 nvkm_vmm_flush_mark(it);
271 nvkm_vmm_flush(it);
272 desc->func->pfn_unmap(it->vmm, pgt->pt[type], ptei, ptes);
273 }
274 }
275
276 /* Drop PTE references. */
277 pgt->refs[type] -= ptes;
278
279 /* Dual-PTs need special handling, unless PDE becoming invalid. */
280 if (desc->type == SPT && (pgt->refs[0] || pgt->refs[1]))
281 nvkm_vmm_unref_sptes(it, pgt, desc, ptei, ptes);
282
283 /* PT no longer neeed? Destroy it. */
284 if (!pgt->refs[type]) {
285 it->lvl++;
286 TRA(it, "%s empty", nvkm_vmm_desc_type(desc));
287 it->lvl--;
288 nvkm_vmm_unref_pdes(it);
289 return false; /* PTE writes for unmap() not necessary. */
290 }
291
292 return true;
293 }
294
295 static void
nvkm_vmm_ref_sptes(struct nvkm_vmm_iter * it,struct nvkm_vmm_pt * pgt,const struct nvkm_vmm_desc * desc,u32 ptei,u32 ptes)296 nvkm_vmm_ref_sptes(struct nvkm_vmm_iter *it, struct nvkm_vmm_pt *pgt,
297 const struct nvkm_vmm_desc *desc, u32 ptei, u32 ptes)
298 {
299 const struct nvkm_vmm_desc *pair = it->page[-1].desc;
300 const u32 sptb = desc->bits - pair->bits;
301 const u32 sptn = 1 << sptb;
302 struct nvkm_vmm *vmm = it->vmm;
303 u32 spti = ptei & (sptn - 1), lpti, pteb;
304
305 /* Determine how many SPTEs are being touched under each LPTE,
306 * and increase reference counts.
307 */
308 for (lpti = ptei >> sptb; ptes; spti = 0, lpti++) {
309 const u32 pten = min(sptn - spti, ptes);
310 pgt->pte[lpti] += pten;
311 ptes -= pten;
312 }
313
314 /* We're done here if there's no corresponding LPT. */
315 if (!pgt->refs[0])
316 return;
317
318 for (ptei = pteb = ptei >> sptb; ptei < lpti; pteb = ptei) {
319 /* Skip over any LPTEs that already have valid SPTEs. */
320 if (pgt->pte[pteb] & NVKM_VMM_PTE_VALID) {
321 for (ptes = 1, ptei++; ptei < lpti; ptes++, ptei++) {
322 if (!(pgt->pte[ptei] & NVKM_VMM_PTE_VALID))
323 break;
324 }
325 continue;
326 }
327
328 /* As there are now non-UNMAPPED SPTEs in the range covered
329 * by a number of LPTEs, we need to transfer control of the
330 * address range to the SPTEs.
331 *
332 * Determine how many LPTEs need to transition state.
333 */
334 pgt->pte[ptei] |= NVKM_VMM_PTE_VALID;
335 for (ptes = 1, ptei++; ptei < lpti; ptes++, ptei++) {
336 if (pgt->pte[ptei] & NVKM_VMM_PTE_VALID)
337 break;
338 pgt->pte[ptei] |= NVKM_VMM_PTE_VALID;
339 }
340
341 if (pgt->pte[pteb] & NVKM_VMM_PTE_SPARSE) {
342 const u32 spti = pteb * sptn;
343 const u32 sptc = ptes * sptn;
344 /* The entire LPTE is marked as sparse, we need
345 * to make sure that the SPTEs are too.
346 */
347 TRA(it, "SPTE %05x: U -> S %d PTEs", spti, sptc);
348 desc->func->sparse(vmm, pgt->pt[1], spti, sptc);
349 /* Sparse LPTEs prevent SPTEs from being accessed. */
350 TRA(it, "LPTE %05x: S -> U %d PTEs", pteb, ptes);
351 pair->func->unmap(vmm, pgt->pt[0], pteb, ptes);
352 } else
353 if (pair->func->invalid) {
354 /* MMU supports blocking SPTEs by marking an LPTE
355 * as INVALID. We need to reverse that here.
356 */
357 TRA(it, "LPTE %05x: I -> U %d PTEs", pteb, ptes);
358 pair->func->unmap(vmm, pgt->pt[0], pteb, ptes);
359 }
360 }
361 }
362
363 static bool
nvkm_vmm_ref_ptes(struct nvkm_vmm_iter * it,bool pfn,u32 ptei,u32 ptes)364 nvkm_vmm_ref_ptes(struct nvkm_vmm_iter *it, bool pfn, u32 ptei, u32 ptes)
365 {
366 const struct nvkm_vmm_desc *desc = it->desc;
367 const int type = desc->type == SPT;
368 struct nvkm_vmm_pt *pgt = it->pt[0];
369
370 /* Take PTE references. */
371 pgt->refs[type] += ptes;
372
373 /* Dual-PTs need special handling. */
374 if (desc->type == SPT)
375 nvkm_vmm_ref_sptes(it, pgt, desc, ptei, ptes);
376
377 return true;
378 }
379
380 static void
nvkm_vmm_sparse_ptes(const struct nvkm_vmm_desc * desc,struct nvkm_vmm_pt * pgt,u32 ptei,u32 ptes)381 nvkm_vmm_sparse_ptes(const struct nvkm_vmm_desc *desc,
382 struct nvkm_vmm_pt *pgt, u32 ptei, u32 ptes)
383 {
384 if (desc->type == PGD) {
385 while (ptes--)
386 pgt->pde[ptei++] = NVKM_VMM_PDE_SPARSE;
387 } else
388 if (desc->type == LPT) {
389 memset(&pgt->pte[ptei], NVKM_VMM_PTE_SPARSE, ptes);
390 }
391 }
392
393 static bool
nvkm_vmm_sparse_unref_ptes(struct nvkm_vmm_iter * it,bool pfn,u32 ptei,u32 ptes)394 nvkm_vmm_sparse_unref_ptes(struct nvkm_vmm_iter *it, bool pfn, u32 ptei, u32 ptes)
395 {
396 struct nvkm_vmm_pt *pt = it->pt[0];
397 if (it->desc->type == PGD)
398 memset(&pt->pde[ptei], 0x00, sizeof(pt->pde[0]) * ptes);
399 else
400 if (it->desc->type == LPT)
401 memset(&pt->pte[ptei], 0x00, sizeof(pt->pte[0]) * ptes);
402 return nvkm_vmm_unref_ptes(it, pfn, ptei, ptes);
403 }
404
405 static bool
nvkm_vmm_sparse_ref_ptes(struct nvkm_vmm_iter * it,bool pfn,u32 ptei,u32 ptes)406 nvkm_vmm_sparse_ref_ptes(struct nvkm_vmm_iter *it, bool pfn, u32 ptei, u32 ptes)
407 {
408 nvkm_vmm_sparse_ptes(it->desc, it->pt[0], ptei, ptes);
409 return nvkm_vmm_ref_ptes(it, pfn, ptei, ptes);
410 }
411
412 static bool
nvkm_vmm_ref_hwpt(struct nvkm_vmm_iter * it,struct nvkm_vmm_pt * pgd,u32 pdei)413 nvkm_vmm_ref_hwpt(struct nvkm_vmm_iter *it, struct nvkm_vmm_pt *pgd, u32 pdei)
414 {
415 const struct nvkm_vmm_desc *desc = &it->desc[it->lvl - 1];
416 const int type = desc->type == SPT;
417 struct nvkm_vmm_pt *pgt = pgd->pde[pdei];
418 const bool zero = !pgt->sparse && !desc->func->invalid;
419 struct nvkm_vmm *vmm = it->vmm;
420 struct nvkm_mmu *mmu = vmm->mmu;
421 struct nvkm_mmu_pt *pt;
422 u32 pten = 1 << desc->bits;
423 u32 pteb, ptei, ptes;
424 u32 size = desc->size * pten;
425
426 pgd->refs[0]++;
427
428 pgt->pt[type] = nvkm_mmu_ptc_get(mmu, size, desc->align, zero);
429 if (!pgt->pt[type]) {
430 it->lvl--;
431 nvkm_vmm_unref_pdes(it);
432 return false;
433 }
434
435 if (zero)
436 goto done;
437
438 pt = pgt->pt[type];
439
440 if (desc->type == LPT && pgt->refs[1]) {
441 /* SPT already exists covering the same range as this LPT,
442 * which means we need to be careful that any LPTEs which
443 * overlap valid SPTEs are unmapped as opposed to invalid
444 * or sparse, which would prevent the MMU from looking at
445 * the SPTEs on some GPUs.
