tjh.dev
Linux kernel mirror (for testing)
git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel
os
linux
1/*
2 * vtlb.c: guest virtual tlb handling module.
3 * Copyright (c) 2004, Intel Corporation.
4 * Yaozu Dong (Eddie Dong) <Eddie.dong@intel.com>
5 * Xuefei Xu (Anthony Xu) <anthony.xu@intel.com>
6 *
7 * Copyright (c) 2007, Intel Corporation.
8 * Xuefei Xu (Anthony Xu) <anthony.xu@intel.com>
9 * Xiantao Zhang <xiantao.zhang@intel.com>
10 *
11 * This program is free software; you can redistribute it and/or modify it
12 * under the terms and conditions of the GNU General Public License,
13 * version 2, as published by the Free Software Foundation.
14 *
15 * This program is distributed in the hope it will be useful, but WITHOUT
16 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
17 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
18 * more details.
19 *
20 * You should have received a copy of the GNU General Public License along with
21 * this program; if not, write to the Free Software Foundation, Inc., 59 Temple
22 * Place - Suite 330, Boston, MA 02111-1307 USA.
23 *
24 */
25
26#include "vcpu.h"
27
28#include <linux/rwsem.h>
29
30#include <asm/tlb.h>
31
32/*
33 * Check to see if the address rid:va is translated by the TLB
34 */
35
36static int __is_tr_translated(struct thash_data *trp, u64 rid, u64 va)
37{
38 return ((trp->p) && (trp->rid == rid)
39 && ((va-trp->vadr) < PSIZE(trp->ps)));
40}
41
42/*
43 * Only for GUEST TR format.
44 */
45static int __is_tr_overlap(struct thash_data *trp, u64 rid, u64 sva, u64 eva)
46{
47 u64 sa1, ea1;
48
49 if (!trp->p || trp->rid != rid)
50 return 0;
51
52 sa1 = trp->vadr;
53 ea1 = sa1 + PSIZE(trp->ps) - 1;
54 eva -= 1;
55 if ((sva > ea1) || (sa1 > eva))
56 return 0;
57 else
58 return 1;
59
60}
61
62void machine_tlb_purge(u64 va, u64 ps)
63{
64 ia64_ptcl(va, ps << 2);
65}
66
67void local_flush_tlb_all(void)
68{
69 int i, j;
70 unsigned long flags, count0, count1;
71 unsigned long stride0, stride1, addr;
72
73 addr = current_vcpu->arch.ptce_base;
74 count0 = current_vcpu->arch.ptce_count[0];
75 count1 = current_vcpu->arch.ptce_count[1];
76 stride0 = current_vcpu->arch.ptce_stride[0];
77 stride1 = current_vcpu->arch.ptce_stride[1];
78
79 local_irq_save(flags);
80 for (i = 0; i < count0; ++i) {
81 for (j = 0; j < count1; ++j) {
82 ia64_ptce(addr);
83 addr += stride1;
84 }
85 addr += stride0;
86 }
87 local_irq_restore(flags);
88 ia64_srlz_i(); /* srlz.i implies srlz.d */
89}
90
91int vhpt_enabled(struct kvm_vcpu *vcpu, u64 vadr, enum vhpt_ref ref)
92{
93 union ia64_rr vrr;
94 union ia64_pta vpta;
95 struct ia64_psr vpsr;
96
97 vpsr = *(struct ia64_psr *)&VCPU(vcpu, vpsr);
98 vrr.val = vcpu_get_rr(vcpu, vadr);
99 vpta.val = vcpu_get_pta(vcpu);