446 */
447 for (ptei = pteb = 0; ptei < pten; pteb = ptei) {
448 bool spte = pgt->pte[ptei] & NVKM_VMM_PTE_SPTES;
449 for (ptes = 1, ptei++; ptei < pten; ptes++, ptei++) {
450 bool next = pgt->pte[ptei] & NVKM_VMM_PTE_SPTES;
451 if (spte != next)
452 break;
453 }
454
455 if (!spte) {
456 if (pgt->sparse)
457 desc->func->sparse(vmm, pt, pteb, ptes);
458 else
459 desc->func->invalid(vmm, pt, pteb, ptes);
460 memset(&pgt->pte[pteb], 0x00, ptes);
461 } else {
462 desc->func->unmap(vmm, pt, pteb, ptes);
463 while (ptes--)
464 pgt->pte[pteb++] |= NVKM_VMM_PTE_VALID;
465 }
466 }
467 } else {
468 if (pgt->sparse) {
469 nvkm_vmm_sparse_ptes(desc, pgt, 0, pten);
470 desc->func->sparse(vmm, pt, 0, pten);
471 } else {
472 desc->func->invalid(vmm, pt, 0, pten);
473 }
474 }
475
476 done:
477 TRA(it, "PDE write %s", nvkm_vmm_desc_type(desc));
478 it->desc[it->lvl].func->pde(it->vmm, pgd, pdei);
479 nvkm_vmm_flush_mark(it);
480 return true;
481 }
482
483 static bool
nvkm_vmm_ref_swpt(struct nvkm_vmm_iter * it,struct nvkm_vmm_pt * pgd,u32 pdei)484 nvkm_vmm_ref_swpt(struct nvkm_vmm_iter *it, struct nvkm_vmm_pt *pgd, u32 pdei)
485 {
486 const struct nvkm_vmm_desc *desc = &it->desc[it->lvl - 1];
487 struct nvkm_vmm_pt *pgt = pgd->pde[pdei];
488
489 pgt = nvkm_vmm_pt_new(desc, NVKM_VMM_PDE_SPARSED(pgt), it->page);
490 if (!pgt) {
491 if (!pgd->refs[0])
492 nvkm_vmm_unref_pdes(it);
493 return false;
494 }
495
496 pgd->pde[pdei] = pgt;
497 return true;
498 }
499
500 static inline u64
nvkm_vmm_iter(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size,const char * name,bool ref,bool pfn,bool (* REF_PTES)(struct nvkm_vmm_iter *,bool pfn,u32,u32),nvkm_vmm_pte_func MAP_PTES,struct nvkm_vmm_map * map,nvkm_vmm_pxe_func CLR_PTES)501 nvkm_vmm_iter(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
502 u64 addr, u64 size, const char *name, bool ref, bool pfn,
503 bool (*REF_PTES)(struct nvkm_vmm_iter *, bool pfn, u32, u32),
504 nvkm_vmm_pte_func MAP_PTES, struct nvkm_vmm_map *map,
505 nvkm_vmm_pxe_func CLR_PTES)
506 {
507 const struct nvkm_vmm_desc *desc = page->desc;
508 struct nvkm_vmm_iter it;
509 u64 bits = addr >> page->shift;
510
511 it.page = page;
512 it.desc = desc;
513 it.vmm = vmm;
514 it.cnt = size >> page->shift;
515 it.flush = NVKM_VMM_LEVELS_MAX;
516
517 /* Deconstruct address into PTE indices for each mapping level. */
518 for (it.lvl = 0; desc[it.lvl].bits; it.lvl++) {
519 it.pte[it.lvl] = bits & ((1 << desc[it.lvl].bits) - 1);
520 bits >>= desc[it.lvl].bits;
521 }
522 it.max = --it.lvl;
523 it.pt[it.max] = vmm->pd;
524
525 it.lvl = 0;
526 TRA(&it, "%s: %016llx %016llx %d %lld PTEs", name,
527 addr, size, page->shift, it.cnt);
528 it.lvl = it.max;
529
530 /* Depth-first traversal of page tables. */
531 while (it.cnt) {
532 struct nvkm_vmm_pt *pgt = it.pt[it.lvl];
533 const int type = desc->type == SPT;
534 const u32 pten = 1 << desc->bits;
535 const u32 ptei = it.pte[0];
536 const u32 ptes = min_t(u64, it.cnt, pten - ptei);
537
538 /* Walk down the tree, finding page tables for each level. */
539 for (; it.lvl; it.lvl--) {
540 const u32 pdei = it.pte[it.lvl];
541 struct nvkm_vmm_pt *pgd = pgt;
542
543 /* Software PT. */
544 if (ref && NVKM_VMM_PDE_INVALID(pgd->pde[pdei])) {
545 if (!nvkm_vmm_ref_swpt(&it, pgd, pdei))
546 goto fail;
547 }
548 it.pt[it.lvl - 1] = pgt = pgd->pde[pdei];
549
550 /* Hardware PT.
551 *
552 * This is a separate step from above due to GF100 and
553 * newer having dual page tables at some levels, which
554 * are refcounted independently.
555 */
556 if (ref && !pgt->refs[desc[it.lvl - 1].type == SPT]) {
557 if (!nvkm_vmm_ref_hwpt(&it, pgd, pdei))
558 goto fail;
559 }
560 }
561
562 /* Handle PTE updates. */
563 if (!REF_PTES || REF_PTES(&it, pfn, ptei, ptes)) {
564 struct nvkm_mmu_pt *pt = pgt->pt[type];
565 if (MAP_PTES || CLR_PTES) {
566 if (MAP_PTES)
567 MAP_PTES(vmm, pt, ptei, ptes, map);
568 else
569 CLR_PTES(vmm, pt, ptei, ptes);
570 nvkm_vmm_flush_mark(&it);
571 }
572 }
573
574 /* Walk back up the tree to the next position. */
575 it.pte[it.lvl] += ptes;
576 it.cnt -= ptes;
577 if (it.cnt) {
578 while (it.pte[it.lvl] == (1 << desc[it.lvl].bits)) {
579 it.pte[it.lvl++] = 0;
580 it.pte[it.lvl]++;
581 }
582 }
583 }
584
585 nvkm_vmm_flush(&it);
586 return ~0ULL;
587
588 fail:
589 /* Reconstruct the failure address so the caller is able to
590 * reverse any partially completed operations.
591 */
592 addr = it.pte[it.max--];
593 do {
594 addr = addr << desc[it.max].bits;
595 addr |= it.pte[it.max];
596 } while (it.max--);
597
598 return addr << page->shift;
599 }
600
601 static void
nvkm_vmm_ptes_sparse_put(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size)602 nvkm_vmm_ptes_sparse_put(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
603 u64 addr, u64 size)
604 {
605 nvkm_vmm_iter(vmm, page, addr, size, "sparse unref", false, false,
606 nvkm_vmm_sparse_unref_ptes, NULL, NULL,
607 page->desc->func->invalid ?
608 page->desc->func->invalid : page->desc->func->unmap);
609 }
610
611 static int
nvkm_vmm_ptes_sparse_get(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size)612 nvkm_vmm_ptes_sparse_get(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
613 u64 addr, u64 size)
614 {
615 if ((page->type & NVKM_VMM_PAGE_SPARSE)) {
616 u64 fail = nvkm_vmm_iter(vmm, page, addr, size, "sparse ref",
617 true, false, nvkm_vmm_sparse_ref_ptes,
618 NULL, NULL, page->desc->func->sparse);
619 if (fail != ~0ULL) {
620 if ((size = fail - addr))
621 nvkm_vmm_ptes_sparse_put(vmm, page, addr, size);
622 return -ENOMEM;
623 }
624 return 0;
625 }
626 return -EINVAL;
627 }
628
629 static int
nvkm_vmm_ptes_sparse(struct nvkm_vmm * vmm,u64 addr,u64 size,bool ref)630 nvkm_vmm_ptes_sparse(struct nvkm_vmm *vmm, u64 addr, u64 size, bool ref)
631 {
632 const struct nvkm_vmm_page *page = vmm->func->page;
633 int m = 0, i;
634 u64 start = addr;
635 u64 block;
636
637 while (size) {
638 /* Limit maximum page size based on remaining size. */
639 while (size < (1ULL << page[m].shift))
640 m++;
641 i = m;
642
643 /* Find largest page size suitable for alignment. */
644 while (!IS_ALIGNED(addr, 1ULL << page[i].shift))
645 i++;
646
647 /* Determine number of PTEs at this page size. */
648 if (i != m) {
649 /* Limited to alignment boundary of next page size. */
650 u64 next = 1ULL << page[i - 1].shift;
651 u64 part = ALIGN(addr, next) - addr;
652 if (size - part >= next)
653 block = (part >> page[i].shift) << page[i].shift;
654 else
655 block = (size >> page[i].shift) << page[i].shift;
656 } else {
657 block = (size >> page[i].shift) << page[i].shift;
658 }
659
660 /* Perform operation. */
661 if (ref) {
662 int ret = nvkm_vmm_ptes_sparse_get(vmm, &page[i], addr, block);
663 if (ret) {
664 if ((size = addr - start))
665 nvkm_vmm_ptes_sparse(vmm, start, size, false);
666 return ret;
667 }
668 } else {
669 nvkm_vmm_ptes_sparse_put(vmm, &page[i], addr, block);
670 }
671
672 size -= block;
673 addr += block;
674 }
675
676 return 0;
677 }
678
679 static void
nvkm_vmm_ptes_unmap_put(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size,bool sparse,bool pfn)680 nvkm_vmm_ptes_unmap_put(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
681 u64 addr, u64 size, bool sparse, bool pfn)
682 {
683 const struct nvkm_vmm_desc_func *func = page->desc->func;
684 nvkm_vmm_iter(vmm, page, addr, size, "unmap + unref",
685 false, pfn, nvkm_vmm_unref_ptes, NULL, NULL,
686 sparse ? func->sparse : func->invalid ? func->invalid :
687 func->unmap);
688 }
689
690 static int
nvkm_vmm_ptes_get_map(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size,struct nvkm_vmm_map * map,nvkm_vmm_pte_func func)691 nvkm_vmm_ptes_get_map(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
692 u64 addr, u64 size, struct nvkm_vmm_map *map,
693 nvkm_vmm_pte_func func)
694 {
695 u64 fail = nvkm_vmm_iter(vmm, page, addr, size, "ref + map", true,
696 false, nvkm_vmm_ref_ptes, func, map, NULL);
697 if (fail != ~0ULL) {
698 if ((size = fail - addr))
699 nvkm_vmm_ptes_unmap_put(vmm, page, addr, size, false, false);
700 return -ENOMEM;
701 }
702 return 0;
703 }
704
705 static void
nvkm_vmm_ptes_unmap(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size,bool sparse,bool pfn)706 nvkm_vmm_ptes_unmap(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
707 u64 addr, u64 size, bool sparse, bool pfn)
708 {
709 const struct nvkm_vmm_desc_func *func = page->desc->func;
710 nvkm_vmm_iter(vmm, page, addr, size, "unmap", false, pfn,
711 NULL, NULL, NULL,
712 sparse ? func->sparse : func->invalid ? func->invalid :
713 func->unmap);
714 }
715
716 static void
nvkm_vmm_ptes_map(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size,struct nvkm_vmm_map * map,nvkm_vmm_pte_func func)717 nvkm_vmm_ptes_map(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
718 u64 addr, u64 size, struct nvkm_vmm_map *map,
719 nvkm_vmm_pte_func func)
720 {
721 nvkm_vmm_iter(vmm, page, addr, size, "map", false, false,
722 NULL, func, map, NULL);
723 }
724
725 static void
nvkm_vmm_ptes_put(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size)726 nvkm_vmm_ptes_put(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
727 u64 addr, u64 size)
728 {
729 nvkm_vmm_iter(vmm, page, addr, size, "unref", false, false,
730 nvkm_vmm_unref_ptes, NULL, NULL, NULL);
731 }
732
733 static int
nvkm_vmm_ptes_get(struct nvkm_vmm * vmm,const struct nvkm_vmm_page * page,u64 addr,u64 size)734 nvkm_vmm_ptes_get(struct nvkm_vmm *vmm, const struct nvkm_vmm_page *page,
735 u64 addr, u64 size)
736 {
737 u64 fail = nvkm_vmm_iter(vmm, page, addr, size, "ref", true, false,
738 nvkm_vmm_ref_ptes, NULL, NULL, NULL);
739 if (fail != ~0ULL) {
740 if (fail != addr)
741 nvkm_vmm_ptes_put(vmm, page, addr, fail - addr);
742 return -ENOMEM;
743 }
744 return 0;
745 }
746
747 static inline struct nvkm_vma *
nvkm_vma_new(u64 addr,u64 size)748 nvkm_vma_new(u64 addr, u64 size)
749 {
750 struct nvkm_vma *vma = kzalloc(sizeof(*vma), GFP_KERNEL);
751 if (vma) {
752 vma->addr = addr;
753 vma->size = size;
754 vma->page = NVKM_VMA_PAGE_NONE;
755 vma->refd = NVKM_VMA_PAGE_NONE;
756 }
757 return vma;
758 }
759
760 struct nvkm_vma *
nvkm_vma_tail(struct nvkm_vma * vma,u64 tail)761 nvkm_vma_tail(struct nvkm_vma *vma, u64 tail)
762 {
763 struct nvkm_vma *new;
764
765 BUG_ON(vma->size == tail);
766
767 if (!(new = nvkm_vma_new(vma->addr + (vma->size - tail), tail)))
768 return NULL;
769 vma->size -= tail;
770
771 new->mapref = vma->mapref;
772 new->sparse = vma->sparse;
773 new->page = vma->page;
774 new->refd = vma->refd;
775 new->used = vma->used;
776 new->part = vma->part;
777 new->user = vma->user;
778 new->busy = vma->busy;
779 new->mapped = vma->mapped;
780 list_add(&new->head, &vma->head);
781 return new;
782 }
783
784 static inline void
nvkm_vmm_free_remove(struct nvkm_vmm * vmm,struct nvkm_vma * vma)785 nvkm_vmm_free_remove(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
786 {
787 rb_erase(&vma->tree, &vmm->free);
788 }
789
790 static inline void
nvkm_vmm_free_delete(struct nvkm_vmm * vmm,struct nvkm_vma * vma)791 nvkm_vmm_free_delete(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
792 {
793 nvkm_vmm_free_remove(vmm, vma);
794 list_del(&vma->head);
795 kfree(vma);
796 }
797
798 static void
nvkm_vmm_free_insert(struct nvkm_vmm * vmm,struct nvkm_vma * vma)799 nvkm_vmm_free_insert(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
800 {
801 struct rb_node **ptr = &vmm->free.rb_node;
802 struct rb_node *parent = NULL;
803
804 while (*ptr) {
805 struct nvkm_vma *this = rb_entry(*ptr, typeof(*this), tree);
806 parent = *ptr;
807 if (vma->size < this->size)
808 ptr = &parent->rb_left;
809 else
810 if (vma->size > this->size)
811 ptr = &parent->rb_right;
812 else
813 if (vma->addr < this->addr)
814 ptr = &parent->rb_left;
815 else
816 if (vma->addr > this->addr)
817 ptr = &parent->rb_right;
818 else
819 BUG();
820 }
821
822 rb_link_node(&vma->tree, parent, ptr);
823 rb_insert_color(&vma->tree, &vmm->free);
824 }
825
826 static inline void
nvkm_vmm_node_remove(struct nvkm_vmm * vmm,struct nvkm_vma * vma)827 nvkm_vmm_node_remove(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
828 {