100
101 if (vrr.ve & vpta.ve) {
102 switch (ref) {
103 case DATA_REF:
104 case NA_REF:
105 return vpsr.dt;
106 case INST_REF:
107 return vpsr.dt && vpsr.it && vpsr.ic;
108 case RSE_REF:
109 return vpsr.dt && vpsr.rt;
110
111 }
112 }
113 return 0;
114}
115
116struct thash_data *vsa_thash(union ia64_pta vpta, u64 va, u64 vrr, u64 *tag)
117{
118 u64 index, pfn, rid, pfn_bits;
119
120 pfn_bits = vpta.size - 5 - 8;
121 pfn = REGION_OFFSET(va) >> _REGION_PAGE_SIZE(vrr);
122 rid = _REGION_ID(vrr);
123 index = ((rid & 0xff) << pfn_bits)|(pfn & ((1UL << pfn_bits) - 1));
124 *tag = ((rid >> 8) & 0xffff) | ((pfn >> pfn_bits) << 16);
125
126 return (struct thash_data *)((vpta.base << PTA_BASE_SHIFT) +
127 (index << 5));
128}
129
130struct thash_data *__vtr_lookup(struct kvm_vcpu *vcpu, u64 va, int type)
131{
132
133 struct thash_data *trp;
134 int i;
135 u64 rid;
136
137 rid = vcpu_get_rr(vcpu, va);
138 rid = rid & RR_RID_MASK;;
139 if (type == D_TLB) {
140 if (vcpu_quick_region_check(vcpu->arch.dtr_regions, va)) {
141 for (trp = (struct thash_data *)&vcpu->arch.dtrs, i = 0;
142 i < NDTRS; i++, trp++) {
143 if (__is_tr_translated(trp, rid, va))
144 return trp;
145 }
146 }
147 } else {
148 if (vcpu_quick_region_check(vcpu->arch.itr_regions, va)) {
149 for (trp = (struct thash_data *)&vcpu->arch.itrs, i = 0;
150 i < NITRS; i++, trp++) {
151 if (__is_tr_translated(trp, rid, va))
152 return trp;
153 }
154 }
155 }
156
157 return NULL;
158}
159
160static void vhpt_insert(u64 pte, u64 itir, u64 ifa, u64 gpte)
161{
162 union ia64_rr rr;
163 struct thash_data *head;
164 unsigned long ps, gpaddr;
165
166 ps = itir_ps(itir);
167
168 gpaddr = ((gpte & _PAGE_PPN_MASK) >> ps << ps) |
169 (ifa & ((1UL << ps) - 1));
170
171 rr.val = ia64_get_rr(ifa);
172 head = (struct thash_data *)ia64_thash(ifa);
173 head->etag = INVALID_TI_TAG;
174 ia64_mf();
175 head->page_flags = pte & ~PAGE_FLAGS_RV_MASK;
176 head->itir = rr.ps << 2;
177 head->etag = ia64_ttag(ifa);
178 head->gpaddr = gpaddr;
179}
180
181void mark_pages_dirty(struct kvm_vcpu *v, u64 pte, u64 ps)
182{
183 u64 i, dirty_pages = 1;
184 u64 base_gfn = (pte&_PAGE_PPN_MASK) >> PAGE_SHIFT;
185 spinlock_t *lock = __kvm_va(v->arch.dirty_log_lock_pa);
186 void *dirty_bitmap = (void *)v - (KVM_VCPU_OFS + v->vcpu_id * VCPU_SIZE)
187 + KVM_MEM_DIRTY_LOG_OFS;
188 dirty_pages <<= ps <= PAGE_SHIFT ? 0 : ps - PAGE_SHIFT;
189
190 vmm_spin_lock(lock);
191 for (i = 0; i < dirty_pages; i++) {
192 /* avoid RMW */
193 if (!test_bit(base_gfn + i, dirty_bitmap))
194 set_bit(base_gfn + i , dirty_bitmap);
195 }
196 vmm_spin_unlock(lock);
197}
198
199void thash_vhpt_insert(struct kvm_vcpu *v, u64 pte, u64 itir, u64 va, int type)
200{
201 u64 phy_pte, psr;
202 union ia64_rr mrr;