829 rb_erase(&vma->tree, &vmm->root);
830 }
831
832 static inline void
nvkm_vmm_node_delete(struct nvkm_vmm * vmm,struct nvkm_vma * vma)833 nvkm_vmm_node_delete(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
834 {
835 nvkm_vmm_node_remove(vmm, vma);
836 list_del(&vma->head);
837 kfree(vma);
838 }
839
840 static void
nvkm_vmm_node_insert(struct nvkm_vmm * vmm,struct nvkm_vma * vma)841 nvkm_vmm_node_insert(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
842 {
843 struct rb_node **ptr = &vmm->root.rb_node;
844 struct rb_node *parent = NULL;
845
846 while (*ptr) {
847 struct nvkm_vma *this = rb_entry(*ptr, typeof(*this), tree);
848 parent = *ptr;
849 if (vma->addr < this->addr)
850 ptr = &parent->rb_left;
851 else
852 if (vma->addr > this->addr)
853 ptr = &parent->rb_right;
854 else
855 BUG();
856 }
857
858 rb_link_node(&vma->tree, parent, ptr);
859 rb_insert_color(&vma->tree, &vmm->root);
860 }
861
862 struct nvkm_vma *
nvkm_vmm_node_search(struct nvkm_vmm * vmm,u64 addr)863 nvkm_vmm_node_search(struct nvkm_vmm *vmm, u64 addr)
864 {
865 struct rb_node *node = vmm->root.rb_node;
866 while (node) {
867 struct nvkm_vma *vma = rb_entry(node, typeof(*vma), tree);
868 if (addr < vma->addr)
869 node = node->rb_left;
870 else
871 if (addr >= vma->addr + vma->size)
872 node = node->rb_right;
873 else
874 return vma;
875 }
876 return NULL;
877 }
878
879 #define node(root, dir) (((root)->head.dir == &vmm->list) ? NULL : \
880 list_entry((root)->head.dir, struct nvkm_vma, head))
881
882 static struct nvkm_vma *
nvkm_vmm_node_merge(struct nvkm_vmm * vmm,struct nvkm_vma * prev,struct nvkm_vma * vma,struct nvkm_vma * next,u64 size)883 nvkm_vmm_node_merge(struct nvkm_vmm *vmm, struct nvkm_vma *prev,
884 struct nvkm_vma *vma, struct nvkm_vma *next, u64 size)
885 {
886 if (next) {
887 if (vma->size == size) {
888 vma->size += next->size;
889 nvkm_vmm_node_delete(vmm, next);
890 if (prev) {
891 prev->size += vma->size;
892 nvkm_vmm_node_delete(vmm, vma);
893 return prev;
894 }
895 return vma;
896 }
897 BUG_ON(prev);
898
899 nvkm_vmm_node_remove(vmm, next);
900 vma->size -= size;
901 next->addr -= size;
902 next->size += size;
903 nvkm_vmm_node_insert(vmm, next);
904 return next;
905 }
906
907 if (prev) {
908 if (vma->size != size) {
909 nvkm_vmm_node_remove(vmm, vma);
910 prev->size += size;
911 vma->addr += size;
912 vma->size -= size;
913 nvkm_vmm_node_insert(vmm, vma);
914 } else {
915 prev->size += vma->size;
916 nvkm_vmm_node_delete(vmm, vma);
917 }
918 return prev;
919 }
920
921 return vma;
922 }
923
924 struct nvkm_vma *
nvkm_vmm_node_split(struct nvkm_vmm * vmm,struct nvkm_vma * vma,u64 addr,u64 size)925 nvkm_vmm_node_split(struct nvkm_vmm *vmm,
926 struct nvkm_vma *vma, u64 addr, u64 size)
927 {
928 struct nvkm_vma *prev = NULL;
929
930 if (vma->addr != addr) {
931 prev = vma;
932 if (!(vma = nvkm_vma_tail(vma, vma->size + vma->addr - addr)))
933 return NULL;
934 vma->part = true;
935 nvkm_vmm_node_insert(vmm, vma);
936 }
937
938 if (vma->size != size) {
939 struct nvkm_vma *tmp;
940 if (!(tmp = nvkm_vma_tail(vma, vma->size - size))) {
941 nvkm_vmm_node_merge(vmm, prev, vma, NULL, vma->size);
942 return NULL;
943 }
944 tmp->part = true;
945 nvkm_vmm_node_insert(vmm, tmp);
946 }
947
948 return vma;
949 }
950
951 static void
nvkm_vma_dump(struct nvkm_vma * vma)952 nvkm_vma_dump(struct nvkm_vma *vma)
953 {
954 printk(KERN_ERR "%016llx %016llx %c%c%c%c%c%c%c%c%c %p\n",
955 vma->addr, (u64)vma->size,
956 vma->used ? '-' : 'F',
957 vma->mapref ? 'R' : '-',
958 vma->sparse ? 'S' : '-',
959 vma->page != NVKM_VMA_PAGE_NONE ? '0' + vma->page : '-',
960 vma->refd != NVKM_VMA_PAGE_NONE ? '0' + vma->refd : '-',
961 vma->part ? 'P' : '-',
962 vma->user ? 'U' : '-',
963 vma->busy ? 'B' : '-',
964 vma->mapped ? 'M' : '-',
965 vma->memory);
966 }
967
968 static void
nvkm_vmm_dump(struct nvkm_vmm * vmm)969 nvkm_vmm_dump(struct nvkm_vmm *vmm)
970 {
971 struct nvkm_vma *vma;
972 list_for_each_entry(vma, &vmm->list, head) {
973 nvkm_vma_dump(vma);
974 }
975 }
976
977 static void
nvkm_vmm_dtor(struct nvkm_vmm * vmm)978 nvkm_vmm_dtor(struct nvkm_vmm *vmm)
979 {
980 struct nvkm_vma *vma;
981 struct rb_node *node;
982
983 if (0)
984 nvkm_vmm_dump(vmm);
985
986 while ((node = rb_first(&vmm->root))) {
987 struct nvkm_vma *vma = rb_entry(node, typeof(*vma), tree);
988 nvkm_vmm_put(vmm, &vma);
989 }
990
991 if (vmm->bootstrapped) {
992 const struct nvkm_vmm_page *page = vmm->func->page;
993 const u64 limit = vmm->limit - vmm->start;
994
995 while (page[1].shift)
996 page++;
997
998 nvkm_mmu_ptc_dump(vmm->mmu);
999 nvkm_vmm_ptes_put(vmm, page, vmm->start, limit);
1000 }
1001
1002 vma = list_first_entry(&vmm->list, typeof(*vma), head);
1003 list_del(&vma->head);
1004 kfree(vma);
1005 WARN_ON(!list_empty(&vmm->list));
1006
1007 if (vmm->nullp) {
1008 dma_free_coherent(vmm->mmu->subdev.device->dev, 16 * 1024,
1009 vmm->nullp, vmm->null);
1010 }
1011
1012 if (vmm->pd) {
1013 nvkm_mmu_ptc_put(vmm->mmu, true, &vmm->pd->pt[0]);
1014 nvkm_vmm_pt_del(&vmm->pd);
1015 }
1016 }
1017
1018 static int
nvkm_vmm_ctor_managed(struct nvkm_vmm * vmm,u64 addr,u64 size)1019 nvkm_vmm_ctor_managed(struct nvkm_vmm *vmm, u64 addr, u64 size)
1020 {
1021 struct nvkm_vma *vma;
1022 if (!(vma = nvkm_vma_new(addr, size)))
1023 return -ENOMEM;
1024 vma->mapref = true;
1025 vma->sparse = false;
1026 vma->used = true;
1027 vma->user = true;
1028 nvkm_vmm_node_insert(vmm, vma);
1029 list_add_tail(&vma->head, &vmm->list);
1030 return 0;
1031 }
1032
1033 static int
nvkm_vmm_ctor(const struct nvkm_vmm_func * func,struct nvkm_mmu * mmu,u32 pd_header,bool managed,u64 addr,u64 size,struct lock_class_key * key,const char * name,struct nvkm_vmm * vmm)1034 nvkm_vmm_ctor(const struct nvkm_vmm_func *func, struct nvkm_mmu *mmu,
1035 u32 pd_header, bool managed, u64 addr, u64 size,
1036 struct lock_class_key *key, const char *name,
1037 struct nvkm_vmm *vmm)
1038 {
1039 static struct lock_class_key _key;
1040 const struct nvkm_vmm_page *page = func->page;
1041 const struct nvkm_vmm_desc *desc;
1042 struct nvkm_vma *vma;
1043 int levels, bits = 0, ret;
1044
1045 vmm->func = func;
1046 vmm->mmu = mmu;
1047 vmm->name = name;
1048 vmm->debug = mmu->subdev.debug;
1049 kref_init(&vmm->kref);
1050
1051 __mutex_init(&vmm->mutex, "&vmm->mutex", key ? key : &_key);
1052
1053 /* Locate the smallest page size supported by the backend, it will
1054 * have the the deepest nesting of page tables.
1055 */
1056 while (page[1].shift)
1057 page++;
1058
1059 /* Locate the structure that describes the layout of the top-level
1060 * page table, and determine the number of valid bits in a virtual
1061 * address.
1062 */
1063 for (levels = 0, desc = page->desc; desc->bits; desc++, levels++)
1064 bits += desc->bits;
1065 bits += page->shift;
1066 desc--;
1067
1068 if (WARN_ON(levels > NVKM_VMM_LEVELS_MAX))
1069 return -EINVAL;
1070
1071 /* Allocate top-level page table. */
1072 vmm->pd = nvkm_vmm_pt_new(desc, false, NULL);
1073 if (!vmm->pd)
1074 return -ENOMEM;
1075 vmm->pd->refs[0] = 1;
1076 INIT_LIST_HEAD(&vmm->join);
1077
1078 /* ... and the GPU storage for it, except on Tesla-class GPUs that
1079 * have the PD embedded in the instance structure.
1080 */
1081 if (desc->size) {
1082 const u32 size = pd_header + desc->size * (1 << desc->bits);
1083 vmm->pd->pt[0] = nvkm_mmu_ptc_get(mmu, size, desc->align, true);
1084 if (!vmm->pd->pt[0])
1085 return -ENOMEM;
1086 }
1087
1088 /* Initialise address-space MM. */
1089 INIT_LIST_HEAD(&vmm->list);
1090 vmm->free = RB_ROOT;
1091 vmm->root = RB_ROOT;
1092
1093 if (managed) {
1094 /* Address-space will be managed by the client for the most
1095 * part, except for a specified area where NVKM allocations
1096 * are allowed to be placed.
1097 */
1098 vmm->start = 0;
1099 vmm->limit = 1ULL << bits;
1100 if (addr + size < addr || addr + size > vmm->limit)
1101 return -EINVAL;
1102
1103 /* Client-managed area before the NVKM-managed area. */
1104 if (addr && (ret = nvkm_vmm_ctor_managed(vmm, 0, addr)))
1105 return ret;
1106
1107 /* NVKM-managed area. */
1108 if (size) {
1109 if (!(vma = nvkm_vma_new(addr, size)))
1110 return -ENOMEM;
1111 nvkm_vmm_free_insert(vmm, vma);
1112 list_add_tail(&vma->head, &vmm->list);
1113 }
1114
1115 /* Client-managed area after the NVKM-managed area. */
1116 addr = addr + size;
1117 size = vmm->limit - addr;
1118 if (size && (ret = nvkm_vmm_ctor_managed(vmm, addr, size)))
1119 return ret;
1120 } else {
1121 /* Address-space fully managed by NVKM, requiring calls to
1122 * nvkm_vmm_get()/nvkm_vmm_put() to allocate address-space.
1123 */
1124 vmm->start = addr;
1125 vmm->limit = size ? (addr + size) : (1ULL << bits);
1126 if (vmm->start > vmm->limit || vmm->limit > (1ULL << bits))
1127 return -EINVAL;
1128
1129 if (!(vma = nvkm_vma_new(vmm->start, vmm->limit - vmm->start)))
1130 return -ENOMEM;
1131
1132 nvkm_vmm_free_insert(vmm, vma);
1133 list_add(&vma->head, &vmm->list);
1134 }
1135
1136 return 0;
1137 }
1138
1139 int
nvkm_vmm_new_(const struct nvkm_vmm_func * func,struct nvkm_mmu * mmu,u32 hdr,bool managed,u64 addr,u64 size,struct lock_class_key * key,const char * name,struct nvkm_vmm ** pvmm)1140 nvkm_vmm_new_(const struct nvkm_vmm_func *func, struct nvkm_mmu *mmu,
1141 u32 hdr, bool managed, u64 addr, u64 size,
1142 struct lock_class_key *key, const char *name,
1143 struct nvkm_vmm **pvmm)
1144 {
1145 if (!(*pvmm = kzalloc(sizeof(**pvmm), GFP_KERNEL)))
1146 return -ENOMEM;
1147 return nvkm_vmm_ctor(func, mmu, hdr, managed, addr, size, key, name, *pvmm);
1148 }
1149
1150 static struct nvkm_vma *
nvkm_vmm_pfn_split_merge(struct nvkm_vmm * vmm,struct nvkm_vma * vma,u64 addr,u64 size,u8 page,bool map)1151 nvkm_vmm_pfn_split_merge(struct nvkm_vmm *vmm, struct nvkm_vma *vma,
1152 u64 addr, u64 size, u8 page, bool map)
1153 {
1154 struct nvkm_vma *prev = NULL;
1155 struct nvkm_vma *next = NULL;
1156
1157 if (vma->addr == addr && vma->part && (prev = node(vma, prev))) {
1158 if (prev->memory || prev->mapped != map)
1159 prev = NULL;
1160 }
1161
1162 if (vma->addr + vma->size == addr + size && (next = node(vma, next))) {
1163 if (!next->part ||
1164 next->memory || next->mapped != map)
1165 next = NULL;
1166 }
1167
1168 if (prev || next)
1169 return nvkm_vmm_node_merge(vmm, prev, vma, next, size);
1170 return nvkm_vmm_node_split(vmm, vma, addr, size);
1171 }
1172
1173 int
nvkm_vmm_pfn_unmap(struct nvkm_vmm * vmm,u64 addr,u64 size)1174 nvkm_vmm_pfn_unmap(struct nvkm_vmm *vmm, u64 addr, u64 size)
1175 {
1176 struct nvkm_vma *vma = nvkm_vmm_node_search(vmm, addr);
1177 struct nvkm_vma *next;
1178 u64 limit = addr + size;
1179 u64 start = addr;
1180
1181 if (!vma)
1182 return -EINVAL;
1183
1184 do {
1185 if (!vma->mapped || vma->memory)
1186 continue;
1187
1188 size = min(limit - start, vma->size - (start - vma->addr));
1189
1190 nvkm_vmm_ptes_unmap_put(vmm, &vmm->func->page[vma->refd],
1191 start, size, false, true);
1192
1193 next = nvkm_vmm_pfn_split_merge(vmm, vma, start, size, 0, false);
1194 if (!WARN_ON(!next)) {
1195 vma = next;
1196 vma->refd = NVKM_VMA_PAGE_NONE;
1197 vma->mapped = false;
1198 }
1199 } while ((vma = node(vma, next)) && (start = vma->addr) < limit);
1200
1201 return 0;
1202 }
1203
1204 /*TODO:
1205 * - Avoid PT readback (for dma_unmap etc), this might end up being dealt
1206 * with inside HMM, which would be a lot nicer for us to deal with.
1207 * - Support for systems without a 4KiB page size.
1208 */
1209 int
nvkm_vmm_pfn_map(struct nvkm_vmm * vmm,u8 shift,u64 addr,u64 size,u64 * pfn)1210 nvkm_vmm_pfn_map(struct nvkm_vmm *vmm, u8 shift, u64 addr, u64 size, u64 *pfn)
1211 {
1212 const struct nvkm_vmm_page *page = vmm->func->page;
1213 struct nvkm_vma *vma, *tmp;
1214 u64 limit = addr + size;
1215 u64 start = addr;
1216 int pm = size >> shift;
1217 int pi = 0;
1218
1219 /* Only support mapping where the page size of the incoming page
1220 * array matches a page size available for direct mapping.
1221 */
1222 while (page->shift && (page->shift != shift ||
1223 page->desc->func->pfn == NULL))
1224 page++;
1225
1226 if (!page->shift || !IS_ALIGNED(addr, 1ULL << shift) ||
1227 !IS_ALIGNED(size, 1ULL << shift) ||
1228 addr + size < addr || addr + size > vmm->limit) {
1229 VMM_DEBUG(vmm, "paged map %d %d %016llx %016llx\n",
1230 shift, page->shift, addr, size);
1231 return -EINVAL;
1232 }
1233
1234 if (!(vma = nvkm_vmm_node_search(vmm, addr)))
1235 return -ENOENT;
1236
1237 do {
1238 bool map = !!(pfn[pi] & NVKM_VMM_PFN_V);
1239 bool mapped = vma->mapped;
1240 u64 size = limit - start;
1241 u64 addr = start;
1242 int pn, ret = 0;
1243
1244 /* Narrow the operation window to cover a single action (page
1245 * should be mapped or not) within a single VMA.
1246 */
1247 for (pn = 0; pi + pn < pm; pn++) {
1248 if (map != !!(pfn[pi + pn] & NVKM_VMM_PFN_V))
1249 break;
1250 }
1251 size = min_t(u64, size, pn << page->shift);
1252 size = min_t(u64, size, vma->size + vma->addr - addr);
1253
1254 /* Reject any operation to unmanaged regions, and areas that
1255 * have nvkm_memory objects mapped in them already.
1256 */
1257 if (!vma->mapref || vma->memory) {
1258 ret = -EINVAL;
1259 goto next;
1260 }
1261
1262 /* In order to both properly refcount GPU page tables, and
1263 * prevent "normal" mappings and these direct mappings from
1264 * interfering with each other, we need to track contiguous
1265 * ranges that have been mapped with this interface.
1266 *
1267 * Here we attempt to either split an existing VMA so we're
1268 * able to flag the region as either unmapped/mapped, or to
1269 * merge with adjacent VMAs that are already compatible.
1270 *
1271 * If the region is already compatible, nothing is required.