203
204 mrr.val = ia64_get_rr(va);
205 phy_pte = translate_phy_pte(&pte, itir, va);
206
207 if (itir_ps(itir) >= mrr.ps) {
208 vhpt_insert(phy_pte, itir, va, pte);
209 } else {
210 phy_pte &= ~PAGE_FLAGS_RV_MASK;
211 psr = ia64_clear_ic();
212 ia64_itc(type, va, phy_pte, itir_ps(itir));
213 ia64_set_psr(psr);
214 }
215
216 if (!(pte&VTLB_PTE_IO))
217 mark_pages_dirty(v, pte, itir_ps(itir));
218}
219
220/*
221 * vhpt lookup
222 */
223struct thash_data *vhpt_lookup(u64 va)
224{
225 struct thash_data *head;
226 u64 tag;
227
228 head = (struct thash_data *)ia64_thash(va);
229 tag = ia64_ttag(va);
230 if (head->etag == tag)
231 return head;
232 return NULL;
233}
234
235u64 guest_vhpt_lookup(u64 iha, u64 *pte)
236{
237 u64 ret;
238 struct thash_data *data;
239
240 data = __vtr_lookup(current_vcpu, iha, D_TLB);
241 if (data != NULL)
242 thash_vhpt_insert(current_vcpu, data->page_flags,
243 data->itir, iha, D_TLB);
244
245 asm volatile ("rsm psr.ic|psr.i;;"
246 "srlz.d;;"
247 "ld8.s r9=[%1];;"
248 "tnat.nz p6,p7=r9;;"
249 "(p6) mov %0=1;"
250 "(p6) mov r9=r0;"
251 "(p7) extr.u r9=r9,0,53;;"
252 "(p7) mov %0=r0;"
253 "(p7) st8 [%2]=r9;;"
254 "ssm psr.ic;;"
255 "srlz.d;;"
256 /* "ssm psr.i;;" Once interrupts in vmm open, need fix*/
257 : "=r"(ret) : "r"(iha), "r"(pte):"memory");
258
259 return ret;
260}
261
262/*
263 * purge software guest tlb
264 */
265
266static void vtlb_purge(struct kvm_vcpu *v, u64 va, u64 ps)
267{
268 struct thash_data *cur;
269 u64 start, curadr, size, psbits, tag, rr_ps, num;
270 union ia64_rr vrr;
271 struct thash_cb *hcb = &v->arch.vtlb;
272
273 vrr.val = vcpu_get_rr(v, va);
274 psbits = VMX(v, psbits[(va >> 61)]);
275 start = va & ~((1UL << ps) - 1);
276 while (psbits) {
277 curadr = start;
278 rr_ps = __ffs(psbits);
279 psbits &= ~(1UL << rr_ps);
280 num = 1UL << ((ps < rr_ps) ? 0 : (ps - rr_ps));
281 size = PSIZE(rr_ps);
282 vrr.ps = rr_ps;
283 while (num) {
284 cur = vsa_thash(hcb->pta, curadr, vrr.val, &tag);
285 if (cur->etag == tag && cur->ps == rr_ps)
286 cur->etag = INVALID_TI_TAG;
287 curadr += size;
288 num--;
289 }
290 }
291}
292
293
294/*
295 * purge VHPT and machine TLB
296 */
297static void vhpt_purge(struct kvm_vcpu *v, u64 va, u64 ps)
298{
299 struct thash_data *cur;
300 u64 start, size, tag, num;
301 union ia64_rr rr;
302
303 start = va & ~((1UL << ps) - 1);
304 rr.val = ia64_get_rr(va);
305 size = PSIZE(rr.ps);
306 num = 1UL << ((ps < rr.ps) ? 0 : (ps - rr.ps));
307 while (num) {
308 cur = (struct thash_data *)ia64_thash(start);
309 tag = ia64_ttag(start);
310 if (cur->etag == tag)
311 cur->etag = INVALID_TI_TAG;
312 start += size;
313 num--;
314 }
315 machine_tlb_purge(va, ps);
316}
317
318/*
319 * Insert an entry into hash TLB or VHPT.