1272 */
1273 if (map != mapped) {
1274 tmp = nvkm_vmm_pfn_split_merge(vmm, vma, addr, size,
1275 page -
1276 vmm->func->page, map);
1277 if (WARN_ON(!tmp)) {
1278 ret = -ENOMEM;
1279 goto next;
1280 }
1281
1282 if ((tmp->mapped = map))
1283 tmp->refd = page - vmm->func->page;
1284 else
1285 tmp->refd = NVKM_VMA_PAGE_NONE;
1286 vma = tmp;
1287 }
1288
1289 /* Update HW page tables. */
1290 if (map) {
1291 struct nvkm_vmm_map args;
1292 args.page = page;
1293 args.pfn = &pfn[pi];
1294
1295 if (!mapped) {
1296 ret = nvkm_vmm_ptes_get_map(vmm, page, addr,
1297 size, &args, page->
1298 desc->func->pfn);
1299 } else {
1300 nvkm_vmm_ptes_map(vmm, page, addr, size, &args,
1301 page->desc->func->pfn);
1302 }
1303 } else {
1304 if (mapped) {
1305 nvkm_vmm_ptes_unmap_put(vmm, page, addr, size,
1306 false, true);
1307 }
1308 }
1309
1310 next:
1311 /* Iterate to next operation. */
1312 if (vma->addr + vma->size == addr + size)
1313 vma = node(vma, next);
1314 start += size;
1315
1316 if (ret) {
1317 /* Failure is signalled by clearing the valid bit on
1318 * any PFN that couldn't be modified as requested.
1319 */
1320 while (size) {
1321 pfn[pi++] = NVKM_VMM_PFN_NONE;
1322 size -= 1 << page->shift;
1323 }
1324 } else {
1325 pi += size >> page->shift;
1326 }
1327 } while (vma && start < limit);
1328
1329 return 0;
1330 }
1331
1332 void
nvkm_vmm_unmap_region(struct nvkm_vmm * vmm,struct nvkm_vma * vma)1333 nvkm_vmm_unmap_region(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
1334 {
1335 struct nvkm_vma *prev = NULL;
1336 struct nvkm_vma *next;
1337
1338 nvkm_memory_tags_put(vma->memory, vmm->mmu->subdev.device, &vma->tags);
1339 nvkm_memory_unref(&vma->memory);
1340 vma->mapped = false;
1341
1342 if (vma->part && (prev = node(vma, prev)) && prev->mapped)
1343 prev = NULL;
1344 if ((next = node(vma, next)) && (!next->part || next->mapped))
1345 next = NULL;
1346 nvkm_vmm_node_merge(vmm, prev, vma, next, vma->size);
1347 }
1348
1349 void
nvkm_vmm_unmap_locked(struct nvkm_vmm * vmm,struct nvkm_vma * vma,bool pfn)1350 nvkm_vmm_unmap_locked(struct nvkm_vmm *vmm, struct nvkm_vma *vma, bool pfn)
1351 {
1352 const struct nvkm_vmm_page *page = &vmm->func->page[vma->refd];
1353
1354 if (vma->mapref) {
1355 nvkm_vmm_ptes_unmap_put(vmm, page, vma->addr, vma->size, vma->sparse, pfn);
1356 vma->refd = NVKM_VMA_PAGE_NONE;
1357 } else {
1358 nvkm_vmm_ptes_unmap(vmm, page, vma->addr, vma->size, vma->sparse, pfn);
1359 }
1360
1361 nvkm_vmm_unmap_region(vmm, vma);
1362 }
1363
1364 void
nvkm_vmm_unmap(struct nvkm_vmm * vmm,struct nvkm_vma * vma)1365 nvkm_vmm_unmap(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
1366 {
1367 if (vma->memory) {
1368 mutex_lock(&vmm->mutex);
1369 nvkm_vmm_unmap_locked(vmm, vma, false);
1370 mutex_unlock(&vmm->mutex);
1371 }
1372 }
1373
1374 static int
nvkm_vmm_map_valid(struct nvkm_vmm * vmm,struct nvkm_vma * vma,void * argv,u32 argc,struct nvkm_vmm_map * map)1375 nvkm_vmm_map_valid(struct nvkm_vmm *vmm, struct nvkm_vma *vma,
1376 void *argv, u32 argc, struct nvkm_vmm_map *map)
1377 {
1378 switch (nvkm_memory_target(map->memory)) {
1379 case NVKM_MEM_TARGET_VRAM:
1380 if (!(map->page->type & NVKM_VMM_PAGE_VRAM)) {
1381 VMM_DEBUG(vmm, "%d !VRAM", map->page->shift);
1382 return -EINVAL;
1383 }
1384 break;
1385 case NVKM_MEM_TARGET_HOST:
1386 case NVKM_MEM_TARGET_NCOH:
1387 if (!(map->page->type & NVKM_VMM_PAGE_HOST)) {
1388 VMM_DEBUG(vmm, "%d !HOST", map->page->shift);
1389 return -EINVAL;
1390 }
1391 break;
1392 default:
1393 WARN_ON(1);
1394 return -ENOSYS;
1395 }
1396
1397 if (!IS_ALIGNED( vma->addr, 1ULL << map->page->shift) ||
1398 !IS_ALIGNED((u64)vma->size, 1ULL << map->page->shift) ||
1399 !IS_ALIGNED( map->offset, 1ULL << map->page->shift) ||
1400 nvkm_memory_page(map->memory) < map->page->shift) {
1401 VMM_DEBUG(vmm, "alignment %016llx %016llx %016llx %d %d",
1402 vma->addr, (u64)vma->size, map->offset, map->page->shift,
1403 nvkm_memory_page(map->memory));
1404 return -EINVAL;
1405 }
1406
1407 return vmm->func->valid(vmm, argv, argc, map);
1408 }
1409
1410 static int
nvkm_vmm_map_choose(struct nvkm_vmm * vmm,struct nvkm_vma * vma,void * argv,u32 argc,struct nvkm_vmm_map * map)1411 nvkm_vmm_map_choose(struct nvkm_vmm *vmm, struct nvkm_vma *vma,
1412 void *argv, u32 argc, struct nvkm_vmm_map *map)
1413 {
1414 for (map->page = vmm->func->page; map->page->shift; map->page++) {
1415 VMM_DEBUG(vmm, "trying %d", map->page->shift);
1416 if (!nvkm_vmm_map_valid(vmm, vma, argv, argc, map))
1417 return 0;
1418 }
1419 return -EINVAL;
1420 }
1421
1422 static int
nvkm_vmm_map_locked(struct nvkm_vmm * vmm,struct nvkm_vma * vma,void * argv,u32 argc,struct nvkm_vmm_map * map)1423 nvkm_vmm_map_locked(struct nvkm_vmm *vmm, struct nvkm_vma *vma,
1424 void *argv, u32 argc, struct nvkm_vmm_map *map)
1425 {
1426 nvkm_vmm_pte_func func;
1427 int ret;
1428
1429 /* Make sure we won't overrun the end of the memory object. */
1430 if (unlikely(nvkm_memory_size(map->memory) < map->offset + vma->size)) {
1431 VMM_DEBUG(vmm, "overrun %016llx %016llx %016llx",
1432 nvkm_memory_size(map->memory),
1433 map->offset, (u64)vma->size);
1434 return -EINVAL;
1435 }
1436
1437 /* Check remaining arguments for validity. */
1438 if (vma->page == NVKM_VMA_PAGE_NONE &&
1439 vma->refd == NVKM_VMA_PAGE_NONE) {
1440 /* Find the largest page size we can perform the mapping at. */
1441 const u32 debug = vmm->debug;
1442 vmm->debug = 0;
1443 ret = nvkm_vmm_map_choose(vmm, vma, argv, argc, map);
1444 vmm->debug = debug;
1445 if (ret) {
1446 VMM_DEBUG(vmm, "invalid at any page size");
1447 nvkm_vmm_map_choose(vmm, vma, argv, argc, map);
1448 return -EINVAL;
1449 }
1450 } else {
1451 /* Page size of the VMA is already pre-determined. */
1452 if (vma->refd != NVKM_VMA_PAGE_NONE)
1453 map->page = &vmm->func->page[vma->refd];
1454 else
1455 map->page = &vmm->func->page[vma->page];
1456
1457 ret = nvkm_vmm_map_valid(vmm, vma, argv, argc, map);
1458 if (ret) {
1459 VMM_DEBUG(vmm, "invalid %d\n", ret);
1460 return ret;
1461 }
1462 }
1463
1464 /* Deal with the 'offset' argument, and fetch the backend function. */
1465 map->off = map->offset;
1466 if (map->mem) {
1467 for (; map->off; map->mem = map->mem->next) {
1468 u64 size = (u64)map->mem->length << NVKM_RAM_MM_SHIFT;
1469 if (size > map->off)
1470 break;
1471 map->off -= size;
1472 }
1473 func = map->page->desc->func->mem;
1474 } else
1475 if (map->sgl) {
1476 for (; map->off; map->sgl = sg_next(map->sgl)) {
1477 u64 size = sg_dma_len(map->sgl);
1478 if (size > map->off)
1479 break;
1480 map->off -= size;
1481 }
1482 func = map->page->desc->func->sgl;
1483 } else {
1484 map->dma += map->offset >> PAGE_SHIFT;
1485 map->off = map->offset & PAGE_MASK;
1486 func = map->page->desc->func->dma;
1487 }
1488
1489 /* Perform the map. */
1490 if (vma->refd == NVKM_VMA_PAGE_NONE) {
1491 ret = nvkm_vmm_ptes_get_map(vmm, map->page, vma->addr, vma->size, map, func);
1492 if (ret)
1493 return ret;
1494
1495 vma->refd = map->page - vmm->func->page;
1496 } else {
1497 nvkm_vmm_ptes_map(vmm, map->page, vma->addr, vma->size, map, func);
1498 }
1499
1500 nvkm_memory_tags_put(vma->memory, vmm->mmu->subdev.device, &vma->tags);
1501 nvkm_memory_unref(&vma->memory);
1502 vma->memory = nvkm_memory_ref(map->memory);
1503 vma->mapped = true;
1504 vma->tags = map->tags;
1505 return 0;
1506 }
1507
1508 int
nvkm_vmm_map(struct nvkm_vmm * vmm,struct nvkm_vma * vma,void * argv,u32 argc,struct nvkm_vmm_map * map)1509 nvkm_vmm_map(struct nvkm_vmm *vmm, struct nvkm_vma *vma, void *argv, u32 argc,
1510 struct nvkm_vmm_map *map)
1511 {
1512 int ret;
1513 mutex_lock(&vmm->mutex);
1514 ret = nvkm_vmm_map_locked(vmm, vma, argv, argc, map);
1515 vma->busy = false;
1516 mutex_unlock(&vmm->mutex);
1517 return ret;
1518 }
1519
1520 static void
nvkm_vmm_put_region(struct nvkm_vmm * vmm,struct nvkm_vma * vma)1521 nvkm_vmm_put_region(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
1522 {
1523 struct nvkm_vma *prev, *next;
1524
1525 if ((prev = node(vma, prev)) && !prev->used) {
1526 vma->addr = prev->addr;
1527 vma->size += prev->size;
1528 nvkm_vmm_free_delete(vmm, prev);
1529 }
1530
1531 if ((next = node(vma, next)) && !next->used) {
1532 vma->size += next->size;
1533 nvkm_vmm_free_delete(vmm, next);
1534 }
1535
1536 nvkm_vmm_free_insert(vmm, vma);
1537 }
1538
1539 void
nvkm_vmm_put_locked(struct nvkm_vmm * vmm,struct nvkm_vma * vma)1540 nvkm_vmm_put_locked(struct nvkm_vmm *vmm, struct nvkm_vma *vma)
1541 {
1542 const struct nvkm_vmm_page *page = vmm->func->page;
1543 struct nvkm_vma *next = vma;
1544
1545 BUG_ON(vma->part);
1546
1547 if (vma->mapref || !vma->sparse) {
1548 do {
1549 const bool mem = next->memory != NULL;
1550 const bool map = next->mapped;
1551 const u8 refd = next->refd;
1552 const u64 addr = next->addr;
1553 u64 size = next->size;
1554
1555 /* Merge regions that are in the same state. */
1556 while ((next = node(next, next)) && next->part &&
1557 (next->mapped == map) &&
1558 (next->memory != NULL) == mem &&
1559 (next->refd == refd))
1560 size += next->size;
1561
1562 if (map) {
1563 /* Region(s) are mapped, merge the unmap
1564 * and dereference into a single walk of
1565 * the page tree.
1566 */
1567 nvkm_vmm_ptes_unmap_put(vmm, &page[refd], addr,
1568 size, vma->sparse,
1569 !mem);
1570 } else
1571 if (refd != NVKM_VMA_PAGE_NONE) {
1572 /* Drop allocation-time PTE references. */
1573 nvkm_vmm_ptes_put(vmm, &page[refd], addr, size);
1574 }
1575 } while (next && next->part);
1576 }
1577
1578 /* Merge any mapped regions that were split from the initial
1579 * address-space allocation back into the allocated VMA, and
1580 * release memory/compression resources.
1581 */
1582 next = vma;
1583 do {
1584 if (next->mapped)
1585 nvkm_vmm_unmap_region(vmm, next);
1586 } while ((next = node(vma, next)) && next->part);
1587
1588 if (vma->sparse && !vma->mapref) {
1589 /* Sparse region that was allocated with a fixed page size,
1590 * meaning all relevant PTEs were referenced once when the
1591 * region was allocated, and remained that way, regardless
1592 * of whether memory was mapped into it afterwards.
1593 *
1594 * The process of unmapping, unsparsing, and dereferencing
1595 * PTEs can be done in a single page tree walk.
1596 */
1597 nvkm_vmm_ptes_sparse_put(vmm, &page[vma->refd], vma->addr, vma->size);
1598 } else
1599 if (vma->sparse) {
1600 /* Sparse region that wasn't allocated with a fixed page size,
1601 * PTE references were taken both at allocation time (to make
1602 * the GPU see the region as sparse), and when mapping memory
1603 * into the region.
1604 *
1605 * The latter was handled above, and the remaining references
1606 * are dealt with here.
1607 */
1608 nvkm_vmm_ptes_sparse(vmm, vma->addr, vma->size, false);
1609 }
1610
1611 /* Remove VMA from the list of allocated nodes. */
1612 nvkm_vmm_node_remove(vmm, vma);
1613
1614 /* Merge VMA back into the free list. */
1615 vma->page = NVKM_VMA_PAGE_NONE;
1616 vma->refd = NVKM_VMA_PAGE_NONE;
1617 vma->used = false;
1618 vma->user = false;
1619 nvkm_vmm_put_region(vmm, vma);
1620 }
1621
1622 void
nvkm_vmm_put(struct nvkm_vmm * vmm,struct nvkm_vma ** pvma)1623 nvkm_vmm_put(struct nvkm_vmm *vmm, struct nvkm_vma **pvma)
1624 {
1625 struct nvkm_vma *vma = *pvma;
1626 if (vma) {
1627 mutex_lock(&vmm->mutex);
1628 nvkm_vmm_put_locked(vmm, vma);
1629 mutex_unlock(&vmm->mutex);
1630 *pvma = NULL;
1631 }
1632 }
1633
1634 int
nvkm_vmm_get_locked(struct nvkm_vmm * vmm,bool getref,bool mapref,bool sparse,u8 shift,u8 align,u64 size,struct nvkm_vma ** pvma)1635 nvkm_vmm_get_locked(struct nvkm_vmm *vmm, bool getref, bool mapref, bool sparse,
1636 u8 shift, u8 align, u64 size, struct nvkm_vma **pvma)
1637 {
1638 const struct nvkm_vmm_page *page = &vmm->func->page[NVKM_VMA_PAGE_NONE];
1639 struct rb_node *node = NULL, *temp;
1640 struct nvkm_vma *vma = NULL, *tmp;
1641 u64 addr, tail;
1642 int ret;
1643
1644 VMM_TRACE(vmm, "getref %d mapref %d sparse %d "
1645 "shift: %d align: %d size: %016llx",
1646 getref, mapref, sparse, shift, align, size);
1647
1648 /* Zero-sized, or lazily-allocated sparse VMAs, make no sense. */
1649 if (unlikely(!size || (!getref && !mapref && sparse))) {
1650 VMM_DEBUG(vmm, "args %016llx %d %d %d",
1651 size, getref, mapref, sparse);
1652 return -EINVAL;
1653 }
1654
1655 /* Tesla-class GPUs can only select page size per-PDE, which means
1656 * we're required to know the mapping granularity up-front to find
1657 * a suitable region of address-space.
1658 *
1659 * The same goes if we're requesting up-front allocation of PTES.
1660 */
1661 if (unlikely((getref || vmm->func->page_block) && !shift)) {
1662 VMM_DEBUG(vmm, "page size required: %d %016llx",
1663 getref, vmm->func->page_block);
1664 return -EINVAL;
1665 }
1666
1667 /* If a specific page size was requested, determine its index and
1668 * make sure the requested size is a multiple of the page size.