320 * NOTES:
321 * 1: When inserting VHPT to thash, "va" is a must covered
322 * address by the inserted machine VHPT entry.
323 * 2: The format of entry is always in TLB.
324 * 3: The caller need to make sure the new entry will not overlap
325 * with any existed entry.
326 */
327void vtlb_insert(struct kvm_vcpu *v, u64 pte, u64 itir, u64 va)
328{
329 struct thash_data *head;
330 union ia64_rr vrr;
331 u64 tag;
332 struct thash_cb *hcb = &v->arch.vtlb;
333
334 vrr.val = vcpu_get_rr(v, va);
335 vrr.ps = itir_ps(itir);
336 VMX(v, psbits[va >> 61]) |= (1UL << vrr.ps);
337 head = vsa_thash(hcb->pta, va, vrr.val, &tag);
338 head->page_flags = pte;
339 head->itir = itir;
340 head->etag = tag;
341}
342
343int vtr_find_overlap(struct kvm_vcpu *vcpu, u64 va, u64 ps, int type)
344{
345 struct thash_data *trp;
346 int i;
347 u64 end, rid;
348
349 rid = vcpu_get_rr(vcpu, va);
350 rid = rid & RR_RID_MASK;
351 end = va + PSIZE(ps);
352 if (type == D_TLB) {
353 if (vcpu_quick_region_check(vcpu->arch.dtr_regions, va)) {
354 for (trp = (struct thash_data *)&vcpu->arch.dtrs, i = 0;
355 i < NDTRS; i++, trp++) {
356 if (__is_tr_overlap(trp, rid, va, end))
357 return i;
358 }
359 }
360 } else {
361 if (vcpu_quick_region_check(vcpu->arch.itr_regions, va)) {
362 for (trp = (struct thash_data *)&vcpu->arch.itrs, i = 0;
363 i < NITRS; i++, trp++) {
364 if (__is_tr_overlap(trp, rid, va, end))
365 return i;
366 }
367 }
368 }
369 return -1;
370}
371
372/*
373 * Purge entries in VTLB and VHPT
374 */
375void thash_purge_entries(struct kvm_vcpu *v, u64 va, u64 ps)
376{
377 if (vcpu_quick_region_check(v->arch.tc_regions, va))
378 vtlb_purge(v, va, ps);
379 vhpt_purge(v, va, ps);
380}
381
382void thash_purge_entries_remote(struct kvm_vcpu *v, u64 va, u64 ps)
383{
384 u64 old_va = va;
385 va = REGION_OFFSET(va);
386 if (vcpu_quick_region_check(v->arch.tc_regions, old_va))
387 vtlb_purge(v, va, ps);
388 vhpt_purge(v, va, ps);
389}
390
391u64 translate_phy_pte(u64 *pte, u64 itir, u64 va)
392{
393 u64 ps, ps_mask, paddr, maddr;
394 union pte_flags phy_pte;
395
396 ps = itir_ps(itir);
397 ps_mask = ~((1UL << ps) - 1);
398 phy_pte.val = *pte;
399 paddr = *pte;
400 paddr = ((paddr & _PAGE_PPN_MASK) & ps_mask) | (va & ~ps_mask);
401 maddr = kvm_lookup_mpa(paddr >> PAGE_SHIFT);
402 if (maddr & GPFN_IO_MASK) {
403 *pte |= VTLB_PTE_IO;
404 return -1;
405 }
406 maddr = ((maddr & _PAGE_PPN_MASK) & PAGE_MASK) |
407 (paddr & ~PAGE_MASK);
408 phy_pte.ppn = maddr >> ARCH_PAGE_SHIFT;
409 return phy_pte.val;
410}
411
412/*
413 * Purge overlap TCs and then insert the new entry to emulate itc ops.