1669 */
1670 if (shift) {
1671 for (page = vmm->func->page; page->shift; page++) {
1672 if (shift == page->shift)
1673 break;
1674 }
1675
1676 if (!page->shift || !IS_ALIGNED(size, 1ULL << page->shift)) {
1677 VMM_DEBUG(vmm, "page %d %016llx", shift, size);
1678 return -EINVAL;
1679 }
1680 align = max_t(u8, align, shift);
1681 } else {
1682 align = max_t(u8, align, 12);
1683 }
1684
1685 /* Locate smallest block that can possibly satisfy the allocation. */
1686 temp = vmm->free.rb_node;
1687 while (temp) {
1688 struct nvkm_vma *this = rb_entry(temp, typeof(*this), tree);
1689 if (this->size < size) {
1690 temp = temp->rb_right;
1691 } else {
1692 node = temp;
1693 temp = temp->rb_left;
1694 }
1695 }
1696
1697 if (unlikely(!node))
1698 return -ENOSPC;
1699
1700 /* Take into account alignment restrictions, trying larger blocks
1701 * in turn until we find a suitable free block.
1702 */
1703 do {
1704 struct nvkm_vma *this = rb_entry(node, typeof(*this), tree);
1705 struct nvkm_vma *prev = node(this, prev);
1706 struct nvkm_vma *next = node(this, next);
1707 const int p = page - vmm->func->page;
1708
1709 addr = this->addr;
1710 if (vmm->func->page_block && prev && prev->page != p)
1711 addr = ALIGN(addr, vmm->func->page_block);
1712 addr = ALIGN(addr, 1ULL << align);
1713
1714 tail = this->addr + this->size;
1715 if (vmm->func->page_block && next && next->page != p)
1716 tail = ALIGN_DOWN(tail, vmm->func->page_block);
1717
1718 if (addr <= tail && tail - addr >= size) {
1719 nvkm_vmm_free_remove(vmm, this);
1720 vma = this;
1721 break;
1722 }
1723 } while ((node = rb_next(node)));
1724
1725 if (unlikely(!vma))
1726 return -ENOSPC;
1727
1728 /* If the VMA we found isn't already exactly the requested size,
1729 * it needs to be split, and the remaining free blocks returned.
1730 */
1731 if (addr != vma->addr) {
1732 if (!(tmp = nvkm_vma_tail(vma, vma->size + vma->addr - addr))) {
1733 nvkm_vmm_put_region(vmm, vma);
1734 return -ENOMEM;
1735 }
1736 nvkm_vmm_free_insert(vmm, vma);
1737 vma = tmp;
1738 }
1739
1740 if (size != vma->size) {
1741 if (!(tmp = nvkm_vma_tail(vma, vma->size - size))) {
1742 nvkm_vmm_put_region(vmm, vma);
1743 return -ENOMEM;
1744 }
1745 nvkm_vmm_free_insert(vmm, tmp);
1746 }
1747
1748 /* Pre-allocate page tables and/or setup sparse mappings. */
1749 if (sparse && getref)
1750 ret = nvkm_vmm_ptes_sparse_get(vmm, page, vma->addr, vma->size);
1751 else if (sparse)
1752 ret = nvkm_vmm_ptes_sparse(vmm, vma->addr, vma->size, true);
1753 else if (getref)
1754 ret = nvkm_vmm_ptes_get(vmm, page, vma->addr, vma->size);
1755 else
1756 ret = 0;
1757 if (ret) {
1758 nvkm_vmm_put_region(vmm, vma);
1759 return ret;
1760 }
1761
1762 vma->mapref = mapref && !getref;
1763 vma->sparse = sparse;
1764 vma->page = page - vmm->func->page;
1765 vma->refd = getref ? vma->page : NVKM_VMA_PAGE_NONE;
1766 vma->used = true;
1767 nvkm_vmm_node_insert(vmm, vma);
1768 *pvma = vma;
1769 return 0;
1770 }
1771
1772 int
nvkm_vmm_get(struct nvkm_vmm * vmm,u8 page,u64 size,struct nvkm_vma ** pvma)1773 nvkm_vmm_get(struct nvkm_vmm *vmm, u8 page, u64 size, struct nvkm_vma **pvma)
1774 {
1775 int ret;
1776 mutex_lock(&vmm->mutex);
1777 ret = nvkm_vmm_get_locked(vmm, false, true, false, page, 0, size, pvma);
1778 mutex_unlock(&vmm->mutex);
1779 return ret;
1780 }
1781
1782 void
nvkm_vmm_part(struct nvkm_vmm * vmm,struct nvkm_memory * inst)1783 nvkm_vmm_part(struct nvkm_vmm *vmm, struct nvkm_memory *inst)
1784 {
1785 if (inst && vmm && vmm->func->part) {
1786 mutex_lock(&vmm->mutex);
1787 vmm->func->part(vmm, inst);
1788 mutex_unlock(&vmm->mutex);
1789 }
1790 }
1791
1792 int
nvkm_vmm_join(struct nvkm_vmm * vmm,struct nvkm_memory * inst)1793 nvkm_vmm_join(struct nvkm_vmm *vmm, struct nvkm_memory *inst)
1794 {
1795 int ret = 0;
1796 if (vmm->func->join) {
1797 mutex_lock(&vmm->mutex);
1798 ret = vmm->func->join(vmm, inst);
1799 mutex_unlock(&vmm->mutex);
1800 }
1801 return ret;
1802 }
1803
1804 static bool
nvkm_vmm_boot_ptes(struct nvkm_vmm_iter * it,bool pfn,u32 ptei,u32 ptes)1805 nvkm_vmm_boot_ptes(struct nvkm_vmm_iter *it, bool pfn, u32 ptei, u32 ptes)
1806 {
1807 const struct nvkm_vmm_desc *desc = it->desc;
1808 const int type = desc->type == SPT;
1809 nvkm_memory_boot(it->pt[0]->pt[type]->memory, it->vmm);
1810 return false;
1811 }
1812
1813 int
nvkm_vmm_boot(struct nvkm_vmm * vmm)1814 nvkm_vmm_boot(struct nvkm_vmm *vmm)
1815 {
1816 const struct nvkm_vmm_page *page = vmm->func->page;
1817 const u64 limit = vmm->limit - vmm->start;
1818 int ret;
1819
1820 while (page[1].shift)
1821 page++;
1822
1823 ret = nvkm_vmm_ptes_get(vmm, page, vmm->start, limit);
1824 if (ret)
1825 return ret;
1826
1827 nvkm_vmm_iter(vmm, page, vmm->start, limit, "bootstrap", false, false,
1828 nvkm_vmm_boot_ptes, NULL, NULL, NULL);
1829 vmm->bootstrapped = true;
1830 return 0;
1831 }
1832
1833 static void
nvkm_vmm_del(struct kref * kref)1834 nvkm_vmm_del(struct kref *kref)
1835 {
1836 struct nvkm_vmm *vmm = container_of(kref, typeof(*vmm), kref);
1837 nvkm_vmm_dtor(vmm);
1838 kfree(vmm);
1839 }
1840
1841 void
nvkm_vmm_unref(struct nvkm_vmm ** pvmm)1842 nvkm_vmm_unref(struct nvkm_vmm **pvmm)
1843 {
1844 struct nvkm_vmm *vmm = *pvmm;
1845 if (vmm) {
1846 kref_put(&vmm->kref, nvkm_vmm_del);
1847 *pvmm = NULL;
1848 }
1849 }
1850
1851 struct nvkm_vmm *
nvkm_vmm_ref(struct nvkm_vmm * vmm)1852 nvkm_vmm_ref(struct nvkm_vmm *vmm)
1853 {
1854 if (vmm)
1855 kref_get(&vmm->kref);
1856 return vmm;
1857 }
1858
1859 int
nvkm_vmm_new(struct nvkm_device * device,u64 addr,u64 size,void * argv,u32 argc,struct lock_class_key * key,const char * name,struct nvkm_vmm ** pvmm)1860 nvkm_vmm_new(struct nvkm_device *device, u64 addr, u64 size, void *argv,
1861 u32 argc, struct lock_class_key *key, const char *name,
1862 struct nvkm_vmm **pvmm)
1863 {
1864 struct nvkm_mmu *mmu = device->mmu;
1865 struct nvkm_vmm *vmm = NULL;
1866 int ret;
1867 ret = mmu->func->vmm.ctor(mmu, false, addr, size, argv, argc,
1868 key, name, &vmm);
1869 if (ret)
1870 nvkm_vmm_unref(&vmm);
1871 *pvmm = vmm;
1872 return ret;
1873 }
1874