414 * Notes: Only TC entry can purge and insert.
415 * 1 indicates this is MMIO
416 */
417int thash_purge_and_insert(struct kvm_vcpu *v, u64 pte, u64 itir,
418 u64 ifa, int type)
419{
420 u64 ps;
421 u64 phy_pte;
422 union ia64_rr vrr, mrr;
423 int ret = 0;
424
425 ps = itir_ps(itir);
426 vrr.val = vcpu_get_rr(v, ifa);
427 mrr.val = ia64_get_rr(ifa);
428
429 phy_pte = translate_phy_pte(&pte, itir, ifa);
430
431 /* Ensure WB attribute if pte is related to a normal mem page,
432 * which is required by vga acceleration since qemu maps shared
433 * vram buffer with WB.
434 */
435 if (!(pte & VTLB_PTE_IO) && ((pte & _PAGE_MA_MASK) != _PAGE_MA_NAT)) {
436 pte &= ~_PAGE_MA_MASK;
437 phy_pte &= ~_PAGE_MA_MASK;
438 }
439
440 if (pte & VTLB_PTE_IO)
441 ret = 1;
442
443 vtlb_purge(v, ifa, ps);
444 vhpt_purge(v, ifa, ps);
445
446 if (ps == mrr.ps) {
447 if (!(pte&VTLB_PTE_IO)) {
448 vhpt_insert(phy_pte, itir, ifa, pte);
449 } else {
450 vtlb_insert(v, pte, itir, ifa);
451 vcpu_quick_region_set(VMX(v, tc_regions), ifa);
452 }
453 } else if (ps > mrr.ps) {
454 vtlb_insert(v, pte, itir, ifa);
455 vcpu_quick_region_set(VMX(v, tc_regions), ifa);
456 if (!(pte&VTLB_PTE_IO))
457 vhpt_insert(phy_pte, itir, ifa, pte);
458 } else {
459 u64 psr;
460 phy_pte &= ~PAGE_FLAGS_RV_MASK;
461 psr = ia64_clear_ic();
462 ia64_itc(type, ifa, phy_pte, ps);
463 ia64_set_psr(psr);
464 }
465 if (!(pte&VTLB_PTE_IO))
466 mark_pages_dirty(v, pte, ps);
467
468 return ret;
469}
470
471/*
472 * Purge all TCs or VHPT entries including those in Hash table.
473 *
474 */
475
476void thash_purge_all(struct kvm_vcpu *v)
477{
478 int i;
479 struct thash_data *head;
480 struct thash_cb *vtlb, *vhpt;
481 vtlb = &v->arch.vtlb;
482 vhpt = &v->arch.vhpt;
483
484 for (i = 0; i < 8; i++)
485 VMX(v, psbits[i]) = 0;
486
487 head = vtlb->hash;
488 for (i = 0; i < vtlb->num; i++) {
489 head->page_flags = 0;
490 head->etag = INVALID_TI_TAG;
491 head->itir = 0;
492 head->next = 0;
493 head++;
494 };
495
496 head = vhpt->hash;
497 for (i = 0; i < vhpt->num; i++) {
498 head->page_flags = 0;
499 head->etag = INVALID_TI_TAG;
500 head->itir = 0;
501 head->next = 0;
502 head++;
503 };
504
505 local_flush_tlb_all();
506}
507
508
509/*
510 * Lookup the hash table and its collision chain to find an entry
511 * covering this address rid:va or the entry.
512 *
513 * INPUT:
514 * in: TLB format for both VHPT & TLB.
515 */
516
517struct thash_data *vtlb_lookup(struct kvm_vcpu *v, u64 va, int is_data)
518{
519 struct thash_data *cch;
520 u64 psbits, ps, tag;
521 union ia64_rr vrr;
522
523 struct thash_cb *hcb = &v->arch.vtlb;
524
525 cch = __vtr_lookup(v, va, is_data);;
526 if (cch)
527 return cch;
528
529 if (vcpu_quick_region_check(v->arch.tc_regions, va) == 0)
530 return NULL;
531
532 psbits = VMX(v, psbits[(va >> 61)]);
533 vrr.val = vcpu_get_rr(v, va);
534 while (psbits) {
535 ps = __ffs(psbits);
536 psbits &= ~(1UL << ps);
537 vrr.ps = ps;
538 cch = vsa_thash(hcb->pta, va, vrr.val, &tag);
539 if (cch->etag == tag && cch->ps == ps)
540 return cch;
541 }
542
543 return NULL;
544}
545
546
547/*
548 * Initialize internal control data before service.
549 */
550void thash_init(struct thash_cb *hcb, u64 sz)
551{
552 int i;
553 struct thash_data *head;
554
555 hcb->pta.val = (unsigned long)hcb->hash;
556 hcb->pta.vf = 1;
557 hcb->pta.ve = 1;
558 hcb->pta.size = sz;
559 head = hcb->hash;
560 for (i = 0; i < hcb->num; i++) {
561 head->page_flags = 0;
562 head->itir = 0;
563 head->etag = INVALID_TI_TAG;
564 head->next = 0;
565 head++;
566 }
567}
568
569u64 kvm_lookup_mpa(u64 gpfn)
570{
571 u64 *base = (u64 *) KVM_P2M_BASE;
572 return *(base + gpfn);
573}
574
575u64 kvm_gpa_to_mpa(u64 gpa)
576{
577 u64 pte = kvm_lookup_mpa(gpa >> PAGE_SHIFT);
578 return (pte >> PAGE_SHIFT << PAGE_SHIFT) | (gpa & ~PAGE_MASK);
579}
580
581
582/*
583 * Fetch guest bundle code.
584 * INPUT:
585 * gip: guest ip
586 * pbundle: used to return fetched bundle.
587 */
588int fetch_code(struct kvm_vcpu *vcpu, u64 gip, IA64_BUNDLE *pbundle)
589{
590 u64 gpip = 0; /* guest physical IP*/
591 u64 *vpa;
592 struct thash_data *tlb;
593 u64 maddr;
594
595 if (!(VCPU(vcpu, vpsr) & IA64_PSR_IT)) {
596 /* I-side physical mode */
597 gpip = gip;
598 } else {
599 tlb = vtlb_lookup(vcpu, gip, I_TLB);
600 if (tlb)
601 gpip = (tlb->ppn >> (tlb->ps - 12) << tlb->ps) |
602 (gip & (PSIZE(tlb->ps) - 1));
603 }
604 if (gpip) {
605 maddr = kvm_gpa_to_mpa(gpip);
606 } else {
607 tlb = vhpt_lookup(gip);
608 if (tlb == NULL) {
609 ia64_ptcl(gip, ARCH_PAGE_SHIFT << 2);
610 return IA64_FAULT;
611 }
612 maddr = (tlb->ppn >> (tlb->ps - 12) << tlb->ps)
613 | (gip & (PSIZE(tlb->ps) - 1));
614 }
615 vpa = (u64 *)__kvm_va(maddr);
616
617 pbundle->i64[0] = *vpa++;
618 pbundle->i64[1] = *vpa;
619
620 return IA64_NO_FAULT;
621}
622
623
624void kvm_init_vhpt(struct kvm_vcpu *v)
625{
626 v->arch.vhpt.num = VHPT_NUM_ENTRIES;
627 thash_init(&v->arch.vhpt, VHPT_SHIFT);
628 ia64_set_pta(v->arch.vhpt.pta.val);
629 /*Enable VHPT here?*/
630}
631
632void kvm_init_vtlb(struct kvm_vcpu *v)
633{
634 v->arch.vtlb.num = VTLB_NUM_ENTRIES;
635 thash_init(&v->arch.vtlb, VTLB_SHIFT);
636}